Move all dependencies to the repository

This step seems bold, but is saves us so much hassle. Even better, we have a
reliable codebase, with all the dependencies (and their versions) we
need in order to build the project. If a library got an update, we can
replace it inplace if the code is still compatible.
This commit is contained in:
Aaron Fischer 2019-02-03 16:12:19 +01:00
parent 091ab25196
commit f24858d162
349 changed files with 177093 additions and 12 deletions

1
firmware/config.h Executable file → Normal file
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@ -1,4 +1,3 @@
#ifndef __CONFIG_H__ #ifndef __CONFIG_H__
#define __CONFIG_H__ #define __CONFIG_H__

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firmware/firmware.ino Executable file → Normal file
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#include <WiFiClient.h> // Standard ESP8266 libs
#include <ESP8266mDNS.h> #include <ESP8266mDNS.h>
#include <ESP8266HTTPUpdateServer.h> #include <ESP8266HTTPUpdateServer.h>
#include <ESP8266WiFi.h> #include <ESP8266WiFi.h>
#include <DNSServer.h> #include <DNSServer.h>
#include <ESP8266WebServer.h> #include <ESP8266WebServer.h>
// External libs
// We decided to put these libs inside the project folder, because we have a lot
// of issues with finding the right libs (some libs need a specific version, some
// libs have no unique name, some libs are broken, ...). This is not a fine
// software engineering practice, but it was too much of a hassle to get this right,
// so we decided to put everything in version control. This way, we also can control
// the version of the lib, which makes the build process of this project more
// robust to changes.
// IMPORTANT: You need to set the sketch location of your Arduino IDE to the firmware
// folder in order to use the libs. (File -> Preferences -> Sketchbook Location)
#include <WiFiClient.h> // WiFiClient
#include <WiFiManager.h> // WiFiManager #include <WiFiManager.h> // WiFiManager
#include <ESP8266Influxdb.h> // https://github.com/hwwong/ESP8266Influxdb auchecken und den ordner in das arduino\library verzeichnis kopieren #include <ESP8266Influxdb.h> // https://github.com/hwwong/ESP8266Influxdb auchecken und den ordner in das arduino\library verzeichnis kopieren
#include <Adafruit_Sensor.h> // Package Adafruit Unified Sensor #include <Adafruit_Sensor.h> // Package Adafruit Unified Sensor
#include <Adafruit_APDS9960.h> // Adafruit APDS9960 - https://www.makerfabs.com/index.php?route=product/product&product_id=281 #include <Adafruit_APDS9960.h> // Adafruit APDS9960 - https://www.makerfabs.com/index.php?route=product/product&product_id=281
#include <Adafruit_BME280.h> // BME280 - https://www.roboter-bausatz.de/1704/bmp280-barometer-luftdrucksensor?gclid=EAIaIQobChMIlpumj8Hp2wIVFWYbCh01PgmFEAQYAyABEgIwBvD_BwE #include <Adafruit_BME280.h> // BME280 - https://www.roboter-bausatz.de/1704/bmp280-barometer-luftdrucksensor?gclid=EAIaIQobChMIlpumj8Hp2wIVFWYbCh01PgmFEAQYAyABEgIwBvD_BwE
// Project includes
#include "config.h" #include "config.h"
// IMPORTANT: If you compile the sourcecode and it can't find this file, this is
// indended :) You need to create a config_user.h with your own settings. Use the
// config_user.h.example as a starting point.
#include "config_user.h" #include "config_user.h"
//*************************************************************************// //*************************************************************************//

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void pushToInfluxDB(String device, float sensorValues[]) { void pushToInfluxDB(String device, float sensorValues[]) {
uint8_t tries = 0; uint8_t tries = 0;

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/**************************************************************************/
/*!
@file Adafruit_APDS9960.cpp
@author Ladyada, Dean Miller (Adafruit Industries)
@section LICENSE
Software License Agreement (BSD License)
Copyright (c) 2017, Adafruit Industries
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. Neither the name of the copyright holders nor the
names of its contributors may be used to endorse or promote products
derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ''AS IS'' AND ANY
EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY
DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/**************************************************************************/
#ifdef __AVR
#include <avr/pgmspace.h>
#elif defined(ESP8266)
#include <pgmspace.h>
#endif
#include <stdlib.h>
#include <math.h>
#include "Adafruit_APDS9960.h"
/*========================================================================*/
/* PRIVATE FUNCTIONS */
/*========================================================================*/
/**************************************************************************/
/*!
@brief Implements missing powf function
*/
/**************************************************************************/
float powf(const float x, const float y)
{
return (float)(pow((double)x, (double)y));
}
/**************************************************************************/
/*!
Enables the device
Disables the device (putting it in lower power sleep mode)
*/
/**************************************************************************/
void Adafruit_APDS9960::enable(boolean en)
{
_enable.PON = en;
this->write8(APDS9960_ENABLE, _enable.get());
}
/*========================================================================*/
/* PUBLIC FUNCTIONS */
/*========================================================================*/
/**************************************************************************/
/*!
Initializes I2C and configures the sensor (call this function before
doing anything else)
*/
/**************************************************************************/
boolean Adafruit_APDS9960::begin(uint16_t iTimeMS, apds9960AGain_t aGain, uint8_t addr)
{
_i2c_init();
_i2caddr = addr;
/* Make sure we're actually connected */
uint8_t x = read8(APDS9960_ID);
if (x != 0xAB)
{
return false;
}
/* Set default integration time and gain */
setADCIntegrationTime(iTimeMS);
setADCGain(aGain);
// disable everything to start
enableGesture(false);
enableProximity(false);
enableColor(false);
disableColorInterrupt();
disableProximityInterrupt();
clearInterrupt();
/* Note: by default, the device is in power down mode on bootup */
enable(false);
delay(10);
enable(true);
delay(10);
//default to all gesture dimensions
setGestureDimensions(APDS9960_DIMENSIONS_ALL);
setGestureFIFOThreshold(APDS9960_GFIFO_4);
setGestureGain(APDS9960_GGAIN_4);
setGestureProximityThreshold(50);
resetCounts();
_gpulse.GPLEN = APDS9960_GPULSE_32US;
_gpulse.GPULSE = 9; //10 pulses
this->write8(APDS9960_GPULSE, _gpulse.get());
return true;
}
/**************************************************************************/
/*!
Sets the integration time for the ADC of the APDS9960, in millis
*/
/**************************************************************************/
void Adafruit_APDS9960::setADCIntegrationTime(uint16_t iTimeMS)
{
float temp;
// convert ms into 2.78ms increments
temp = iTimeMS;
temp /= 2.78;
temp = 256 - temp;
if (temp > 255) temp = 255;
if (temp < 0) temp = 0;
/* Update the timing register */
write8(APDS9960_ATIME, (uint8_t)temp);
}
float Adafruit_APDS9960::getADCIntegrationTime(void)
{
float temp;
temp = read8(APDS9960_ATIME);
// convert to units of 2.78 ms
temp = 256 - temp;
temp *= 2.78;
return temp;
}
/**************************************************************************/
/*!
Adjusts the color/ALS gain on the APDS9960 (adjusts the sensitivity to light)
*/
/**************************************************************************/
void Adafruit_APDS9960::setADCGain(apds9960AGain_t aGain)
{
_control.AGAIN = aGain;
/* Update the timing register */
write8(APDS9960_CONTROL, _control.get());
}
apds9960AGain_t Adafruit_APDS9960::getADCGain(void)
{
return (apds9960AGain_t) ( read8(APDS9960_CONTROL) & 0x03 );
}
/**************************************************************************/
/*!
Adjusts the Proximity gain on the APDS9960
*/
/**************************************************************************/
void Adafruit_APDS9960::setProxGain(apds9960PGain_t pGain)
{
_control.PGAIN = pGain;
/* Update the timing register */
write8(APDS9960_CONTROL, _control.get());
}
apds9960PGain_t Adafruit_APDS9960::getProxGain(void)
{
return (apds9960PGain_t) ( read8(APDS9960_CONTROL) & 0x0C );
}
void Adafruit_APDS9960::setProxPulse(apds9960PPulseLen_t pLen, uint8_t pulses) {
if (pulses < 1) pulses = 1;
if (pulses > 64) pulses = 64;
pulses--;
_ppulse.PPLEN = pLen;
_ppulse.PPULSE = pulses;
write8(APDS9960_PPULSE, _ppulse.get());
}
/**************************************************************************/
/*!
Enable proximity readings on APDS9960
*/
/**************************************************************************/
void Adafruit_APDS9960::enableProximity(boolean en)
{
_enable.PEN = en;
write8(APDS9960_ENABLE, _enable.get());
}
void Adafruit_APDS9960::enableProximityInterrupt() {
_enable.PIEN = 1;
write8(APDS9960_ENABLE, _enable.get());
clearInterrupt();
}
void Adafruit_APDS9960::disableProximityInterrupt() {
_enable.PIEN = 0;
write8(APDS9960_ENABLE, _enable.get());
}
void Adafruit_APDS9960::setProximityInterruptThreshold(uint8_t low, uint8_t high, uint8_t persistance){
write8(APDS9960_PILT, low);
write8(APDS9960_PIHT, high);
if (persistance > 7) persistance = 7;
_pers.PPERS = persistance;
write8(APDS9960_PERS,_pers.get());
}
bool Adafruit_APDS9960::getProximityInterrupt()
{
_status.set(this->read8(APDS9960_STATUS));
return _status.PINT;
};
/**************************************************************************/
/*!
Read proximity data
*/
/**************************************************************************/
uint8_t Adafruit_APDS9960::readProximity(void)
{
return read8(APDS9960_PDATA);
}
bool Adafruit_APDS9960::gestureValid()
{
_gstatus.set(this->read8(APDS9960_GSTATUS));
return _gstatus.GVALID;
}
void Adafruit_APDS9960::setGestureDimensions(uint8_t dims)
{
_gconf3.GDIMS = dims;
this->write8(APDS9960_GCONF3, _gconf3.get());
}
void Adafruit_APDS9960::setGestureFIFOThreshold(uint8_t thresh)
{
_gconf1.GFIFOTH = thresh;
this->write8(APDS9960_GCONF1, _gconf1.get());
}
void Adafruit_APDS9960::setGestureGain(uint8_t gain)
{
_gconf2.GGAIN = gain;
this->write8(APDS9960_GCONF2, _gconf2.get());
}
void Adafruit_APDS9960::setGestureProximityThreshold(uint8_t thresh)
{
this->write8(APDS9960_GPENTH, thresh);
}
void Adafruit_APDS9960::setGestureOffset(uint8_t offset_up, uint8_t offset_down, uint8_t offset_left, uint8_t offset_right)
{
this->write8(APDS9960_GOFFSET_U, offset_up);
this->write8(APDS9960_GOFFSET_D, offset_down);
this->write8(APDS9960_GOFFSET_L, offset_left);
this->write8(APDS9960_GOFFSET_R, offset_right);
}
/**************************************************************************/
/*!
Enable gesture readings on APDS9960
*/
/**************************************************************************/
void Adafruit_APDS9960::enableGesture(boolean en)
{
if(!en){
_gconf4.GMODE = 0;
write8(APDS9960_GCONF4, _gconf4.get());
}
_enable.GEN = en;
write8(APDS9960_ENABLE, _enable.get());
resetCounts();
}
void Adafruit_APDS9960::resetCounts()
{
gestCnt = 0;
UCount = 0;
DCount = 0;
LCount = 0;
RCount = 0;
}
uint8_t Adafruit_APDS9960::readGesture(void)
{
uint8_t toRead, bytesRead;
uint8_t buf[256];
unsigned long t;
uint8_t gestureReceived;
while(1){
int up_down_diff = 0;
int left_right_diff = 0;
gestureReceived = 0;
if(!gestureValid()) return 0;
delay(30);
toRead = this->read8(APDS9960_GFLVL);
bytesRead = this->read(APDS9960_GFIFO_U, buf, toRead);
if(abs((int)buf[0] - (int)buf[1]) > 13)
up_down_diff += (int)buf[0] - (int)buf[1];
if(abs((int)buf[2] - (int)buf[3]) > 13)
left_right_diff += (int)buf[2] - (int)buf[3];
if(up_down_diff != 0){
if(up_down_diff < 0){
if( DCount > 0){
gestureReceived = APDS9960_UP;
}
else UCount++;
}
else if(up_down_diff > 0){
if( UCount > 0){
gestureReceived = APDS9960_DOWN;
}
else DCount++;
}
}
if(left_right_diff != 0){
if(left_right_diff < 0){
if( RCount > 0){
gestureReceived = APDS9960_LEFT;
}
else LCount++;
}
else if(left_right_diff > 0){
if( LCount > 0){
gestureReceived = APDS9960_RIGHT;
}
else RCount++;
}
}
if(up_down_diff != 0 || left_right_diff != 0) t = millis();
if(gestureReceived || millis() - t > 300){
resetCounts();
return gestureReceived;
}
}
}
/**************************************************************************/
/*!
Set LED brightness for proximity/gesture
*/
/**************************************************************************/
void Adafruit_APDS9960::setLED(apds9960LedDrive_t drive, apds9960LedBoost_t boost) {
// set BOOST
_config2.LED_BOOST = boost;
write8(APDS9960_CONFIG2, _config2.get());
_control.LDRIVE = drive;
write8(APDS9960_CONTROL, _control.get());
}
/**************************************************************************/
/*!
Enable proximity readings on APDS9960
*/
/**************************************************************************/
void Adafruit_APDS9960::enableColor(boolean en)
{
_enable.AEN = en;
write8(APDS9960_ENABLE, _enable.get());
}
bool Adafruit_APDS9960::colorDataReady()
{
_status.set(this->read8(APDS9960_STATUS));
return _status.AVALID;
}
/**************************************************************************/
/*!
@brief Reads the raw red, green, blue and clear channel values
*/
/**************************************************************************/
void Adafruit_APDS9960::getColorData (uint16_t *r, uint16_t *g, uint16_t *b, uint16_t *c)
{
*c = read16R(APDS9960_CDATAL);
*r = read16R(APDS9960_RDATAL);
*g = read16R(APDS9960_GDATAL);
*b = read16R(APDS9960_BDATAL);
}
/**************************************************************************/
/*!
@brief Converts the raw R/G/B values to color temperature in degrees
Kelvin
*/
/**************************************************************************/
uint16_t Adafruit_APDS9960::calculateColorTemperature(uint16_t r, uint16_t g, uint16_t b)
{
float X, Y, Z; /* RGB to XYZ correlation */
float xc, yc; /* Chromaticity co-ordinates */
float n; /* McCamy's formula */
float cct;
/* 1. Map RGB values to their XYZ counterparts. */
/* Based on 6500K fluorescent, 3000K fluorescent */
/* and 60W incandescent values for a wide range. */
/* Note: Y = Illuminance or lux */
X = (-0.14282F * r) + (1.54924F * g) + (-0.95641F * b);
Y = (-0.32466F * r) + (1.57837F * g) + (-0.73191F * b);
Z = (-0.68202F * r) + (0.77073F * g) + ( 0.56332F * b);
/* 2. Calculate the chromaticity co-ordinates */
xc = (X) / (X + Y + Z);
yc = (Y) / (X + Y + Z);
/* 3. Use McCamy's formula to determine the CCT */
n = (xc - 0.3320F) / (0.1858F - yc);
/* Calculate the final CCT */
cct = (449.0F * powf(n, 3)) + (3525.0F * powf(n, 2)) + (6823.3F * n) + 5520.33F;
/* Return the results in degrees Kelvin */
return (uint16_t)cct;
}
/**************************************************************************/
/*!
@brief Calculate ambient light values
*/
/**************************************************************************/
uint16_t Adafruit_APDS9960::calculateLux(uint16_t r, uint16_t g, uint16_t b)
{
float illuminance;
/* This only uses RGB ... how can we integrate clear or calculate lux */
/* based exclusively on clear since this might be more reliable? */
illuminance = (-0.32466F * r) + (1.57837F * g) + (-0.73191F * b);
return (uint16_t)illuminance;
}
void Adafruit_APDS9960::enableColorInterrupt() {
_enable.AIEN = 1;
write8(APDS9960_ENABLE, _enable.get());
}
void Adafruit_APDS9960::disableColorInterrupt() {
_enable.AIEN = 0;
write8(APDS9960_ENABLE, _enable.get());
}
void Adafruit_APDS9960::clearInterrupt(void) {
this->write(APDS9960_AICLEAR, NULL, 0);
}
void Adafruit_APDS9960::setIntLimits(uint16_t low, uint16_t high) {
write8(APDS9960_AILTIL, low & 0xFF);
write8(APDS9960_AILTH, low >> 8);
write8(APDS9960_AIHTL, high & 0xFF);
write8(APDS9960_AIHTH, high >> 8);
}
void Adafruit_APDS9960::write8(byte reg, byte value)
{
this->write(reg, &value, 1);
}
uint8_t Adafruit_APDS9960::read8(byte reg)
{
uint8_t ret;
this->read(reg, &ret, 1);
return ret;
}
uint32_t Adafruit_APDS9960::read32(uint8_t reg)
{
uint8_t ret[4];
this->read(reg, ret, 4);
return (ret[0] << 24) | (ret[1] << 16) | (ret[2] << 8) | ret[3];
}
uint16_t Adafruit_APDS9960::read16(uint8_t reg)
{
uint8_t ret[2];
this->read(reg, ret, 2);
return (ret[0] << 8) | ret[1];
}
uint16_t Adafruit_APDS9960::read16R(uint8_t reg)
{
uint8_t ret[2];
this->read(reg, ret, 2);
return (ret[1] << 8) | ret[0];
}
void Adafruit_APDS9960::_i2c_init()
{
Wire.begin();
}
uint8_t Adafruit_APDS9960::read(uint8_t reg, uint8_t *buf, uint8_t num)
{
uint8_t value;
uint8_t pos = 0;
bool eof = false;
//on arduino we need to read in 32 byte chunks
while(pos < num && !eof){
uint8_t read_now = min(32, num - pos);
Wire.beginTransmission((uint8_t)_i2caddr);
Wire.write((uint8_t)reg + pos);
Wire.endTransmission();
Wire.requestFrom((uint8_t)_i2caddr, read_now);
for(int i=0; i<read_now; i++){
if(!Wire.available()){
eof = true;
break;
}
buf[pos] = Wire.read();
pos++;
}
}
return pos;
}
void Adafruit_APDS9960::write(uint8_t reg, uint8_t *buf, uint8_t num)
{
Wire.beginTransmission((uint8_t)_i2caddr);
Wire.write((uint8_t)reg);
Wire.write((uint8_t *)buf, num);
Wire.endTransmission();
}

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/**************************************************************************/
/*!
@file Adafruit_APDS9960.h
@author Ladyada, Dean Miller (Adafruit Industries)
@section LICENSE
Software License Agreement (BSD License)
Copyright (c) 2017, Adafruit Industries
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. Neither the name of the copyright holders nor the
names of its contributors may be used to endorse or promote products
derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ''AS IS'' AND ANY
EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY
DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/**************************************************************************/
#ifndef _APDS9960_H_
#define _APDS9960_H_
#include <Arduino.h>
#include <Wire.h>
#define I2CDEBUG
/*=========================================================================
I2C ADDRESS/BITS
-----------------------------------------------------------------------*/
#define APDS9960_ADDRESS (0x39)
/*=========================================================================*/
/*=========================================================================
REGISTERS
-----------------------------------------------------------------------*/
enum
{
APDS9960_RAM = 0x00,
APDS9960_ENABLE = 0x80,
APDS9960_ATIME = 0x81,
APDS9960_WTIME = 0x83,
APDS9960_AILTIL = 0x84,
APDS9960_AILTH = 0x85,
APDS9960_AIHTL = 0x86,
APDS9960_AIHTH = 0x87,
APDS9960_PILT = 0x89,
APDS9960_PIHT = 0x8B,
APDS9960_PERS = 0x8C,
APDS9960_CONFIG1 = 0x8D,
APDS9960_PPULSE = 0x8E,
APDS9960_CONTROL = 0x8F,
APDS9960_CONFIG2 = 0x90,
APDS9960_ID = 0x92,
APDS9960_STATUS = 0x93,
APDS9960_CDATAL = 0x94,
APDS9960_CDATAH = 0x95,
APDS9960_RDATAL = 0x96,
APDS9960_RDATAH = 0x97,
APDS9960_GDATAL = 0x98,
APDS9960_GDATAH = 0x99,
APDS9960_BDATAL = 0x9A,
APDS9960_BDATAH = 0x9B,
APDS9960_PDATA = 0x9C,
APDS9960_POFFSET_UR = 0x9D,
APDS9960_POFFSET_DL = 0x9E,
APDS9960_CONFIG3 = 0x9F,
APDS9960_GPENTH = 0xA0,
APDS9960_GEXTH = 0xA1,
APDS9960_GCONF1 = 0xA2,
APDS9960_GCONF2 = 0xA3,
APDS9960_GOFFSET_U = 0xA4,
APDS9960_GOFFSET_D = 0xA5,
APDS9960_GOFFSET_L = 0xA7,
APDS9960_GOFFSET_R = 0xA9,
APDS9960_GPULSE = 0xA6,
APDS9960_GCONF3 = 0xAA,
APDS9960_GCONF4 = 0xAB,
APDS9960_GFLVL = 0xAE,
APDS9960_GSTATUS = 0xAF,
APDS9960_IFORCE = 0xE4,
APDS9960_PICLEAR = 0xE5,
APDS9960_CICLEAR = 0xE6,
APDS9960_AICLEAR = 0xE7,
APDS9960_GFIFO_U = 0xFC,
APDS9960_GFIFO_D = 0xFD,
APDS9960_GFIFO_L = 0xFE,
APDS9960_GFIFO_R = 0xFF,
};
/*=========================================================================*/
typedef enum
{
APDS9960_AGAIN_1X = 0x00, /**< No gain */
APDS9960_AGAIN_4X = 0x01, /**< 2x gain */
APDS9960_AGAIN_16X = 0x02, /**< 16x gain */
APDS9960_AGAIN_64X = 0x03 /**< 64x gain */
}
apds9960AGain_t;
typedef enum
{
APDS9960_PGAIN_1X = 0x00, /**< 1x gain */
APDS9960_PGAIN_2X = 0x04, /**< 2x gain */
APDS9960_PGAIN_4X = 0x08, /**< 4x gain */
APDS9960_PGAIN_8X = 0x0C /**< 8x gain */
}
apds9960PGain_t;
typedef enum
{
APDS9960_PPULSELEN_4US = 0x00, /**< 4uS */
APDS9960_PPULSELEN_8US = 0x40, /**< 8uS */
APDS9960_PPULSELEN_16US = 0x80, /**< 16uS */
APDS9960_PPULSELEN_32US = 0xC0 /**< 32uS */
}
apds9960PPulseLen_t;
typedef enum
{
APDS9960_LEDDRIVE_100MA = 0x00, /**< 100mA */
APDS9960_LEDDRIVE_50MA = 0x40, /**< 50mA */
APDS9960_LEDDRIVE_25MA = 0x80, /**< 25mA */
APDS9960_LEDDRIVE_12MA = 0xC0 /**< 12.5mA */
}
apds9960LedDrive_t;
typedef enum
{
APDS9960_LEDBOOST_100PCNT = 0x00, /**< 100% */
APDS9960_LEDBOOST_150PCNT = 0x10, /**< 150% */
APDS9960_LEDBOOST_200PCNT = 0x20, /**< 200% */
APDS9960_LEDBOOST_300PCNT = 0x30 /**< 300% */
}
apds9960LedBoost_t;
enum
{
APDS9960_DIMENSIONS_ALL = 0x00,
APDS9960_DIMENSIONS_UP_DOWM = 0x01,
APGS9960_DIMENSIONS_LEFT_RIGHT = 0x02,
};
enum
{
APDS9960_GFIFO_1 = 0x00,
APDS9960_GFIFO_4 = 0x01,
APDS9960_GFIFO_8 = 0x02,
APDS9960_GFIFO_16 = 0x03,
};
enum
{
APDS9960_GGAIN_1 = 0x00,
APDS9960_GGAIN_2 = 0x01,
APDS9960_GGAIN_4 = 0x02,
APDS9960_GGAIN_8 = 0x03,
};
enum
{
APDS9960_GPULSE_4US = 0x00,
APDS9960_GPULSE_8US = 0x01,
APDS9960_GPULSE_16US = 0x02,
APDS9960_GPULSE_32US = 0x03,
};
#define APDS9960_TIME_MULT 2.78 //millisec
#define APDS9960_UP 0x01
#define APDS9960_DOWN 0x02
#define APDS9960_LEFT 0x03
#define APDS9960_RIGHT 0x04
class Adafruit_APDS9960 {
public:
Adafruit_APDS9960(void) {};
~Adafruit_APDS9960(void) {};
boolean begin(uint16_t iTimeMS = 10, apds9960AGain_t = APDS9960_AGAIN_4X, uint8_t addr = APDS9960_ADDRESS);
void setADCIntegrationTime(uint16_t iTimeMS);
float getADCIntegrationTime(void);
void setADCGain(apds9960AGain_t gain);
apds9960AGain_t getADCGain(void);
void setLED(apds9960LedDrive_t drive, apds9960LedBoost_t boost);
// proximity
void enableProximity(boolean en = true);
void setProxGain(apds9960PGain_t gain);
apds9960PGain_t getProxGain(void);
void setProxPulse(apds9960PPulseLen_t pLen, uint8_t pulses);
void enableProximityInterrupt();
void disableProximityInterrupt();
uint8_t readProximity(void);
void setProximityInterruptThreshold(uint8_t low, uint8_t high, uint8_t persistance = 4);
bool getProximityInterrupt();
// gesture
void enableGesture(boolean en = true);
bool gestureValid();
void setGestureDimensions(uint8_t dims);
void setGestureFIFOThreshold(uint8_t thresh);
void setGestureGain(uint8_t gain);
void setGestureProximityThreshold(uint8_t thresh);
void setGestureOffset(uint8_t offset_up, uint8_t offset_down, uint8_t offset_left, uint8_t offset_right);
uint8_t readGesture(void);
void resetCounts();
// light & color
void enableColor(boolean en = true);
bool colorDataReady();
void getColorData(uint16_t *r, uint16_t *g, uint16_t *b, uint16_t *c);
uint16_t calculateColorTemperature(uint16_t r, uint16_t g, uint16_t b);
uint16_t calculateLux(uint16_t r, uint16_t g, uint16_t b);
void enableColorInterrupt();
void disableColorInterrupt();
void clearInterrupt(void);
void setIntLimits(uint16_t l, uint16_t h);
// turn on/off elements
void enable(boolean en = true);
private:
uint8_t _i2caddr;
uint32_t read32(uint8_t reg);
uint16_t read16(uint8_t reg);
uint16_t read16R(uint8_t reg);
void write8(byte reg, byte value);
uint8_t read8(byte reg);
uint8_t gestCnt;
uint8_t UCount;
uint8_t DCount;
uint8_t LCount;
uint8_t RCount;
uint8_t read(uint8_t reg, uint8_t *buf, uint8_t num);
void write(uint8_t reg, uint8_t *buf, uint8_t num);
void _i2c_init();
struct enable {
//power on
uint8_t PON : 1;
//ALS enable
uint8_t AEN : 1;
//Proximity detect enable
uint8_t PEN : 1;
//wait timer enable
uint8_t WEN : 1;
//ALS interrupt enable
uint8_t AIEN : 1;
//proximity interrupt enable
uint8_t PIEN : 1;
//gesture enable
uint8_t GEN : 1;
uint8_t get() {
return (GEN << 6) | (PIEN << 5) | (AIEN << 4) | (WEN << 3) | (PEN << 2) | (AEN << 1) | PON;
};
};
struct enable _enable;
struct pers {
//ALS Interrupt Persistence. Controls rate of Clear channel interrupt to the host processor
uint8_t APERS : 4;
//proximity interrupt persistence, controls rate of prox interrupt to host processor
uint8_t PPERS : 4;
uint8_t get(){
return (PPERS << 4) | APERS;
};
};
pers _pers;
struct config1 {
uint8_t WLONG : 1;
uint8_t get(){
return WLONG << 1;
};
};
config1 _config1;
struct ppulse {
/*Proximity Pulse Count. Specifies the number of proximity pulses to be generated on LDR.
Number of pulses is set by PPULSE value plus 1.
*/
uint8_t PPULSE : 6;
//Proximity Pulse Length. Sets the LED-ON pulse width during a proximity LDR pulse.
uint8_t PPLEN : 2;
uint8_t get(){
return (PPLEN << 6) | PPULSE;
}
};
ppulse _ppulse;
struct control {
//ALS and Color gain control
uint8_t AGAIN : 2;
//proximity gain control
uint8_t PGAIN : 2;
//led drive strength
uint8_t LDRIVE : 2;
uint8_t get(){
return (LDRIVE << 6) | (PGAIN << 2) | AGAIN;
}
};
control _control;
struct config2 {
/* Additional LDR current during proximity and gesture LED pulses. Current value, set by LDRIVE,
is increased by the percentage of LED_BOOST.
*/
uint8_t LED_BOOST : 2;
//clear photodiode saturation int enable
uint8_t CPSIEN : 1;
//proximity saturation interrupt enable
uint8_t PSIEN : 1;
uint8_t get(){
return (PSIEN << 7) | (CPSIEN << 6) | (LED_BOOST << 4) | 1;
}
};
config2 _config2;
struct status {
/* ALS Valid. Indicates that an ALS cycle has completed since AEN was asserted or since a read
from any of the ALS/Color data registers.
*/
uint8_t AVALID : 1;
/* Proximity Valid. Indicates that a proximity cycle has completed since PEN was asserted or since
PDATA was last read. A read of PDATA automatically clears PVALID.
*/
uint8_t PVALID : 1;
/* Gesture Interrupt. GINT is asserted when GFVLV becomes greater than GFIFOTH or if GVALID
has become asserted when GMODE transitioned to zero. The bit is reset when FIFO is
completely emptied (read).
*/
uint8_t GINT : 1;
//ALS Interrupt. This bit triggers an interrupt if AIEN in ENABLE is set.
uint8_t AINT : 1;
//Proximity Interrupt. This bit triggers an interrupt if PIEN in ENABLE is set.
uint8_t PINT : 1;
/* Indicates that an analog saturation event occurred during a previous proximity or gesture
cycle. Once set, this bit remains set until cleared by clear proximity interrupt special function
command (0xE5 PICLEAR) or by disabling Prox (PEN=0). This bit triggers an interrupt if PSIEN
is set.
*/
uint8_t PGSAT : 1;
/* Clear Photodiode Saturation. When asserted, the analog sensor was at the upper end of its
dynamic range. The bit can be de-asserted by sending a Clear channel interrupt command
(0xE6 CICLEAR) or by disabling the ADC (AEN=0). This bit triggers an interrupt if CPSIEN is set.
*/
uint8_t CPSAT : 1;
void set(uint8_t data){
AVALID = data & 0x01;
PVALID = (data >> 1) & 0x01;
GINT = (data >> 2) & 0x01;
AINT = (data >> 4) & 0x01;
PINT = (data >> 5) & 0x01;
PGSAT = (data >> 6) & 0x01;
CPSAT = (data >> 7) & 0x01;
}
};
status _status;
struct config3 {
//proximity mask
uint8_t PMASK_R : 1;
uint8_t PMASK_L : 1;
uint8_t PMASK_D : 1;
uint8_t PMASK_U : 1;
/* Sleep After Interrupt. When enabled, the device will automatically enter low power mode
when the INT pin is asserted and the state machine has progressed to the SAI decision block.
Normal operation is resumed when INT pin is cleared over I2C.
*/
uint8_t SAI : 1;
/* Proximity Gain Compensation Enable. This bit provides gain compensation when proximity
photodiode signal is reduced as a result of sensor masking. If only one diode of the diode pair
is contributing, then only half of the signal is available at the ADC; this results in a maximum
ADC value of 127. Enabling PCMP enables an additional gain of 2X, resulting in a maximum
ADC value of 255.
*/
uint8_t PCMP : 1;
uint8_t get(){
return (PCMP << 5) | (SAI << 4) | (PMASK_U << 3) | (PMASK_D << 2) | (PMASK_L << 1) | PMASK_R;
}
};
config3 _config3;
struct gconf1 {
/* Gesture Exit Persistence. When a number of consecutive “gesture end” occurrences become
equal or greater to the GEPERS value, the Gesture state machine is exited.
*/
uint8_t GEXPERS : 2;
/* Gesture Exit Mask. Controls which of the gesture detector photodiodes (UDLR) will be included
to determine a gesture end and subsequent exit of the gesture state machine. Unmasked
UDLR data will be compared with the value in GTHR_OUT. Field value bits correspond to UDLR
detectors.
*/
uint8_t GEXMSK : 4;
/* Gesture FIFO Threshold. This value is compared with the FIFO Level (i.e. the number of UDLR
datasets) to generate an interrupt (if enabled).
*/
uint8_t GFIFOTH : 2;
uint8_t get(){
return (GFIFOTH << 6) | (GEXMSK << 2) | GEXPERS;
}
};
gconf1 _gconf1;
struct gconf2 {
/* Gesture Wait Time. The GWTIME controls the amount of time in a low power mode between
gesture detection cycles.
*/
uint8_t GWTIME : 3;
//Gesture LED Drive Strength. Sets LED Drive Strength in gesture mode.
uint8_t GLDRIVE : 2;
//Gesture Gain Control. Sets the gain of the proximity receiver in gesture mode.
uint8_t GGAIN : 2;
uint8_t get(){
return (GGAIN << 5) | (GLDRIVE << 3) | GWTIME;
}
};
gconf2 _gconf2;
struct gpulse {
/* Number of Gesture Pulses. Specifies the number of pulses to be generated on LDR.
Number of pulses is set by GPULSE value plus 1.
*/
uint8_t GPULSE : 6;
//Gesture Pulse Length. Sets the LED_ON pulse width during a Gesture LDR Pulse.
uint8_t GPLEN : 2;
uint8_t get(){
return (GPLEN << 6) | GPULSE;
}
};
gpulse _gpulse;
struct gconf3 {
/* Gesture Dimension Select. Selects which gesture photodiode pairs are enabled to gather
results during gesture.
*/
uint8_t GDIMS : 2;
uint8_t get(){
return GDIMS;
}
};
gconf3 _gconf3;
struct gconf4 {
/* Gesture Mode. Reading this bit reports if the gesture state machine is actively running, 1
= Gesture, 0= ALS, Proximity, Color. Writing a 1 to this bit causes immediate entry in to the
gesture state machine (as if GPENTH had been exceeded). Writing a 0 to this bit causes exit of
gesture when current analog conversion has finished (as if GEXTH had been exceeded).
*/
uint8_t GMODE : 1;
/* Gesture interrupt enable. Gesture Interrupt Enable. When asserted, all gesture related
interrupts are unmasked.
*/
uint8_t GIEN : 2;
uint8_t get(){
return (GIEN << 1) | GMODE;
}
void set(uint8_t data){
GIEN = (data >> 1) & 0x01;
GMODE = data & 0x01;
}
};
gconf4 _gconf4;
struct gstatus {
/* Gesture FIFO Data. GVALID bit is sent when GFLVL becomes greater than GFIFOTH (i.e. FIFO has
enough data to set GINT). GFIFOD is reset when GMODE = 0 and the GFLVL=0 (i.e. All FIFO data
has been read).
*/
uint8_t GVALID : 1;
/* Gesture FIFO Overflow. A setting of 1 indicates that the FIFO has filled to capacity and that new
gesture detector data has been lost.
*/
uint8_t GFOV : 1;
void set(uint8_t data){
GFOV = (data >> 1) & 0x01;
GVALID = data & 0x01;
}
};
gstatus _gstatus;
};
#endif

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/***************************************************************************
This is a library for the APDS9960 digital proximity, ambient light, RGB, and gesture sensor
This sketch puts the sensor in color mode and reads the RGB and clear values.
Designed specifically to work with the Adafruit APDS9960 breakout
----> http://www.adafruit.com/products/3595
These sensors use I2C to communicate. The device's I2C address is 0x39
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Dean Miller for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#include "Adafruit_APDS9960.h"
Adafruit_APDS9960 apds;
void setup() {
Serial.begin(115200);
if(!apds.begin()){
Serial.println("failed to initialize device! Please check your wiring.");
}
else Serial.println("Device initialized!");
//enable color sensign mode
apds.enableColor(true);
}
void loop() {
//create some variables to store the color data in
uint16_t r, g, b, c;
//wait for color data to be ready
while(!apds.colorDataReady()){
delay(5);
}
//get the data and print the different channels
apds.getColorData(&r, &g, &b, &c);
Serial.print("red: ");
Serial.print(r);
Serial.print(" green: ");
Serial.print(g);
Serial.print(" blue: ");
Serial.print(b);
Serial.print(" clear: ");
Serial.println(c);
Serial.println();
delay(500);
}

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/***************************************************************************
This is a library for the APDS9960 digital proximity, ambient light, RGB, and gesture sensor
This sketch puts the sensor in gesture mode and decodes gestures.
To use this, first put your hand close to the sensor to enable gesture mode.
Then move your hand about 6" from the sensor in the up -> down, down -> up,
left -> right, or right -> left direction.
Designed specifically to work with the Adafruit APDS9960 breakout
----> http://www.adafruit.com/products/3595
These sensors use I2C to communicate. The device's I2C address is 0x39
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Dean Miller for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#include "Adafruit_APDS9960.h"
Adafruit_APDS9960 apds;
// the setup function runs once when you press reset or power the board
void setup() {
Serial.begin(115200);
if(!apds.begin()){
Serial.println("failed to initialize device! Please check your wiring.");
}
else Serial.println("Device initialized!");
//gesture mode will be entered once proximity mode senses something close
apds.enableProximity(true);
apds.enableGesture(true);
}
// the loop function runs over and over again forever
void loop() {
//read a gesture from the device
uint8_t gesture = apds.readGesture();
if(gesture == APDS9960_DOWN) Serial.println("v");
if(gesture == APDS9960_UP) Serial.println("^");
if(gesture == APDS9960_LEFT) Serial.println("<");
if(gesture == APDS9960_RIGHT) Serial.println(">");
}

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/***************************************************************************
This is a library for the APDS9960 digital proximity, ambient light, RGB, and gesture sensor
This sketch puts the sensor in proximity mode and enables the interrupt
to fire when proximity goes over a set value
Designed specifically to work with the Adafruit APDS9960 breakout
----> http://www.adafruit.com/products/3595
These sensors use I2C to communicate. The device's I2C address is 0x39
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Dean Miller for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#include "Adafruit_APDS9960.h"
//the pin that the interrupt is attached to
#define INT_PIN 3
//create the APDS9960 object
Adafruit_APDS9960 apds;
void setup() {
Serial.begin(115200);
pinMode(INT_PIN, INPUT_PULLUP);
if(!apds.begin()){
Serial.println("failed to initialize device! Please check your wiring.");
}
else Serial.println("Device initialized!");
//enable proximity mode
apds.enableProximity(true);
//set the interrupt threshold to fire when proximity reading goes above 175
apds.setProximityInterruptThreshold(0, 175);
//enable the proximity interrupt
apds.enableProximityInterrupt();
}
void loop() {
//print the proximity reading when the interrupt pin goes low
if(!digitalRead(INT_PIN)){
Serial.println(apds.readProximity());
//clear the interrupt
apds.clearInterrupt();
}
}

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name=Adafruit APDS9960 Library
version=1.0.5
author=Adafruit
maintainer=Adafruit <info@adafruit.com>
sentence=This is a library for the Adafruit APDS9960 gesture/proximity/color/light sensor.
paragraph=This is a library for the Adafruit APDS9960 gesture/proximity/color/light sensor.
category=Sensors
url=https://github.com/adafruit/Adafruit_APDS9960
architectures=*

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/***************************************************************************
This is a library for the BME280 humidity, temperature & pressure sensor
Designed specifically to work with the Adafruit BME280 Breakout
----> http://www.adafruit.com/products/2650
These sensors use I2C or SPI to communicate, 2 or 4 pins are required
to interface.
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Limor Fried & Kevin Townsend for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#include "Arduino.h"
#include <Wire.h>
#include <SPI.h>
#include "Adafruit_BME280.h"
/***************************************************************************
PRIVATE FUNCTIONS
***************************************************************************/
Adafruit_BME280::Adafruit_BME280()
: _cs(-1), _mosi(-1), _miso(-1), _sck(-1)
{ }
Adafruit_BME280::Adafruit_BME280(int8_t cspin)
: _cs(cspin), _mosi(-1), _miso(-1), _sck(-1)
{ }
Adafruit_BME280::Adafruit_BME280(int8_t cspin, int8_t mosipin, int8_t misopin, int8_t sckpin)
: _cs(cspin), _mosi(mosipin), _miso(misopin), _sck(sckpin)
{ }
/**************************************************************************/
/*!
@brief Initialise sensor with given parameters / settings
*/
/**************************************************************************/
bool Adafruit_BME280::begin(TwoWire *theWire)
{
_wire = theWire;
_i2caddr = BME280_ADDRESS;
return init();
}
bool Adafruit_BME280::begin(uint8_t addr)
{
_i2caddr = addr;
_wire = &Wire;
return init();
}
bool Adafruit_BME280::begin(uint8_t addr, TwoWire *theWire)
{
_i2caddr = addr;
_wire = theWire;
return init();
}
bool Adafruit_BME280::begin(void)
{
_i2caddr = BME280_ADDRESS;
_wire = &Wire;
return init();
}
bool Adafruit_BME280::init()
{
// init I2C or SPI sensor interface
if (_cs == -1) {
// I2C
_wire -> begin();
} else {
digitalWrite(_cs, HIGH);
pinMode(_cs, OUTPUT);
if (_sck == -1) {
// hardware SPI
SPI.begin();
} else {
// software SPI
pinMode(_sck, OUTPUT);
pinMode(_mosi, OUTPUT);
pinMode(_miso, INPUT);
}
}
// check if sensor, i.e. the chip ID is correct
if (read8(BME280_REGISTER_CHIPID) != 0x60)
return false;
// reset the device using soft-reset
// this makes sure the IIR is off, etc.
write8(BME280_REGISTER_SOFTRESET, 0xB6);
// wait for chip to wake up.
delay(300);
// if chip is still reading calibration, delay
while (isReadingCalibration())
delay(100);
readCoefficients(); // read trimming parameters, see DS 4.2.2
setSampling(); // use defaults
delay(100);
return true;
}
/**************************************************************************/
/*!
@brief setup sensor with given parameters / settings
This is simply a overload to the normal begin()-function, so SPI users
don't get confused about the library requiring an address.
*/
/**************************************************************************/
void Adafruit_BME280::setSampling(sensor_mode mode,
sensor_sampling tempSampling,
sensor_sampling pressSampling,
sensor_sampling humSampling,
sensor_filter filter,
standby_duration duration) {
_measReg.mode = mode;
_measReg.osrs_t = tempSampling;
_measReg.osrs_p = pressSampling;
_humReg.osrs_h = humSampling;
_configReg.filter = filter;
_configReg.t_sb = duration;
// you must make sure to also set REGISTER_CONTROL after setting the
// CONTROLHUMID register, otherwise the values won't be applied (see DS 5.4.3)
write8(BME280_REGISTER_CONTROLHUMID, _humReg.get());
write8(BME280_REGISTER_CONFIG, _configReg.get());
write8(BME280_REGISTER_CONTROL, _measReg.get());
}
/**************************************************************************/
/*!
@brief Encapsulate hardware and software SPI transfer into one function
*/
/**************************************************************************/
uint8_t Adafruit_BME280::spixfer(uint8_t x) {
// hardware SPI
if (_sck == -1)
return SPI.transfer(x);
// software SPI
uint8_t reply = 0;
for (int i=7; i>=0; i--) {
reply <<= 1;
digitalWrite(_sck, LOW);
digitalWrite(_mosi, x & (1<<i));
digitalWrite(_sck, HIGH);
if (digitalRead(_miso))
reply |= 1;
}
return reply;
}
/**************************************************************************/
/*!
@brief Writes an 8 bit value over I2C or SPI
*/
/**************************************************************************/
void Adafruit_BME280::write8(byte reg, byte value) {
if (_cs == -1) {
_wire -> beginTransmission((uint8_t)_i2caddr);
_wire -> write((uint8_t)reg);
_wire -> write((uint8_t)value);
_wire -> endTransmission();
} else {
if (_sck == -1)
SPI.beginTransaction(SPISettings(500000, MSBFIRST, SPI_MODE0));
digitalWrite(_cs, LOW);
spixfer(reg & ~0x80); // write, bit 7 low
spixfer(value);
digitalWrite(_cs, HIGH);
if (_sck == -1)
SPI.endTransaction(); // release the SPI bus
}
}
/**************************************************************************/
/*!
@brief Reads an 8 bit value over I2C or SPI
*/
/**************************************************************************/
uint8_t Adafruit_BME280::read8(byte reg) {
uint8_t value;
if (_cs == -1) {
_wire -> beginTransmission((uint8_t)_i2caddr);
_wire -> write((uint8_t)reg);
_wire -> endTransmission();
_wire -> requestFrom((uint8_t)_i2caddr, (byte)1);
value = _wire -> read();
} else {
if (_sck == -1)
SPI.beginTransaction(SPISettings(500000, MSBFIRST, SPI_MODE0));
digitalWrite(_cs, LOW);
spixfer(reg | 0x80); // read, bit 7 high
value = spixfer(0);
digitalWrite(_cs, HIGH);
if (_sck == -1)
SPI.endTransaction(); // release the SPI bus
}
return value;
}
/**************************************************************************/
/*!
@brief Reads a 16 bit value over I2C or SPI
*/
/**************************************************************************/
uint16_t Adafruit_BME280::read16(byte reg)
{
uint16_t value;
if (_cs == -1) {
_wire -> beginTransmission((uint8_t)_i2caddr);
_wire -> write((uint8_t)reg);
_wire -> endTransmission();
_wire -> requestFrom((uint8_t)_i2caddr, (byte)2);
value = (_wire -> read() << 8) | _wire -> read();
} else {
if (_sck == -1)
SPI.beginTransaction(SPISettings(500000, MSBFIRST, SPI_MODE0));
digitalWrite(_cs, LOW);
spixfer(reg | 0x80); // read, bit 7 high
value = (spixfer(0) << 8) | spixfer(0);
digitalWrite(_cs, HIGH);
if (_sck == -1)
SPI.endTransaction(); // release the SPI bus
}
return value;
}
/**************************************************************************/
/*!
*/
/**************************************************************************/
uint16_t Adafruit_BME280::read16_LE(byte reg) {
uint16_t temp = read16(reg);
return (temp >> 8) | (temp << 8);
}
/**************************************************************************/
/*!
@brief Reads a signed 16 bit value over I2C or SPI
*/
/**************************************************************************/
int16_t Adafruit_BME280::readS16(byte reg)
{
return (int16_t)read16(reg);
}
/**************************************************************************/
/*!
*/
/**************************************************************************/
int16_t Adafruit_BME280::readS16_LE(byte reg)
{
return (int16_t)read16_LE(reg);
}
/**************************************************************************/
/*!
@brief Reads a 24 bit value over I2C
*/
/**************************************************************************/
uint32_t Adafruit_BME280::read24(byte reg)
{
uint32_t value;
if (_cs == -1) {
_wire -> beginTransmission((uint8_t)_i2caddr);
_wire -> write((uint8_t)reg);
_wire -> endTransmission();
_wire -> requestFrom((uint8_t)_i2caddr, (byte)3);
value = _wire -> read();
value <<= 8;
value |= _wire -> read();
value <<= 8;
value |= _wire -> read();
} else {
if (_sck == -1)
SPI.beginTransaction(SPISettings(500000, MSBFIRST, SPI_MODE0));
digitalWrite(_cs, LOW);
spixfer(reg | 0x80); // read, bit 7 high
value = spixfer(0);
value <<= 8;
value |= spixfer(0);
value <<= 8;
value |= spixfer(0);
digitalWrite(_cs, HIGH);
if (_sck == -1)
SPI.endTransaction(); // release the SPI bus
}
return value;
}
/**************************************************************************/
/*!
@brief Take a new measurement (only possible in forced mode)
*/
/**************************************************************************/
void Adafruit_BME280::takeForcedMeasurement()
{
// If we are in forced mode, the BME sensor goes back to sleep after each
// measurement and we need to set it to forced mode once at this point, so
// it will take the next measurement and then return to sleep again.
// In normal mode simply does new measurements periodically.
if (_measReg.mode == MODE_FORCED) {
// set to forced mode, i.e. "take next measurement"
write8(BME280_REGISTER_CONTROL, _measReg.get());
// wait until measurement has been completed, otherwise we would read
// the values from the last measurement
while (read8(BME280_REGISTER_STATUS) & 0x08)
delay(1);
}
}
/**************************************************************************/
/*!
@brief Reads the factory-set coefficients
*/
/**************************************************************************/
void Adafruit_BME280::readCoefficients(void)
{
_bme280_calib.dig_T1 = read16_LE(BME280_REGISTER_DIG_T1);
_bme280_calib.dig_T2 = readS16_LE(BME280_REGISTER_DIG_T2);
_bme280_calib.dig_T3 = readS16_LE(BME280_REGISTER_DIG_T3);
_bme280_calib.dig_P1 = read16_LE(BME280_REGISTER_DIG_P1);
_bme280_calib.dig_P2 = readS16_LE(BME280_REGISTER_DIG_P2);
_bme280_calib.dig_P3 = readS16_LE(BME280_REGISTER_DIG_P3);
_bme280_calib.dig_P4 = readS16_LE(BME280_REGISTER_DIG_P4);
_bme280_calib.dig_P5 = readS16_LE(BME280_REGISTER_DIG_P5);
_bme280_calib.dig_P6 = readS16_LE(BME280_REGISTER_DIG_P6);
_bme280_calib.dig_P7 = readS16_LE(BME280_REGISTER_DIG_P7);
_bme280_calib.dig_P8 = readS16_LE(BME280_REGISTER_DIG_P8);
_bme280_calib.dig_P9 = readS16_LE(BME280_REGISTER_DIG_P9);
_bme280_calib.dig_H1 = read8(BME280_REGISTER_DIG_H1);
_bme280_calib.dig_H2 = readS16_LE(BME280_REGISTER_DIG_H2);
_bme280_calib.dig_H3 = read8(BME280_REGISTER_DIG_H3);
_bme280_calib.dig_H4 = (read8(BME280_REGISTER_DIG_H4) << 4) | (read8(BME280_REGISTER_DIG_H4+1) & 0xF);
_bme280_calib.dig_H5 = (read8(BME280_REGISTER_DIG_H5+1) << 4) | (read8(BME280_REGISTER_DIG_H5) >> 4);
_bme280_calib.dig_H6 = (int8_t)read8(BME280_REGISTER_DIG_H6);
}
/**************************************************************************/
/*!
@brief return true if chip is busy reading cal data
*/
/**************************************************************************/
bool Adafruit_BME280::isReadingCalibration(void)
{
uint8_t const rStatus = read8(BME280_REGISTER_STATUS);
return (rStatus & (1 << 0)) != 0;
}
/**************************************************************************/
/*!
@brief Returns the temperature from the sensor
*/
/**************************************************************************/
float Adafruit_BME280::readTemperature(void)
{
int32_t var1, var2;
int32_t adc_T = read24(BME280_REGISTER_TEMPDATA);
if (adc_T == 0x800000) // value in case temp measurement was disabled
return NAN;
adc_T >>= 4;
var1 = ((((adc_T>>3) - ((int32_t)_bme280_calib.dig_T1 <<1))) *
((int32_t)_bme280_calib.dig_T2)) >> 11;
var2 = (((((adc_T>>4) - ((int32_t)_bme280_calib.dig_T1)) *
((adc_T>>4) - ((int32_t)_bme280_calib.dig_T1))) >> 12) *
((int32_t)_bme280_calib.dig_T3)) >> 14;
t_fine = var1 + var2;
float T = (t_fine * 5 + 128) >> 8;
return T/100;
}
/**************************************************************************/
/*!
@brief Returns the temperature from the sensor
*/
/**************************************************************************/
float Adafruit_BME280::readPressure(void) {
int64_t var1, var2, p;
readTemperature(); // must be done first to get t_fine
int32_t adc_P = read24(BME280_REGISTER_PRESSUREDATA);
if (adc_P == 0x800000) // value in case pressure measurement was disabled
return NAN;
adc_P >>= 4;
var1 = ((int64_t)t_fine) - 128000;
var2 = var1 * var1 * (int64_t)_bme280_calib.dig_P6;
var2 = var2 + ((var1*(int64_t)_bme280_calib.dig_P5)<<17);
var2 = var2 + (((int64_t)_bme280_calib.dig_P4)<<35);
var1 = ((var1 * var1 * (int64_t)_bme280_calib.dig_P3)>>8) +
((var1 * (int64_t)_bme280_calib.dig_P2)<<12);
var1 = (((((int64_t)1)<<47)+var1))*((int64_t)_bme280_calib.dig_P1)>>33;
if (var1 == 0) {
return 0; // avoid exception caused by division by zero
}
p = 1048576 - adc_P;
p = (((p<<31) - var2)*3125) / var1;
var1 = (((int64_t)_bme280_calib.dig_P9) * (p>>13) * (p>>13)) >> 25;
var2 = (((int64_t)_bme280_calib.dig_P8) * p) >> 19;
p = ((p + var1 + var2) >> 8) + (((int64_t)_bme280_calib.dig_P7)<<4);
return (float)p/256;
}
/**************************************************************************/
/*!
@brief Returns the humidity from the sensor
*/
/**************************************************************************/
float Adafruit_BME280::readHumidity(void) {
readTemperature(); // must be done first to get t_fine
int32_t adc_H = read16(BME280_REGISTER_HUMIDDATA);
if (adc_H == 0x8000) // value in case humidity measurement was disabled
return NAN;
int32_t v_x1_u32r;
v_x1_u32r = (t_fine - ((int32_t)76800));
v_x1_u32r = (((((adc_H << 14) - (((int32_t)_bme280_calib.dig_H4) << 20) -
(((int32_t)_bme280_calib.dig_H5) * v_x1_u32r)) + ((int32_t)16384)) >> 15) *
(((((((v_x1_u32r * ((int32_t)_bme280_calib.dig_H6)) >> 10) *
(((v_x1_u32r * ((int32_t)_bme280_calib.dig_H3)) >> 11) + ((int32_t)32768))) >> 10) +
((int32_t)2097152)) * ((int32_t)_bme280_calib.dig_H2) + 8192) >> 14));
v_x1_u32r = (v_x1_u32r - (((((v_x1_u32r >> 15) * (v_x1_u32r >> 15)) >> 7) *
((int32_t)_bme280_calib.dig_H1)) >> 4));
v_x1_u32r = (v_x1_u32r < 0) ? 0 : v_x1_u32r;
v_x1_u32r = (v_x1_u32r > 419430400) ? 419430400 : v_x1_u32r;
float h = (v_x1_u32r>>12);
return h / 1024.0;
}
/**************************************************************************/
/*!
Calculates the altitude (in meters) from the specified atmospheric
pressure (in hPa), and sea-level pressure (in hPa).
@param seaLevel Sea-level pressure in hPa
@param atmospheric Atmospheric pressure in hPa
*/
/**************************************************************************/
float Adafruit_BME280::readAltitude(float seaLevel)
{
// Equation taken from BMP180 datasheet (page 16):
// http://www.adafruit.com/datasheets/BST-BMP180-DS000-09.pdf
// Note that using the equation from wikipedia can give bad results
// at high altitude. See this thread for more information:
// http://forums.adafruit.com/viewtopic.php?f=22&t=58064
float atmospheric = readPressure() / 100.0F;
return 44330.0 * (1.0 - pow(atmospheric / seaLevel, 0.1903));
}
/**************************************************************************/
/*!
Calculates the pressure at sea level (in hPa) from the specified altitude
(in meters), and atmospheric pressure (in hPa).
@param altitude Altitude in meters
@param atmospheric Atmospheric pressure in hPa
*/
/**************************************************************************/
float Adafruit_BME280::seaLevelForAltitude(float altitude, float atmospheric)
{
// Equation taken from BMP180 datasheet (page 17):
// http://www.adafruit.com/datasheets/BST-BMP180-DS000-09.pdf
// Note that using the equation from wikipedia can give bad results
// at high altitude. See this thread for more information:
// http://forums.adafruit.com/viewtopic.php?f=22&t=58064
return atmospheric / pow(1.0 - (altitude/44330.0), 5.255);
}

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/***************************************************************************
This is a library for the BME280 humidity, temperature & pressure sensor
Designed specifically to work with the Adafruit BME280 Breakout
----> http://www.adafruit.com/products/2650
These sensors use I2C or SPI to communicate, 2 or 4 pins are required
to interface.
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Limor Fried & Kevin Townsend for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#ifndef __BME280_H__
#define __BME280_H__
#if (ARDUINO >= 100)
#include "Arduino.h"
#else
#include "WProgram.h"
#endif
#include <Adafruit_Sensor.h>
#include <Wire.h>
/*=========================================================================
I2C ADDRESS/BITS
-----------------------------------------------------------------------*/
#define BME280_ADDRESS (0x77)
/*=========================================================================*/
/*=========================================================================
REGISTERS
-----------------------------------------------------------------------*/
enum
{
BME280_REGISTER_DIG_T1 = 0x88,
BME280_REGISTER_DIG_T2 = 0x8A,
BME280_REGISTER_DIG_T3 = 0x8C,
BME280_REGISTER_DIG_P1 = 0x8E,
BME280_REGISTER_DIG_P2 = 0x90,
BME280_REGISTER_DIG_P3 = 0x92,
BME280_REGISTER_DIG_P4 = 0x94,
BME280_REGISTER_DIG_P5 = 0x96,
BME280_REGISTER_DIG_P6 = 0x98,
BME280_REGISTER_DIG_P7 = 0x9A,
BME280_REGISTER_DIG_P8 = 0x9C,
BME280_REGISTER_DIG_P9 = 0x9E,
BME280_REGISTER_DIG_H1 = 0xA1,
BME280_REGISTER_DIG_H2 = 0xE1,
BME280_REGISTER_DIG_H3 = 0xE3,
BME280_REGISTER_DIG_H4 = 0xE4,
BME280_REGISTER_DIG_H5 = 0xE5,
BME280_REGISTER_DIG_H6 = 0xE7,
BME280_REGISTER_CHIPID = 0xD0,
BME280_REGISTER_VERSION = 0xD1,
BME280_REGISTER_SOFTRESET = 0xE0,
BME280_REGISTER_CAL26 = 0xE1, // R calibration stored in 0xE1-0xF0
BME280_REGISTER_CONTROLHUMID = 0xF2,
BME280_REGISTER_STATUS = 0XF3,
BME280_REGISTER_CONTROL = 0xF4,
BME280_REGISTER_CONFIG = 0xF5,
BME280_REGISTER_PRESSUREDATA = 0xF7,
BME280_REGISTER_TEMPDATA = 0xFA,
BME280_REGISTER_HUMIDDATA = 0xFD
};
/*=========================================================================*/
/*=========================================================================
CALIBRATION DATA
-----------------------------------------------------------------------*/
typedef struct
{
uint16_t dig_T1;
int16_t dig_T2;
int16_t dig_T3;
uint16_t dig_P1;
int16_t dig_P2;
int16_t dig_P3;
int16_t dig_P4;
int16_t dig_P5;
int16_t dig_P6;
int16_t dig_P7;
int16_t dig_P8;
int16_t dig_P9;
uint8_t dig_H1;
int16_t dig_H2;
uint8_t dig_H3;
int16_t dig_H4;
int16_t dig_H5;
int8_t dig_H6;
} bme280_calib_data;
/*=========================================================================*/
/*
class Adafruit_BME280_Unified : public Adafruit_Sensor
{
public:
Adafruit_BME280_Unified(int32_t sensorID = -1);
bool begin(uint8_t addr = BME280_ADDRESS);
void getTemperature(float *temp);
void getPressure(float *pressure);
float pressureToAltitude(float seaLevel, float atmospheric, float temp);
float seaLevelForAltitude(float altitude, float atmospheric, float temp);
void getEvent(sensors_event_t*);
void getSensor(sensor_t*);
private:
uint8_t _i2c_addr;
int32_t _sensorID;
};
*/
class Adafruit_BME280 {
public:
enum sensor_sampling {
SAMPLING_NONE = 0b000,
SAMPLING_X1 = 0b001,
SAMPLING_X2 = 0b010,
SAMPLING_X4 = 0b011,
SAMPLING_X8 = 0b100,
SAMPLING_X16 = 0b101
};
enum sensor_mode {
MODE_SLEEP = 0b00,
MODE_FORCED = 0b01,
MODE_NORMAL = 0b11
};
enum sensor_filter {
FILTER_OFF = 0b000,
FILTER_X2 = 0b001,
FILTER_X4 = 0b010,
FILTER_X8 = 0b011,
FILTER_X16 = 0b100
};
// standby durations in ms
enum standby_duration {
STANDBY_MS_0_5 = 0b000,
STANDBY_MS_10 = 0b110,
STANDBY_MS_20 = 0b111,
STANDBY_MS_62_5 = 0b001,
STANDBY_MS_125 = 0b010,
STANDBY_MS_250 = 0b011,
STANDBY_MS_500 = 0b100,
STANDBY_MS_1000 = 0b101
};
// constructors
Adafruit_BME280(void);
Adafruit_BME280(int8_t cspin);
Adafruit_BME280(int8_t cspin, int8_t mosipin, int8_t misopin, int8_t sckpin);
bool begin(void);
bool begin(TwoWire *theWire);
bool begin(uint8_t addr);
bool begin(uint8_t addr, TwoWire *theWire);
bool init();
void setSampling(sensor_mode mode = MODE_NORMAL,
sensor_sampling tempSampling = SAMPLING_X16,
sensor_sampling pressSampling = SAMPLING_X16,
sensor_sampling humSampling = SAMPLING_X16,
sensor_filter filter = FILTER_OFF,
standby_duration duration = STANDBY_MS_0_5
);
void takeForcedMeasurement();
float readTemperature(void);
float readPressure(void);
float readHumidity(void);
float readAltitude(float seaLevel);
float seaLevelForAltitude(float altitude, float pressure);
private:
TwoWire *_wire;
void readCoefficients(void);
bool isReadingCalibration(void);
uint8_t spixfer(uint8_t x);
void write8(byte reg, byte value);
uint8_t read8(byte reg);
uint16_t read16(byte reg);
uint32_t read24(byte reg);
int16_t readS16(byte reg);
uint16_t read16_LE(byte reg); // little endian
int16_t readS16_LE(byte reg); // little endian
uint8_t _i2caddr;
int32_t _sensorID;
int32_t t_fine;
int8_t _cs, _mosi, _miso, _sck;
bme280_calib_data _bme280_calib;
// The config register
struct config {
// inactive duration (standby time) in normal mode
// 000 = 0.5 ms
// 001 = 62.5 ms
// 010 = 125 ms
// 011 = 250 ms
// 100 = 500 ms
// 101 = 1000 ms
// 110 = 10 ms
// 111 = 20 ms
unsigned int t_sb : 3;
// filter settings
// 000 = filter off
// 001 = 2x filter
// 010 = 4x filter
// 011 = 8x filter
// 100 and above = 16x filter
unsigned int filter : 3;
// unused - don't set
unsigned int none : 1;
unsigned int spi3w_en : 1;
unsigned int get() {
return (t_sb << 5) | (filter << 3) | spi3w_en;
}
};
config _configReg;
// The ctrl_meas register
struct ctrl_meas {
// temperature oversampling
// 000 = skipped
// 001 = x1
// 010 = x2
// 011 = x4
// 100 = x8
// 101 and above = x16
unsigned int osrs_t : 3;
// pressure oversampling
// 000 = skipped
// 001 = x1
// 010 = x2
// 011 = x4
// 100 = x8
// 101 and above = x16
unsigned int osrs_p : 3;
// device mode
// 00 = sleep
// 01 or 10 = forced
// 11 = normal
unsigned int mode : 2;
unsigned int get() {
return (osrs_t << 5) | (osrs_p << 3) | mode;
}
};
ctrl_meas _measReg;
// The ctrl_hum register
struct ctrl_hum {
// unused - don't set
unsigned int none : 5;
// pressure oversampling
// 000 = skipped
// 001 = x1
// 010 = x2
// 011 = x4
// 100 = x8
// 101 and above = x16
unsigned int osrs_h : 3;
unsigned int get() {
return (osrs_h);
}
};
ctrl_hum _humReg;
};
#endif

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This is a library for the Adafruit BME280 Humidity, Barometric Pressure + Temp sensor
Designed specifically to work with the Adafruit BME280 Breakout
* http://www.adafruit.com/products/2652
These sensors use I2C or SPI to communicate, up to 4 pins are required to interface
Use of this library also requires [Adafruit_Sensor](https://github.com/adafruit/Adafruit_Sensor)
to be installed on your local system.
Adafruit invests time and resources providing this open source code,
please support Adafruit and open-source hardware by purchasing
products from Adafruit!
Check out the links above for our tutorials and wiring diagrams
Written by Limor Fried/Ladyada for Adafruit Industries.
BSD license, all text above must be included in any redistribution
To download. click the DOWNLOAD ZIP button, rename the uncompressed folder Adafruit_BME280.
Check that the Adafruit_BME280 folder contains Adafruit_BME280.cpp and Adafruit_BME280.h
Place the Adafruit_BME280 library folder your arduinosketchfolder/libraries/ folder.
You may need to create the libraries subfolder if its your first library. Restart the IDE.
We also have a great tutorial on Arduino library installation at:
http://learn.adafruit.com/adafruit-all-about-arduino-libraries-install-use
<!-- START COMPATIBILITY TABLE -->
## Compatibility
MCU | Tested Works | Doesn't Work | Not Tested | Notes
------------------ | :----------: | :----------: | :---------: | -----
Atmega328 @ 16MHz | X | | |
Atmega328 @ 12MHz | X | | |
Atmega32u4 @ 16MHz | X | | | Use SDA/SCL on pins D2 &amp; D3
Atmega32u4 @ 8MHz | X | | | Use SDA/SCL on pins D2 &amp; D3
ESP8266 | X | | | I2C: just works, SPI: SDA/SCL default to pins 4 &amp; 5 but any two pins can be assigned as SDA/SCL using Wire.begin(SDA,SCL)
ESP32 | X | | | I2C: just works, SPI: SDA/SCL default to pins 4 &amp; 5 but any two pins can be assigned as SDA/SCL using Wire.begin(SDA,SCL)
Atmega2560 @ 16MHz | X | | | Use SDA/SCL on pins 20 &amp; 21
ATSAM3X8E | X | | | Use SDA/SCL on pins 20 &amp; 21
ATSAM21D | X | | |
ATtiny85 @ 16MHz | | X | |
ATtiny85 @ 8MHz | | X | |
Intel Curie @ 32MHz | | | X |
STM32F2 | | | X |
* ATmega328 @ 16MHz : Arduino UNO, Adafruit Pro Trinket 5V, Adafruit Metro 328, Adafruit Metro Mini
* ATmega328 @ 12MHz : Adafruit Pro Trinket 3V
* ATmega32u4 @ 16MHz : Arduino Leonardo, Arduino Micro, Arduino Yun, Teensy 2.0
* ATmega32u4 @ 8MHz : Adafruit Flora, Bluefruit Micro
* ESP8266 : Adafruit Huzzah
* ATmega2560 @ 16MHz : Arduino Mega
* ATSAM3X8E : Arduino Due
* ATSAM21D : Arduino Zero, M0 Pro
* ATtiny85 @ 16MHz : Adafruit Trinket 5V
* ATtiny85 @ 8MHz : Adafruit Gemma, Arduino Gemma, Adafruit Trinket 3V
<!-- END COMPATIBILITY TABLE -->

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/***************************************************************************
This is a library for the BME280 humidity, temperature & pressure sensor
Designed specifically to work with the Adafruit BME280 Breakout
----> http://www.adafruit.com/products/2650
These sensors use I2C or SPI to communicate, 2 or 4 pins are required
to interface. The device's I2C address is either 0x76 or 0x77.
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Limor Fried & Kevin Townsend for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#include <Wire.h>
#include <SPI.h>
#include <Adafruit_Sensor.h>
#include <Adafruit_BME280.h>
#define BME_SCK 13
#define BME_MISO 12
#define BME_MOSI 11
#define BME_CS 10
#define SEALEVELPRESSURE_HPA (1013.25)
Adafruit_BME280 bme; // I2C
//Adafruit_BME280 bme(BME_CS); // hardware SPI
//Adafruit_BME280 bme(BME_CS, BME_MOSI, BME_MISO, BME_SCK); // software SPI
unsigned long delayTime;
void setup() {
Serial.begin(9600);
Serial.println(F("BME280 test"));
if (! bme.begin(&Wire1)) {
Serial.println("Could not find a valid BME280 sensor, check wiring!");
while (1);
}
Serial.println("-- Default Test --");
Serial.println("normal mode, 16x oversampling for all, filter off,");
Serial.println("0.5ms standby period");
delayTime = 5000;
// For more details on the following scenarious, see chapter
// 3.5 "Recommended modes of operation" in the datasheet
/*
// weather monitoring
Serial.println("-- Weather Station Scenario --");
Serial.println("forced mode, 1x temperature / 1x humidity / 1x pressure oversampling,");
Serial.println("filter off");
bme.setSampling(Adafruit_BME280::MODE_FORCED,
Adafruit_BME280::SAMPLING_X1, // temperature
Adafruit_BME280::SAMPLING_X1, // pressure
Adafruit_BME280::SAMPLING_X1, // humidity
Adafruit_BME280::FILTER_OFF );
// suggested rate is 1/60Hz (1m)
delayTime = 60000; // in milliseconds
*/
/*
// humidity sensing
Serial.println("-- Humidity Sensing Scenario --");
Serial.println("forced mode, 1x temperature / 1x humidity / 0x pressure oversampling");
Serial.println("= pressure off, filter off");
bme.setSampling(Adafruit_BME280::MODE_FORCED,
Adafruit_BME280::SAMPLING_X1, // temperature
Adafruit_BME280::SAMPLING_NONE, // pressure
Adafruit_BME280::SAMPLING_X1, // humidity
Adafruit_BME280::FILTER_OFF );
// suggested rate is 1Hz (1s)
delayTime = 1000; // in milliseconds
*/
/*
// indoor navigation
Serial.println("-- Indoor Navigation Scenario --");
Serial.println("normal mode, 16x pressure / 2x temperature / 1x humidity oversampling,");
Serial.println("0.5ms standby period, filter 16x");
bme.setSampling(Adafruit_BME280::MODE_NORMAL,
Adafruit_BME280::SAMPLING_X2, // temperature
Adafruit_BME280::SAMPLING_X16, // pressure
Adafruit_BME280::SAMPLING_X1, // humidity
Adafruit_BME280::FILTER_X16,
Adafruit_BME280::STANDBY_MS_0_5 );
// suggested rate is 25Hz
// 1 + (2 * T_ovs) + (2 * P_ovs + 0.5) + (2 * H_ovs + 0.5)
// T_ovs = 2
// P_ovs = 16
// H_ovs = 1
// = 40ms (25Hz)
// with standby time that should really be 24.16913... Hz
delayTime = 41;
/*
// gaming
Serial.println("-- Gaming Scenario --");
Serial.println("normal mode, 4x pressure / 1x temperature / 0x humidity oversampling,");
Serial.println("= humidity off, 0.5ms standby period, filter 16x");
bme.setSampling(Adafruit_BME280::MODE_NORMAL,
Adafruit_BME280::SAMPLING_X1, // temperature
Adafruit_BME280::SAMPLING_X4, // pressure
Adafruit_BME280::SAMPLING_NONE, // humidity
Adafruit_BME280::FILTER_X16,
Adafruit_BME280::STANDBY_MS_0_5 );
// Suggested rate is 83Hz
// 1 + (2 * T_ovs) + (2 * P_ovs + 0.5)
// T_ovs = 1
// P_ovs = 4
// = 11.5ms + 0.5ms standby
delayTime = 12;
*/
Serial.println();
}
void loop() {
// Only needed in forced mode! In normal mode, you can remove the next line.
bme.takeForcedMeasurement(); // has no effect in normal mode
printValues();
delay(delayTime);
}
void printValues() {
Serial.print("Temperature = ");
Serial.print(bme.readTemperature());
Serial.println(" *C");
Serial.print("Pressure = ");
Serial.print(bme.readPressure() / 100.0F);
Serial.println(" hPa");
Serial.print("Approx. Altitude = ");
Serial.print(bme.readAltitude(SEALEVELPRESSURE_HPA));
Serial.println(" m");
Serial.print("Humidity = ");
Serial.print(bme.readHumidity());
Serial.println(" %");
Serial.println();
}

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/***************************************************************************
This is a library for the BME280 humidity, temperature & pressure sensor
Designed specifically to work with the Adafruit BME280 Breakout
----> http://www.adafruit.com/products/2650
These sensors use I2C or SPI to communicate, 2 or 4 pins are required
to interface. The device's I2C address is either 0x76 or 0x77.
Adafruit invests time and resources providing this open source code,
please support Adafruit andopen-source hardware by purchasing products
from Adafruit!
Written by Limor Fried & Kevin Townsend for Adafruit Industries.
BSD license, all text above must be included in any redistribution
***************************************************************************/
#include <Wire.h>
#include <SPI.h>
#include <Adafruit_Sensor.h>
#include <Adafruit_BME280.h>
#define BME_SCK 13
#define BME_MISO 12
#define BME_MOSI 11
#define BME_CS 10
#define SEALEVELPRESSURE_HPA (1013.25)
Adafruit_BME280 bme; // I2C
//Adafruit_BME280 bme(BME_CS); // hardware SPI
//Adafruit_BME280 bme(BME_CS, BME_MOSI, BME_MISO, BME_SCK); // software SPI
unsigned long delayTime;
void setup() {
Serial.begin(9600);
Serial.println(F("BME280 test"));
bool status;
// default settings
// (you can also pass in a Wire library object like &Wire2)
status = bme.begin();
if (!status) {
Serial.println("Could not find a valid BME280 sensor, check wiring!");
while (1);
}
Serial.println("-- Default Test --");
delayTime = 1000;
Serial.println();
}
void loop() {
printValues();
delay(delayTime);
}
void printValues() {
Serial.print("Temperature = ");
Serial.print(bme.readTemperature());
Serial.println(" *C");
Serial.print("Pressure = ");
Serial.print(bme.readPressure() / 100.0F);
Serial.println(" hPa");
Serial.print("Approx. Altitude = ");
Serial.print(bme.readAltitude(SEALEVELPRESSURE_HPA));
Serial.println(" m");
Serial.print("Humidity = ");
Serial.print(bme.readHumidity());
Serial.println(" %");
Serial.println();
}

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name=Adafruit BME280 Library
version=1.0.7
author=Adafruit
maintainer=Adafruit <info@adafruit.com>
sentence=Arduino library for BME280 sensors.
paragraph=Arduino library for BME280 humidity and pressure sensors.
category=Sensors
url=https://github.com/adafruit/Adafruit_BME280_Library
architectures=*

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/*
* Copyright (C) 2008 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software< /span>
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* Update by K. Townsend (Adafruit Industries) for lighter typedefs, and
* extended sensor support to include color, voltage and current */
#ifndef _ADAFRUIT_SENSOR_H
#define _ADAFRUIT_SENSOR_H
#if ARDUINO >= 100
#include "Arduino.h"
#include "Print.h"
#else
#include "WProgram.h"
#endif
/* Intentionally modeled after sensors.h in the Android API:
* https://github.com/android/platform_hardware_libhardware/blob/master/include/hardware/sensors.h */
/* Constants */
#define SENSORS_GRAVITY_EARTH (9.80665F) /**< Earth's gravity in m/s^2 */
#define SENSORS_GRAVITY_MOON (1.6F) /**< The moon's gravity in m/s^2 */
#define SENSORS_GRAVITY_SUN (275.0F) /**< The sun's gravity in m/s^2 */
#define SENSORS_GRAVITY_STANDARD (SENSORS_GRAVITY_EARTH)
#define SENSORS_MAGFIELD_EARTH_MAX (60.0F) /**< Maximum magnetic field on Earth's surface */
#define SENSORS_MAGFIELD_EARTH_MIN (30.0F) /**< Minimum magnetic field on Earth's surface */
#define SENSORS_PRESSURE_SEALEVELHPA (1013.25F) /**< Average sea level pressure is 1013.25 hPa */
#define SENSORS_DPS_TO_RADS (0.017453293F) /**< Degrees/s to rad/s multiplier */
#define SENSORS_GAUSS_TO_MICROTESLA (100) /**< Gauss to micro-Tesla multiplier */
/** Sensor types */
typedef enum
{
SENSOR_TYPE_ACCELEROMETER = (1), /**< Gravity + linear acceleration */
SENSOR_TYPE_MAGNETIC_FIELD = (2),
SENSOR_TYPE_ORIENTATION = (3),
SENSOR_TYPE_GYROSCOPE = (4),
SENSOR_TYPE_LIGHT = (5),
SENSOR_TYPE_PRESSURE = (6),
SENSOR_TYPE_PROXIMITY = (8),
SENSOR_TYPE_GRAVITY = (9),
SENSOR_TYPE_LINEAR_ACCELERATION = (10), /**< Acceleration not including gravity */
SENSOR_TYPE_ROTATION_VECTOR = (11),
SENSOR_TYPE_RELATIVE_HUMIDITY = (12),
SENSOR_TYPE_AMBIENT_TEMPERATURE = (13),
SENSOR_TYPE_VOLTAGE = (15),
SENSOR_TYPE_CURRENT = (16),
SENSOR_TYPE_COLOR = (17)
} sensors_type_t;
/** struct sensors_vec_s is used to return a vector in a common format. */
typedef struct {
union {
float v[3];
struct {
float x;
float y;
float z;
};
/* Orientation sensors */
struct {
float roll; /**< Rotation around the longitudinal axis (the plane body, 'X axis'). Roll is positive and increasing when moving downward. -90°<=roll<=90° */
float pitch; /**< Rotation around the lateral axis (the wing span, 'Y axis'). Pitch is positive and increasing when moving upwards. -180°<=pitch<=180°) */
float heading; /**< Angle between the longitudinal axis (the plane body) and magnetic north, measured clockwise when viewing from the top of the device. 0-359° */
};
};
int8_t status;
uint8_t reserved[3];
} sensors_vec_t;
/** struct sensors_color_s is used to return color data in a common format. */
typedef struct {
union {
float c[3];
/* RGB color space */
struct {
float r; /**< Red component */
float g; /**< Green component */
float b; /**< Blue component */
};
};
uint32_t rgba; /**< 24-bit RGBA value */
} sensors_color_t;
/* Sensor event (36 bytes) */
/** struct sensor_event_s is used to provide a single sensor event in a common format. */
typedef struct
{
int32_t version; /**< must be sizeof(struct sensors_event_t) */
int32_t sensor_id; /**< unique sensor identifier */
int32_t type; /**< sensor type */
int32_t reserved0; /**< reserved */
int32_t timestamp; /**< time is in milliseconds */
union
{
float data[4];
sensors_vec_t acceleration; /**< acceleration values are in meter per second per second (m/s^2) */
sensors_vec_t magnetic; /**< magnetic vector values are in micro-Tesla (uT) */
sensors_vec_t orientation; /**< orientation values are in degrees */
sensors_vec_t gyro; /**< gyroscope values are in rad/s */
float temperature; /**< temperature is in degrees centigrade (Celsius) */
float distance; /**< distance in centimeters */
float light; /**< light in SI lux units */
float pressure; /**< pressure in hectopascal (hPa) */
float relative_humidity; /**< relative humidity in percent */
float current; /**< current in milliamps (mA) */
float voltage; /**< voltage in volts (V) */
sensors_color_t color; /**< color in RGB component values */
};
} sensors_event_t;
/* Sensor details (40 bytes) */
/** struct sensor_s is used to describe basic information about a specific sensor. */
typedef struct
{
char name[12]; /**< sensor name */
int32_t version; /**< version of the hardware + driver */
int32_t sensor_id; /**< unique sensor identifier */
int32_t type; /**< this sensor's type (ex. SENSOR_TYPE_LIGHT) */
float max_value; /**< maximum value of this sensor's value in SI units */
float min_value; /**< minimum value of this sensor's value in SI units */
float resolution; /**< smallest difference between two values reported by this sensor */
int32_t min_delay; /**< min delay in microseconds between events. zero = not a constant rate */
} sensor_t;
class Adafruit_Sensor {
public:
// Constructor(s)
Adafruit_Sensor() {}
virtual ~Adafruit_Sensor() {}
// These must be defined by the subclass
virtual void enableAutoRange(bool enabled) {};
virtual bool getEvent(sensors_event_t*) = 0;
virtual void getSensor(sensor_t*) = 0;
private:
bool _autoRange;
};
#endif

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@ -0,0 +1,218 @@
# Adafruit Unified Sensor Driver #
Many small embedded systems exist to collect data from sensors, analyse the data, and either take an appropriate action or send that sensor data to another system for processing.
One of the many challenges of embedded systems design is the fact that parts you used today may be out of production tomorrow, or system requirements may change and you may need to choose a different sensor down the road.
Creating new drivers is a relatively easy task, but integrating them into existing systems is both error prone and time consuming since sensors rarely use the exact same units of measurement.
By reducing all data to a single **sensors\_event\_t** 'type' and settling on specific, **standardised SI units** for each sensor family the same sensor types return values that are comparable with any other similar sensor. This enables you to switch sensor models with very little impact on the rest of the system, which can help mitigate some of the risks and problems of sensor availability and code reuse.
The unified sensor abstraction layer is also useful for data-logging and data-transmission since you only have one well-known type to log or transmit over the air or wire.
## Unified Sensor Drivers ##
The following drivers are based on the Adafruit Unified Sensor Driver:
**Accelerometers**
- [Adafruit\_ADXL345](https://github.com/adafruit/Adafruit_ADXL345)
- [Adafruit\_LSM303DLHC](https://github.com/adafruit/Adafruit_LSM303DLHC)
- [Adafruit\_MMA8451\_Library](https://github.com/adafruit/Adafruit_MMA8451_Library)
**Gyroscope**
- [Adafruit\_L3GD20\_U](https://github.com/adafruit/Adafruit_L3GD20_U)
**Light**
- [Adafruit\_TSL2561](https://github.com/adafruit/Adafruit_TSL2561)
- [Adafruit\_TSL2591\_Library](https://github.com/adafruit/Adafruit_TSL2591_Library)
**Magnetometers**
- [Adafruit\_LSM303DLHC](https://github.com/adafruit/Adafruit_LSM303DLHC)
- [Adafruit\_HMC5883\_Unified](https://github.com/adafruit/Adafruit_HMC5883_Unified)
**Barometric Pressure**
- [Adafruit\_BMP085\_Unified](https://github.com/adafruit/Adafruit_BMP085_Unified)
- [Adafruit\_BMP183\_Unified\_Library](https://github.com/adafruit/Adafruit_BMP183_Unified_Library)
**Humidity & Temperature**
- [Adafruit\_DHT\_Unified](https://github.com/adafruit/Adafruit_DHT_Unified)
## How Does it Work? ##
Any driver that supports the Adafruit unified sensor abstraction layer will implement the Adafruit\_Sensor base class. There are two main typedefs and one enum defined in Adafruit_Sensor.h that are used to 'abstract' away the sensor details and values:
**Sensor Types (sensors\_type\_t)**
These pre-defined sensor types are used to properly handle the two related typedefs below, and allows us determine what types of units the sensor uses, etc.
```
/** Sensor types */
typedef enum
{
SENSOR_TYPE_ACCELEROMETER = (1),
SENSOR_TYPE_MAGNETIC_FIELD = (2),
SENSOR_TYPE_ORIENTATION = (3),
SENSOR_TYPE_GYROSCOPE = (4),
SENSOR_TYPE_LIGHT = (5),
SENSOR_TYPE_PRESSURE = (6),
SENSOR_TYPE_PROXIMITY = (8),
SENSOR_TYPE_GRAVITY = (9),
SENSOR_TYPE_LINEAR_ACCELERATION = (10),
SENSOR_TYPE_ROTATION_VECTOR = (11),
SENSOR_TYPE_RELATIVE_HUMIDITY = (12),
SENSOR_TYPE_AMBIENT_TEMPERATURE = (13),
SENSOR_TYPE_VOLTAGE = (15),
SENSOR_TYPE_CURRENT = (16),
SENSOR_TYPE_COLOR = (17)
} sensors_type_t;
```
**Sensor Details (sensor\_t)**
This typedef describes the specific capabilities of this sensor, and allows us to know what sensor we are using beneath the abstraction layer.
```
/* Sensor details (40 bytes) */
/** struct sensor_s is used to describe basic information about a specific sensor. */
typedef struct
{
char name[12];
int32_t version;
int32_t sensor_id;
int32_t type;
float max_value;
float min_value;
float resolution;
int32_t min_delay;
} sensor_t;
```
The individual fields are intended to be used as follows:
- **name**: The sensor name or ID, up to a maximum of twelve characters (ex. "MPL115A2")
- **version**: The version of the sensor HW and the driver to allow us to differentiate versions of the board or driver
- **sensor\_id**: A unique sensor identifier that is used to differentiate this specific sensor instance from any others that are present on the system or in the sensor network
- **type**: The sensor type, based on **sensors\_type\_t** in sensors.h
- **max\_value**: The maximum value that this sensor can return (in the appropriate SI unit)
- **min\_value**: The minimum value that this sensor can return (in the appropriate SI unit)
- **resolution**: The smallest difference between two values that this sensor can report (in the appropriate SI unit)
- **min\_delay**: The minimum delay in microseconds between two sensor events, or '0' if there is no constant sensor rate
**Sensor Data/Events (sensors\_event\_t)**
This typedef is used to return sensor data from any sensor supported by the abstraction layer, using standard SI units and scales.
```
/* Sensor event (36 bytes) */
/** struct sensor_event_s is used to provide a single sensor event in a common format. */
typedef struct
{
int32_t version;
int32_t sensor_id;
int32_t type;
int32_t reserved0;
int32_t timestamp;
union
{
float data[4];
sensors_vec_t acceleration;
sensors_vec_t magnetic;
sensors_vec_t orientation;
sensors_vec_t gyro;
float temperature;
float distance;
float light;
float pressure;
float relative_humidity;
float current;
float voltage;
sensors_color_t color;
};
} sensors_event_t;
```
It includes the following fields:
- **version**: Contain 'sizeof(sensors\_event\_t)' to identify which version of the API we're using in case this changes in the future
- **sensor\_id**: A unique sensor identifier that is used to differentiate this specific sensor instance from any others that are present on the system or in the sensor network (must match the sensor\_id value in the corresponding sensor\_t enum above!)
- **type**: the sensor type, based on **sensors\_type\_t** in sensors.h
- **timestamp**: time in milliseconds when the sensor value was read
- **data[4]**: An array of four 32-bit values that allows us to encapsulate any type of sensor data via a simple union (further described below)
**Required Functions**
In addition to the two standard types and the sensor type enum, all drivers based on Adafruit_Sensor must also implement the following two functions:
```
bool getEvent(sensors_event_t*);
```
Calling this function will populate the supplied sensors\_event\_t reference with the latest available sensor data. You should call this function as often as you want to update your data.
```
void getSensor(sensor_t*);
```
Calling this function will provide some basic information about the sensor (the sensor name, driver version, min and max values, etc.
**Standardised SI values for sensors\_event\_t**
A key part of the abstraction layer is the standardisation of values on SI units of a particular scale, which is accomplished via the data[4] union in sensors\_event\_t above. This 16 byte union includes fields for each main sensor type, and uses the following SI units and scales:
- **acceleration**: values are in **meter per second per second** (m/s^2)
- **magnetic**: values are in **micro-Tesla** (uT)
- **orientation**: values are in **degrees**
- **gyro**: values are in **rad/s**
- **temperature**: values in **degrees centigrade** (Celsius)
- **distance**: values are in **centimeters**
- **light**: values are in **SI lux** units
- **pressure**: values are in **hectopascal** (hPa)
- **relative\_humidity**: values are in **percent**
- **current**: values are in **milliamps** (mA)
- **voltage**: values are in **volts** (V)
- **color**: values are in 0..1.0 RGB channel luminosity and 32-bit RGBA format
## The Unified Driver Abstraction Layer in Practice ##
Using the unified sensor abstraction layer is relatively easy once a compliant driver has been created.
Every compliant sensor can now be read using a single, well-known 'type' (sensors\_event\_t), and there is a standardised way of interrogating a sensor about its specific capabilities (via sensor\_t).
An example of reading the [TSL2561](https://github.com/adafruit/Adafruit_TSL2561) light sensor can be seen below:
```
Adafruit_TSL2561 tsl = Adafruit_TSL2561(TSL2561_ADDR_FLOAT, 12345);
...
/* Get a new sensor event */
sensors_event_t event;
tsl.getEvent(&event);
/* Display the results (light is measured in lux) */
if (event.light)
{
Serial.print(event.light); Serial.println(" lux");
}
else
{
/* If event.light = 0 lux the sensor is probably saturated
and no reliable data could be generated! */
Serial.println("Sensor overload");
}
```
Similarly, we can get the basic technical capabilities of this sensor with the following code:
```
sensor_t sensor;
sensor_t sensor;
tsl.getSensor(&sensor);
/* Display the sensor details */
Serial.println("------------------------------------");
Serial.print ("Sensor: "); Serial.println(sensor.name);
Serial.print ("Driver Ver: "); Serial.println(sensor.version);
Serial.print ("Unique ID: "); Serial.println(sensor.sensor_id);
Serial.print ("Max Value: "); Serial.print(sensor.max_value); Serial.println(" lux");
Serial.print ("Min Value: "); Serial.print(sensor.min_value); Serial.println(" lux");
Serial.print ("Resolution: "); Serial.print(sensor.resolution); Serial.println(" lux");
Serial.println("------------------------------------");
Serial.println("");
```

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name=Adafruit Unified Sensor
version=1.0.2
author=Adafruit <info@adafruit.com>
maintainer=Adafruit <info@adafruit.com>
sentence=Required for all Adafruit Unified Sensor based libraries.
paragraph=A unified sensor abstraction layer used by many Adafruit sensor libraries.
category=Sensors
url=https://github.com/adafruit/Adafruit_Sensor
architectures=*

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#include "Arduino.h"
#include "ESP8266Influxdb.h"
#include <ESP8266WiFi.h>
#define DEBUG_PRINT // comment this line to disable debug print
#ifndef DEBUG_PRINT
#define DEBUG_PRINT(a)
#else
#define DEBUG_PRINT(a) (Serial.println(String(F("[Debug]: "))+(a)))
#define _DEBUG
#endif
Influxdb::Influxdb(const char *host, uint16_t port) : WiFiClient() {
_port = port;
_host = host;
}
DB_RESPONSE Influxdb::opendb(String db, String user, String password) {
_db = "db=" + db + "&u=" + user + "&p=" + password;
}
DB_RESPONSE Influxdb::opendb(String db) {
_db = "db=" + db;
}
DB_RESPONSE Influxdb::write(FIELD data) {
return write(data.postString());
}
DB_RESPONSE Influxdb::write(String data) {
if (!connect(_host, _port)) {
DEBUG_PRINT("connection failed");
_response = DB_CONNECT_FAILED;
return _response;
}
String postHead = "POST /write?" + _db + " HTTP/1.1\r\n";
postHead += "Host: " + String(_host) + ":" + String(_port) + "\r\n";
// postHead += "Content-Type: application/x-www-form-urlencoded\r\n";
postHead += "Content-Length: " + String(data.length()) + "\r\n\r\n";
DEBUG_PRINT("Writing data to " + String(_host) + ":" + String(_port));
print(postHead + data);
DEBUG_PRINT(postHead + data);
uint8_t t = 0;
// Check the reply whether writing is success or not
while (!available() && t < 200) {
delay(10);
t++;
}
if (t==200) {_response = DB_ERROR; return DB_ERROR; } // Return error if time out.
#if !defined _DEBUG
if (available()) {
_response = (findUntil("204", "\r")) ? DB_SUCCESS : DB_ERROR;
return _response;
}
#else
_response=DB_ERROR;
while (available()) {
String line = readStringUntil('\n');
if (line.substring(9,12)=="204")
_response = DB_SUCCESS;
DEBUG_PRINT("(Responsed): " + line);
}
return _response;
#endif
return DB_ERROR;
}
DB_RESPONSE Influxdb::query(String sql) {
if (!connect(_host, _port)) {
DEBUG_PRINT("connection failed");
_response = DB_CONNECT_FAILED;
return _response;
}
String url = "/query?";
#if defined _DEBUG
url += "pretty=true&";
#endif
url += _db;
url += "&q=" + URLEncode(sql);
DEBUG_PRINT("Requesting URL: ");
DEBUG_PRINT(url);
// This will send the request to the server
print(String("GET ") + url + " HTTP/1.1\r\n" + "Host: " + _host +
":" + _port + "\r\n" + "Connection: close\r\n\r\n");
// Read all the lines of the reply from server and print them to Serial
uint8_t t = 0;
while (!available() && t < 200) {
delay(10);
t++;
}
if (t==200) {_response = DB_ERROR; return DB_ERROR; } // Return error if time out.
DEBUG_PRINT("Receiving....");
uint8_t i=0;
String line = readStringUntil('\n');
DEBUG_PRINT("[HEAD] " + line);
if (line.substring(9,12) == "200") {
while (available()) {
line = readStringUntil('\n');
DEBUG_PRINT("(HEAD) " + line);
if (i < 6 ) i++; else return _response;
}
_response = DB_SUCCESS;
}
else{
_response = DB_ERROR;
#if defined _DEBUG
while (available()) {
line = readStringUntil('\n');
DEBUG_PRINT("[HEAD] " + line);
}
#endif
}
return _response;
}
DB_RESPONSE Influxdb::response() {
return _response;
}
/* -----------------------------------------------*/
// Field object
/* -----------------------------------------------*/
FIELD::FIELD(String m) {
measurement = m;
}
void FIELD::empty() {
_data = "";
_tag = "";
}
void FIELD::addTag(String key, String value) {
_tag += "," + key + "=" + value;
}
void FIELD::addField(String key, float value) {
_data = (_data == "") ? (" ") : (_data += ",");
_data += key + "=" + String(value);
}
String FIELD::postString() {
// uint32_t utc = 1448114561 + millis() /1000;
return measurement + _tag + _data;
}
// URL Encode with Arduino String object
String URLEncode(String msg) {
const char *hex = "0123456789abcdef";
String encodedMsg = "";
uint16_t i;
for (i = 0; i < msg.length(); i++) {
if (('a' <= msg.charAt(i) && msg.charAt(i) <= 'z') ||
('A' <= msg.charAt(i) && msg.charAt(i) <= 'Z') ||
('0' <= msg.charAt(i) && msg.charAt(i) <= '9')) {
encodedMsg += msg.charAt(i);
} else {
encodedMsg += '%';
encodedMsg += hex[msg.charAt(i) >> 4];
encodedMsg += hex[msg.charAt(i) & 15];
}
}
return encodedMsg;
}

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/* Influxdb library
MIT license
Written by HW Wong
*/
#ifndef INFLUXDB_H
#define INFLUXDB_H
#include "Arduino.h"
#include <ESP8266WiFi.h>
enum DB_RESPONSE {DB_SUCCESS, DB_ERROR, DB_CONNECT_FAILED};
// Url encode function
String URLEncode(String msg);
class FIELD
{
public:
FIELD(String m);
String measurement;
void addField(String key, float value);
void addTag(String key, String value);
void empty();
String postString();
private:
String _data;
String _tag;
};
class Influxdb : private WiFiClient
{
public:
Influxdb(const char* host, uint16_t port);
DB_RESPONSE opendb(String db);
DB_RESPONSE opendb(String db, String user, String password);
DB_RESPONSE write(FIELD data);
DB_RESPONSE write(String data);
DB_RESPONSE query(String sql);
//uint8_t createDatabase(char *dbname);
DB_RESPONSE response();
using WiFiClient::available;
using WiFiClient::read;
using WiFiClient::flush;
using WiFiClient::find;
using WiFiClient::findUntil;
using WiFiClient::peek;
using WiFiClient::readBytes;
using WiFiClient::readBytesUntil;
using WiFiClient::readString;
using WiFiClient::readStringUntil;
using WiFiClient::parseInt;
using WiFiClient::setTimeout;
private:
uint16_t _port;
const char* _host;
String _db;
DB_RESPONSE _response;
};
#endif

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# ESP8266Influxdb

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#include <Arduino.h>
#include <ESP8266WiFi.h>
#include <ESP8266WiFiMulti.h>
#include <ESP8266Influxdb.h>
const char *INFLUXDB_HOST = "host_or_ip";
const uint16_t INFLUXDB_PORT = 8086;
const char *DATABASE = "dbname";
const char *DB_USER = "dbuser";
const char *DB_PASSWORD = "dbpassword";
ESP8266WiFiMulti WiFiMulti;
Influxdb influxdb(INFLUXDB_HOST, INFLUXDB_PORT);
void setup() {
Serial.begin(115200);
WiFiMulti.addAP("SSID", "PASSWORD");
while (WiFiMulti.run() != WL_CONNECTED) {
delay(100);
}
Serial.println("Ready");
influxdb.opendb(DATABASE, DB_USER, DB_PASSWORD);
}
void loop() {
// Writing data with influxdb HTTP API
// https://influxdb.com/docs/v0.9/guides/writing_data.html
Serial.println("Writing data to host " + String(INFLUXDB_HOST) + ":" +
INFLUXDB_PORT + "'s database=" + DATABASE);
String data = "analog_read,method=HTTP_API,pin=A0 value=" + String(analogRead(A0));
influxdb.write(data);
Serial.println(influxdb.response() == DB_SUCCESS ? "HTTP write success"
: "Writing failed");
// Writing data using FIELD object
// Create field object with measurment name=analog_read
FIELD dataObj("analog_read");
dataObj.addTag("method", "Field_object"); // Add method tag
dataObj.addTag("pin", "A0"); // Add pin tag
dataObj.addField("value", analogRead(A0)); // Add value field
Serial.println(influxdb.write(dataObj) == DB_SUCCESS ? "Object write success"
: "Writing failed");
// Empty field object.
dataObj.empty();
// Querying Data
// https://influxdb.com/docs/v0.9/query_language/query_syntax.html
Serial.println("Querying data ........");
String sql = "select * from analog_read order by time desc limit 2";
if (influxdb.query(sql) == DB_SUCCESS) {
while (influxdb.available()) {
String line = influxdb.readStringUntil('\n');
Serial.println(line);
}
}
else
Serial.println("Query Failed");
delay(30000);
}

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##################################################
# Syntax Coloring Map For ESP8266 Influxdb library
##################################################
##################################################
# Datatypes (KEYWORD1)
##################################################
Influxdb KEYWORD1
FIELD KEYWORD1
DB_RESPOND KEYWORD1
##################################################
# Methods and Functions (KEYWORD2)
##################################################
addField KEYWORD2
addTag KEYWORD2
empty KEYWORD2
opendb KEYWORD2
write KEYWORD2
query KEYWORD2
postString KEYWORD2
response KEYWORD2

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= WiFi Library for Arduino =
With the Arduino WiFi Shield, this library allows an Arduino board to connect to the internet.
For more information about this library please visit us at
http://www.arduino.cc/en/Reference/WiFi
== License ==
Copyright (c) 2011-2014 Arduino LLC. All right reserved.
Copyright (C) 2006-2008, Atmel Corporation All rights reserved.
Copyright (c) 2001-2004 Swedish Institute of Computer Science.
Copyright (c) 2009-2010, H&D Wireless AB All rights reserved.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA

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/*
This example connects to an unencrypted Wifi network.
Then it prints the MAC address of the Wifi shield,
the IP address obtained, and other network details.
Circuit:
* WiFi shield attached
created 13 July 2010
by dlf (Metodo2 srl)
modified 31 May 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // the name of your network
int status = WL_IDLE_STATUS; // the Wifi radio's status
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to open SSID: ");
Serial.println(ssid);
status = WiFi.begin(ssid);
// wait 10 seconds for connection:
delay(10000);
}
// you're connected now, so print out the data:
Serial.print("You're connected to the network");
printCurrentNet();
printWifiData();
}
void loop() {
// check the network connection once every 10 seconds:
delay(10000);
printCurrentNet();
}
void printWifiData() {
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
Serial.println(ip);
// print your MAC address:
byte mac[6];
WiFi.macAddress(mac);
Serial.print("MAC address: ");
Serial.print(mac[5], HEX);
Serial.print(":");
Serial.print(mac[4], HEX);
Serial.print(":");
Serial.print(mac[3], HEX);
Serial.print(":");
Serial.print(mac[2], HEX);
Serial.print(":");
Serial.print(mac[1], HEX);
Serial.print(":");
Serial.println(mac[0], HEX);
// print your subnet mask:
IPAddress subnet = WiFi.subnetMask();
Serial.print("NetMask: ");
Serial.println(subnet);
// print your gateway address:
IPAddress gateway = WiFi.gatewayIP();
Serial.print("Gateway: ");
Serial.println(gateway);
}
void printCurrentNet() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print the MAC address of the router you're attached to:
byte bssid[6];
WiFi.BSSID(bssid);
Serial.print("BSSID: ");
Serial.print(bssid[5], HEX);
Serial.print(":");
Serial.print(bssid[4], HEX);
Serial.print(":");
Serial.print(bssid[3], HEX);
Serial.print(":");
Serial.print(bssid[2], HEX);
Serial.print(":");
Serial.print(bssid[1], HEX);
Serial.print(":");
Serial.println(bssid[0], HEX);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.println(rssi);
// print the encryption type:
byte encryption = WiFi.encryptionType();
Serial.print("Encryption Type:");
Serial.println(encryption, HEX);
}

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/*
This example connects to a WEP-encrypted Wifi network.
Then it prints the MAC address of the Wifi shield,
the IP address obtained, and other network details.
If you use 40-bit WEP, you need a key that is 10 characters long,
and the characters must be hexadecimal (0-9 or A-F).
e.g. for 40-bit, ABBADEAF01 will work, but ABBADEAF won't work
(too short) and ABBAISDEAF won't work (I and S are not
hexadecimal characters).
For 128-bit, you need a string that is 26 characters long.
D0D0DEADF00DABBADEAFBEADED will work because it's 26 characters,
all in the 0-9, A-F range.
Circuit:
* WiFi shield attached
created 13 July 2010
by dlf (Metodo2 srl)
modified 31 May 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char key[] = "D0D0DEADF00DABBADEAFBEADED"; // your network key
int keyIndex = 0; // your network key Index number
int status = WL_IDLE_STATUS; // the Wifi radio's status
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to WEP network, SSID: ");
Serial.println(ssid);
status = WiFi.begin(ssid, keyIndex, key);
// wait 10 seconds for connection:
delay(10000);
}
// once you are connected :
Serial.print("You're connected to the network");
printCurrentNet();
printWifiData();
}
void loop() {
// check the network connection once every 10 seconds:
delay(10000);
printCurrentNet();
}
void printWifiData() {
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
Serial.println(ip);
// print your MAC address:
byte mac[6];
WiFi.macAddress(mac);
Serial.print("MAC address: ");
Serial.print(mac[5], HEX);
Serial.print(":");
Serial.print(mac[4], HEX);
Serial.print(":");
Serial.print(mac[3], HEX);
Serial.print(":");
Serial.print(mac[2], HEX);
Serial.print(":");
Serial.print(mac[1], HEX);
Serial.print(":");
Serial.println(mac[0], HEX);
}
void printCurrentNet() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print the MAC address of the router you're attached to:
byte bssid[6];
WiFi.BSSID(bssid);
Serial.print("BSSID: ");
Serial.print(bssid[5], HEX);
Serial.print(":");
Serial.print(bssid[4], HEX);
Serial.print(":");
Serial.print(bssid[3], HEX);
Serial.print(":");
Serial.print(bssid[2], HEX);
Serial.print(":");
Serial.print(bssid[1], HEX);
Serial.print(":");
Serial.println(bssid[0], HEX);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.println(rssi);
// print the encryption type:
byte encryption = WiFi.encryptionType();
Serial.print("Encryption Type:");
Serial.println(encryption, HEX);
Serial.println();
}

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/*
This example connects to an unencrypted Wifi network.
Then it prints the MAC address of the Wifi shield,
the IP address obtained, and other network details.
Circuit:
* WiFi shield attached
created 13 July 2010
by dlf (Metodo2 srl)
modified 31 May 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password
int status = WL_IDLE_STATUS; // the Wifi radio's status
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to WPA SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
// you're connected now, so print out the data:
Serial.print("You're connected to the network");
printCurrentNet();
printWifiData();
}
void loop() {
// check the network connection once every 10 seconds:
delay(10000);
printCurrentNet();
}
void printWifiData() {
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
Serial.println(ip);
// print your MAC address:
byte mac[6];
WiFi.macAddress(mac);
Serial.print("MAC address: ");
Serial.print(mac[5], HEX);
Serial.print(":");
Serial.print(mac[4], HEX);
Serial.print(":");
Serial.print(mac[3], HEX);
Serial.print(":");
Serial.print(mac[2], HEX);
Serial.print(":");
Serial.print(mac[1], HEX);
Serial.print(":");
Serial.println(mac[0], HEX);
}
void printCurrentNet() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print the MAC address of the router you're attached to:
byte bssid[6];
WiFi.BSSID(bssid);
Serial.print("BSSID: ");
Serial.print(bssid[5], HEX);
Serial.print(":");
Serial.print(bssid[4], HEX);
Serial.print(":");
Serial.print(bssid[3], HEX);
Serial.print(":");
Serial.print(bssid[2], HEX);
Serial.print(":");
Serial.print(bssid[1], HEX);
Serial.print(":");
Serial.println(bssid[0], HEX);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.println(rssi);
// print the encryption type:
byte encryption = WiFi.encryptionType();
Serial.print("Encryption Type:");
Serial.println(encryption, HEX);
Serial.println();
}

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/*
This example prints the Wifi shield's MAC address, and
scans for available Wifi networks using the Wifi shield.
Every ten seconds, it scans again. It doesn't actually
connect to any network, so no encryption scheme is specified.
Circuit:
* WiFi shield attached
created 13 July 2010
by dlf (Metodo2 srl)
modified 21 Junn 2012
by Tom Igoe and Jaymes Dec
*/
#include <SPI.h>
#include <WiFi.h>
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// Print WiFi MAC address:
printMacAddress();
}
void loop() {
// scan for existing networks:
Serial.println("Scanning available networks...");
listNetworks();
delay(10000);
}
void printMacAddress() {
// the MAC address of your Wifi shield
byte mac[6];
// print your MAC address:
WiFi.macAddress(mac);
Serial.print("MAC: ");
Serial.print(mac[5], HEX);
Serial.print(":");
Serial.print(mac[4], HEX);
Serial.print(":");
Serial.print(mac[3], HEX);
Serial.print(":");
Serial.print(mac[2], HEX);
Serial.print(":");
Serial.print(mac[1], HEX);
Serial.print(":");
Serial.println(mac[0], HEX);
}
void listNetworks() {
// scan for nearby networks:
Serial.println("** Scan Networks **");
int numSsid = WiFi.scanNetworks();
if (numSsid == -1) {
Serial.println("Couldn't get a wifi connection");
while (true);
}
// print the list of networks seen:
Serial.print("number of available networks:");
Serial.println(numSsid);
// print the network number and name for each network found:
for (int thisNet = 0; thisNet < numSsid; thisNet++) {
Serial.print(thisNet);
Serial.print(") ");
Serial.print(WiFi.SSID(thisNet));
Serial.print("\tSignal: ");
Serial.print(WiFi.RSSI(thisNet));
Serial.print(" dBm");
Serial.print("\tEncryption: ");
printEncryptionType(WiFi.encryptionType(thisNet));
}
}
void printEncryptionType(int thisType) {
// read the encryption type and print out the name:
switch (thisType) {
case ENC_TYPE_WEP:
Serial.println("WEP");
break;
case ENC_TYPE_TKIP:
Serial.println("WPA");
break;
case ENC_TYPE_CCMP:
Serial.println("WPA2");
break;
case ENC_TYPE_NONE:
Serial.println("None");
break;
case ENC_TYPE_AUTO:
Serial.println("Auto");
break;
}
}

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/*
WiFi Web Server LED Blink
A simple web server that lets you blink an LED via the web.
This sketch will print the IP address of your WiFi Shield (once connected)
to the Serial monitor. From there, you can open that address in a web browser
to turn on and off the LED on pin 9.
If the IP address of your shield is yourAddress:
http://yourAddress/H turns the LED on
http://yourAddress/L turns it off
This example is written for a network using WPA encryption. For
WEP or WPA, change the Wifi.begin() call accordingly.
Circuit:
* WiFi shield attached
* LED attached to pin 9
created 25 Nov 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password
int keyIndex = 0; // your network key Index number (needed only for WEP)
int status = WL_IDLE_STATUS;
WiFiServer server(80);
void setup() {
Serial.begin(9600); // initialize serial communication
pinMode(9, OUTPUT); // set the LED pin mode
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
while (true); // don't continue
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to Network named: ");
Serial.println(ssid); // print the network name (SSID);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
server.begin(); // start the web server on port 80
printWifiStatus(); // you're connected now, so print out the status
}
void loop() {
WiFiClient client = server.available(); // listen for incoming clients
if (client) { // if you get a client,
Serial.println("new client"); // print a message out the serial port
String currentLine = ""; // make a String to hold incoming data from the client
while (client.connected()) { // loop while the client's connected
if (client.available()) { // if there's bytes to read from the client,
char c = client.read(); // read a byte, then
Serial.write(c); // print it out the serial monitor
if (c == '\n') { // if the byte is a newline character
// if the current line is blank, you got two newline characters in a row.
// that's the end of the client HTTP request, so send a response:
if (currentLine.length() == 0) {
// HTTP headers always start with a response code (e.g. HTTP/1.1 200 OK)
// and a content-type so the client knows what's coming, then a blank line:
client.println("HTTP/1.1 200 OK");
client.println("Content-type:text/html");
client.println();
// the content of the HTTP response follows the header:
client.print("Click <a href=\"/H\">here</a> turn the LED on pin 9 on<br>");
client.print("Click <a href=\"/L\">here</a> turn the LED on pin 9 off<br>");
// The HTTP response ends with another blank line:
client.println();
// break out of the while loop:
break;
} else { // if you got a newline, then clear currentLine:
currentLine = "";
}
} else if (c != '\r') { // if you got anything else but a carriage return character,
currentLine += c; // add it to the end of the currentLine
}
// Check to see if the client request was "GET /H" or "GET /L":
if (currentLine.endsWith("GET /H")) {
digitalWrite(9, HIGH); // GET /H turns the LED on
}
if (currentLine.endsWith("GET /L")) {
digitalWrite(9, LOW); // GET /L turns the LED off
}
}
}
// close the connection:
client.stop();
Serial.println("client disonnected");
}
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
// print where to go in a browser:
Serial.print("To see this page in action, open a browser to http://");
Serial.println(ip);
}

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/*
Chat Server
A simple server that distributes any incoming messages to all
connected clients. To use telnet to your device's IP address and type.
You can see the client's input in the serial monitor as well.
This example is written for a network using WPA encryption. For
WEP or WPA, change the Wifi.begin() call accordingly.
Circuit:
* WiFi shield attached
created 18 Dec 2009
by David A. Mellis
modified 31 May 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password (use for WPA, or use as key for WEP)
int keyIndex = 0; // your network key Index number (needed only for WEP)
int status = WL_IDLE_STATUS;
WiFiServer server(23);
boolean alreadyConnected = false; // whether or not the client was connected previously
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
// start the server:
server.begin();
// you're connected now, so print out the status:
printWifiStatus();
}
void loop() {
// wait for a new client:
WiFiClient client = server.available();
// when the client sends the first byte, say hello:
if (client) {
if (!alreadyConnected) {
// clead out the input buffer:
client.flush();
Serial.println("We have a new client");
client.println("Hello, client!");
alreadyConnected = true;
}
if (client.available() > 0) {
// read the bytes incoming from the client:
char thisChar = client.read();
// echo the bytes back to the client:
server.write(thisChar);
// echo the bytes to the server as well:
Serial.write(thisChar);
}
}
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
}

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/*
Udp NTP Client
Get the time from a Network Time Protocol (NTP) time server
Demonstrates use of UDP sendPacket and ReceivePacket
For more on NTP time servers and the messages needed to communicate with them,
see http://en.wikipedia.org/wiki/Network_Time_Protocol
created 4 Sep 2010
by Michael Margolis
modified 9 Apr 2012
by Tom Igoe
This code is in the public domain.
*/
#include <SPI.h>
#include <WiFi.h>
#include <WiFiUdp.h>
int status = WL_IDLE_STATUS;
char ssid[] = "mynetwork"; // your network SSID (name)
char pass[] = "mypassword"; // your network password
int keyIndex = 0; // your network key Index number (needed only for WEP)
unsigned int localPort = 2390; // local port to listen for UDP packets
IPAddress timeServer(129, 6, 15, 28); // time.nist.gov NTP server
const int NTP_PACKET_SIZE = 48; // NTP time stamp is in the first 48 bytes of the message
byte packetBuffer[ NTP_PACKET_SIZE]; //buffer to hold incoming and outgoing packets
// A UDP instance to let us send and receive packets over UDP
WiFiUDP Udp;
void setup() {
// Open serial communications and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
Serial.println("Connected to wifi");
printWifiStatus();
Serial.println("\nStarting connection to server...");
Udp.begin(localPort);
}
void loop() {
sendNTPpacket(timeServer); // send an NTP packet to a time server
// wait to see if a reply is available
delay(1000);
if (Udp.parsePacket()) {
Serial.println("packet received");
// We've received a packet, read the data from it
Udp.read(packetBuffer, NTP_PACKET_SIZE); // read the packet into the buffer
//the timestamp starts at byte 40 of the received packet and is four bytes,
// or two words, long. First, esxtract the two words:
unsigned long highWord = word(packetBuffer[40], packetBuffer[41]);
unsigned long lowWord = word(packetBuffer[42], packetBuffer[43]);
// combine the four bytes (two words) into a long integer
// this is NTP time (seconds since Jan 1 1900):
unsigned long secsSince1900 = highWord << 16 | lowWord;
Serial.print("Seconds since Jan 1 1900 = ");
Serial.println(secsSince1900);
// now convert NTP time into everyday time:
Serial.print("Unix time = ");
// Unix time starts on Jan 1 1970. In seconds, that's 2208988800:
const unsigned long seventyYears = 2208988800UL;
// subtract seventy years:
unsigned long epoch = secsSince1900 - seventyYears;
// print Unix time:
Serial.println(epoch);
// print the hour, minute and second:
Serial.print("The UTC time is "); // UTC is the time at Greenwich Meridian (GMT)
Serial.print((epoch % 86400L) / 3600); // print the hour (86400 equals secs per day)
Serial.print(':');
if (((epoch % 3600) / 60) < 10) {
// In the first 10 minutes of each hour, we'll want a leading '0'
Serial.print('0');
}
Serial.print((epoch % 3600) / 60); // print the minute (3600 equals secs per minute)
Serial.print(':');
if ((epoch % 60) < 10) {
// In the first 10 seconds of each minute, we'll want a leading '0'
Serial.print('0');
}
Serial.println(epoch % 60); // print the second
}
// wait ten seconds before asking for the time again
delay(10000);
}
// send an NTP request to the time server at the given address
unsigned long sendNTPpacket(IPAddress& address) {
//Serial.println("1");
// set all bytes in the buffer to 0
memset(packetBuffer, 0, NTP_PACKET_SIZE);
// Initialize values needed to form NTP request
// (see URL above for details on the packets)
//Serial.println("2");
packetBuffer[0] = 0b11100011; // LI, Version, Mode
packetBuffer[1] = 0; // Stratum, or type of clock
packetBuffer[2] = 6; // Polling Interval
packetBuffer[3] = 0xEC; // Peer Clock Precision
// 8 bytes of zero for Root Delay & Root Dispersion
packetBuffer[12] = 49;
packetBuffer[13] = 0x4E;
packetBuffer[14] = 49;
packetBuffer[15] = 52;
//Serial.println("3");
// all NTP fields have been given values, now
// you can send a packet requesting a timestamp:
Udp.beginPacket(address, 123); //NTP requests are to port 123
//Serial.println("4");
Udp.write(packetBuffer, NTP_PACKET_SIZE);
//Serial.println("5");
Udp.endPacket();
//Serial.println("6");
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
}

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/*
WiFi UDP Send and Receive String
This sketch wait an UDP packet on localPort using a WiFi shield.
When a packet is received an Acknowledge packet is sent to the client on port remotePort
Circuit:
* WiFi shield attached
created 30 December 2012
by dlf (Metodo2 srl)
*/
#include <SPI.h>
#include <WiFi.h>
#include <WiFiUdp.h>
int status = WL_IDLE_STATUS;
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password (use for WPA, or use as key for WEP)
int keyIndex = 0; // your network key Index number (needed only for WEP)
unsigned int localPort = 2390; // local port to listen on
char packetBuffer[255]; //buffer to hold incoming packet
char ReplyBuffer[] = "acknowledged"; // a string to send back
WiFiUDP Udp;
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid);
// wait 10 seconds for connection:
delay(10000);
}
Serial.println("Connected to wifi");
printWifiStatus();
Serial.println("\nStarting connection to server...");
// if you get a connection, report back via serial:
Udp.begin(localPort);
}
void loop() {
// if there's data available, read a packet
int packetSize = Udp.parsePacket();
if (packetSize) {
Serial.print("Received packet of size ");
Serial.println(packetSize);
Serial.print("From ");
IPAddress remoteIp = Udp.remoteIP();
Serial.print(remoteIp);
Serial.print(", port ");
Serial.println(Udp.remotePort());
// read the packet into packetBufffer
int len = Udp.read(packetBuffer, 255);
if (len > 0) {
packetBuffer[len] = 0;
}
Serial.println("Contents:");
Serial.println(packetBuffer);
// send a reply, to the IP address and port that sent us the packet we received
Udp.beginPacket(Udp.remoteIP(), Udp.remotePort());
Udp.write(ReplyBuffer);
Udp.endPacket();
}
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
}

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/*
Web client
This sketch connects to a website (http://www.google.com)
using a WiFi shield.
This example is written for a network using WPA encryption. For
WEP or WPA, change the Wifi.begin() call accordingly.
This example is written for a network using WPA encryption. For
WEP or WPA, change the Wifi.begin() call accordingly.
Circuit:
* WiFi shield attached
created 13 July 2010
by dlf (Metodo2 srl)
modified 31 May 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password (use for WPA, or use as key for WEP)
int keyIndex = 0; // your network key Index number (needed only for WEP)
int status = WL_IDLE_STATUS;
// if you don't want to use DNS (and reduce your sketch size)
// use the numeric IP instead of the name for the server:
//IPAddress server(74,125,232,128); // numeric IP for Google (no DNS)
char server[] = "www.google.com"; // name address for Google (using DNS)
// Initialize the Ethernet client library
// with the IP address and port of the server
// that you want to connect to (port 80 is default for HTTP):
WiFiClient client;
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
Serial.println("Connected to wifi");
printWifiStatus();
Serial.println("\nStarting connection to server...");
// if you get a connection, report back via serial:
if (client.connect(server, 80)) {
Serial.println("connected to server");
// Make a HTTP request:
client.println("GET /search?q=arduino HTTP/1.1");
client.println("Host: www.google.com");
client.println("Connection: close");
client.println();
}
}
void loop() {
// if there are incoming bytes available
// from the server, read them and print them:
while (client.available()) {
char c = client.read();
Serial.write(c);
}
// if the server's disconnected, stop the client:
if (!client.connected()) {
Serial.println();
Serial.println("disconnecting from server.");
client.stop();
// do nothing forevermore:
while (true);
}
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
}

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/*
Repeating Wifi Web Client
This sketch connects to a a web server and makes a request
using an Arduino Wifi shield.
Circuit:
* WiFi shield attached to pins SPI pins and pin 7
created 23 April 2012
modified 31 May 2012
by Tom Igoe
modified 13 Jan 2014
by Federico Vanzati
http://www.arduino.cc/en/Tutorial/WifiWebClientRepeating
This code is in the public domain.
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password
int keyIndex = 0; // your network key Index number (needed only for WEP)
int status = WL_IDLE_STATUS;
// Initialize the Wifi client library
WiFiClient client;
// server address:
char server[] = "www.arduino.cc";
//IPAddress server(64,131,82,241);
unsigned long lastConnectionTime = 0; // last time you connected to the server, in milliseconds
const unsigned long postingInterval = 10L * 1000L; // delay between updates, in milliseconds
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
// you're connected now, so print out the status:
printWifiStatus();
}
void loop() {
// if there's incoming data from the net connection.
// send it out the serial port. This is for debugging
// purposes only:
while (client.available()) {
char c = client.read();
Serial.write(c);
}
// if ten seconds have passed since your last connection,
// then connect again and send data:
if (millis() - lastConnectionTime > postingInterval) {
httpRequest();
}
}
// this method makes a HTTP connection to the server:
void httpRequest() {
// close any connection before send a new request.
// This will free the socket on the WiFi shield
client.stop();
// if there's a successful connection:
if (client.connect(server, 80)) {
Serial.println("connecting...");
// send the HTTP PUT request:
client.println("GET /latest.txt HTTP/1.1");
client.println("Host: www.arduino.cc");
client.println("User-Agent: ArduinoWiFi/1.1");
client.println("Connection: close");
client.println();
// note the time that the connection was made:
lastConnectionTime = millis();
} else {
// if you couldn't make a connection:
Serial.println("connection failed");
}
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
}

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/*
WiFi Web Server
A simple web server that shows the value of the analog input pins.
using a WiFi shield.
This example is written for a network using WPA encryption. For
WEP or WPA, change the Wifi.begin() call accordingly.
Circuit:
* WiFi shield attached
* Analog inputs attached to pins A0 through A5 (optional)
created 13 July 2010
by dlf (Metodo2 srl)
modified 31 May 2012
by Tom Igoe
*/
#include <SPI.h>
#include <WiFi.h>
char ssid[] = "yourNetwork"; // your network SSID (name)
char pass[] = "secretPassword"; // your network password
int keyIndex = 0; // your network key Index number (needed only for WEP)
int status = WL_IDLE_STATUS;
WiFiServer server(80);
void setup() {
//Initialize serial and wait for port to open:
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for native USB port only
}
// check for the presence of the shield:
if (WiFi.status() == WL_NO_SHIELD) {
Serial.println("WiFi shield not present");
// don't continue:
while (true);
}
String fv = WiFi.firmwareVersion();
if (fv != "1.1.0") {
Serial.println("Please upgrade the firmware");
}
// attempt to connect to Wifi network:
while (status != WL_CONNECTED) {
Serial.print("Attempting to connect to SSID: ");
Serial.println(ssid);
// Connect to WPA/WPA2 network. Change this line if using open or WEP network:
status = WiFi.begin(ssid, pass);
// wait 10 seconds for connection:
delay(10000);
}
server.begin();
// you're connected now, so print out the status:
printWifiStatus();
}
void loop() {
// listen for incoming clients
WiFiClient client = server.available();
if (client) {
Serial.println("new client");
// an http request ends with a blank line
boolean currentLineIsBlank = true;
while (client.connected()) {
if (client.available()) {
char c = client.read();
Serial.write(c);
// if you've gotten to the end of the line (received a newline
// character) and the line is blank, the http request has ended,
// so you can send a reply
if (c == '\n' && currentLineIsBlank) {
// send a standard http response header
client.println("HTTP/1.1 200 OK");
client.println("Content-Type: text/html");
client.println("Connection: close"); // the connection will be closed after completion of the response
client.println("Refresh: 5"); // refresh the page automatically every 5 sec
client.println();
client.println("<!DOCTYPE HTML>");
client.println("<html>");
// output the value of each analog input pin
for (int analogChannel = 0; analogChannel < 6; analogChannel++) {
int sensorReading = analogRead(analogChannel);
client.print("analog input ");
client.print(analogChannel);
client.print(" is ");
client.print(sensorReading);
client.println("<br />");
}
client.println("</html>");
break;
}
if (c == '\n') {
// you're starting a new line
currentLineIsBlank = true;
} else if (c != '\r') {
// you've gotten a character on the current line
currentLineIsBlank = false;
}
}
}
// give the web browser time to receive the data
delay(1);
// close the connection:
client.stop();
Serial.println("client disonnected");
}
}
void printWifiStatus() {
// print the SSID of the network you're attached to:
Serial.print("SSID: ");
Serial.println(WiFi.SSID());
// print your WiFi shield's IP address:
IPAddress ip = WiFi.localIP();
Serial.print("IP Address: ");
Serial.println(ip);
// print the received signal strength:
long rssi = WiFi.RSSI();
Serial.print("signal strength (RSSI):");
Serial.print(rssi);
Serial.println(" dBm");
}

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#!/bin/sh
#WIFI_FW_PATH="/hardware/arduino/firmwares/wifishield/binary"
WIFI_FW_PATH="/libraries/WiFi/extras/binary"
AVR_TOOLS_PATH="/hardware/tools/avr/bin"
TARGET_MICRO="at32uc3a1256"
progname=$0
usage () {
cat <<EOF
Usage: $progname [-a Arduino_path] [-f which_firmware] [-h]
-a set the path where the Arduino IDE is installed
-f the firmware you want to upload, valid parameters are:
shield - to upgrade the WiFi shield firmware
all - to upgrade both firmwares
-h help
EOF
exit 0
}
upgradeHDmodule () {
sleep 1 # Give time to the shield to end the boot
echo "****Upgrade HD WiFi module firmware****\n"
dfu-programmer $TARGET_MICRO erase
dfu-programmer $TARGET_MICRO flash --suppress-bootloader-mem $WIFI_FW_PATH/wifi_dnld.hex
dfu-programmer $TARGET_MICRO start
if [ $? != 0 ] ; then
echo "\nError during device initialization, please close the J3 jumper and press the reset button.\nTry -h for help\n"
exit 1 # if the device is not recognized exit
fi
echo -n "\nPress the RESET button on the shield then type [ENTER] to upgrade the firmware of the shield..\n"
read readEnter
}
upgradeShield () {
sleep 1 # Give time to the shield to end the boot
echo "****Upgrade WiFi Shield firmware****\n"
dfu-programmer $TARGET_MICRO erase
dfu-programmer $TARGET_MICRO flash --suppress-bootloader-mem $WIFI_FW_PATH/wifiHD.hex
dfu-programmer $TARGET_MICRO start
if [ $? != 0 ] ; then
echo "\nError during device initialization, please close the J3 jumper and press the reset button.\nTry -h for help\n"
exit 1 # if the device is not recognized exit
fi
echo "\nDone. Remove the J3 jumper and press the RESET button on the shield."
echo "Thank you!\n"
}
cat <<EOF
Arduino WiFi Shield upgrade
=========================================
Instructions:
To access to the USB devices correctly, the dfu-programmer needs to have the root permissions.
You can upgrade the firmware of the antenna togheter with the shield firmware or only the shield firmware
if there aren't changes on the antenna firmware.
Use the '-h' parameter for help
=========================================
EOF
if [ $USER = 'root' ] ; then #check if the current user is root
while getopts ":a:f:h" opt; do
case $opt in
a)
ARDUINO_PATH=$OPTARG
WIFI_FW_PATH=$ARDUINO_PATH$WIFI_FW_PATH
AVR_TOOLS_PATH=$ARDUINO_PATH$AVR_TOOLS_PATH
cd $AVR_TOOLS_PATH
./avr-objcopy --output-target=ihex $WIFI_FW_PATH/wifi_dnld.elf $WIFI_FW_PATH/wifi_dnld.hex
./avr-objcopy --output-target=ihex $WIFI_FW_PATH/wifiHD.elf $WIFI_FW_PATH/wifiHD.hex
;;
f)
if [ "$ARDUINO_PATH" != "" ] ; then
if [ "$OPTARG" = "all" ] ; then
upgradeHDmodule
upgradeShield
exit 0
else
if [ "$OPTARG" = "shield" ] ; then
upgradeShield
exit 0
else
echo "invalid parameter for the -f [firmware] option, please retry."
echo "Type -h for help\n"
exit 1
fi
fi
else
echo "Arduino Path not setted. Retry...\n"
fi
;;
h)
usage ;;
\?)
echo "Invalid option: $OPTARG" >&2
usage
exit 1
;;
:)
echo "Option -$OPTARG requires an argument." >&2
exit 1
;;
esac
done
else
echo "Please retry running the script as root.\n"
fi
shift $(($OPTIND - 1))

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<?xml version="1.0" encoding="UTF-8"?>
<projectDescription>
<name>wifiHD</name>
<comment></comment>
<projects>
</projects>
<buildSpec>
<buildCommand>
<name>org.eclipse.cdt.managedbuilder.core.genmakebuilder</name>
<triggers>clean,full,incremental,</triggers>
<arguments>
<dictionary>
<key>?name?</key>
<value></value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.append_environment</key>
<value>true</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.buildArguments</key>
<value></value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.buildCommand</key>
<value>make</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.buildLocation</key>
<value>${workspace_loc:/wifiHD/Debug}</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.contents</key>
<value>org.eclipse.cdt.make.core.activeConfigSettings</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.enableAutoBuild</key>
<value>false</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.enableCleanBuild</key>
<value>true</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.enableFullBuild</key>
<value>true</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.stopOnError</key>
<value>true</value>
</dictionary>
<dictionary>
<key>org.eclipse.cdt.make.core.useDefaultBuildCmd</key>
<value>true</value>
</dictionary>
</arguments>
</buildCommand>
<buildCommand>
<name>org.eclipse.cdt.managedbuilder.core.ScannerConfigBuilder</name>
<arguments>
</arguments>
</buildCommand>
</buildSpec>
<natures>
<nature>com.atmel.avr32.core.nature</nature>
<nature>org.eclipse.cdt.core.cnature</nature>
<nature>org.eclipse.cdt.managedbuilder.core.managedBuildNature</nature>
<nature>org.eclipse.cdt.managedbuilder.core.ScannerConfigNature</nature>
</natures>
<linkedResources>
<link>
<name>UC3 Software Framework</name>
<type>2</type>
<locationURI>framework:/com.atmel.avr32.sf.uc3</locationURI>
</link>
</linkedResources>
</projectDescription>

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Memory access control configuration file.
*
* This file contains the possible external configuration of the memory access
* control.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _CONF_ACCESS_H_
#define _CONF_ACCESS_H_
#include "compiler.h"
#include "board.h"
/*! \name Activation of Logical Unit Numbers
*/
//! @{
#define LUN_0 DISABLE //!< On-Chip Virtual Memory.
#define LUN_1 ENABLE //!< AT45DBX Data Flash.
#define LUN_2 DISABLE //!< SD/MMC Card over SPI.
#define LUN_3 DISABLE
#define LUN_4 DISABLE
#define LUN_5 DISABLE
#define LUN_6 DISABLE
#define LUN_7 DISABLE
#define LUN_USB DISABLE //!< Host Mass-Storage Memory.
//! @}
/*! \name LUN 0 Definitions
*/
//! @{
#define VIRTUAL_MEM LUN_0
#define LUN_ID_VIRTUAL_MEM LUN_ID_0
#define LUN_0_INCLUDE "virtual_mem.h"
#define Lun_0_test_unit_ready virtual_test_unit_ready
#define Lun_0_read_capacity virtual_read_capacity
#define Lun_0_wr_protect virtual_wr_protect
#define Lun_0_removal virtual_removal
#define Lun_0_usb_read_10 virtual_usb_read_10
#define Lun_0_usb_write_10 virtual_usb_write_10
#define Lun_0_mem_2_ram virtual_mem_2_ram
#define Lun_0_ram_2_mem virtual_ram_2_mem
#define LUN_0_NAME "\"On-Chip Virtual Memory\""
//! @}
/*! \name LUN 1 Definitions
*/
//! @{
#define AT45DBX_MEM LUN_1
#define LUN_ID_AT45DBX_MEM LUN_ID_1
#define LUN_1_INCLUDE "at45dbx_mem.h"
#define Lun_1_test_unit_ready at45dbx_test_unit_ready
#define Lun_1_read_capacity at45dbx_read_capacity
#define Lun_1_wr_protect at45dbx_wr_protect
#define Lun_1_removal at45dbx_removal
#define Lun_1_usb_read_10 at45dbx_usb_read_10
#define Lun_1_usb_write_10 at45dbx_usb_write_10
#define Lun_1_mem_2_ram at45dbx_df_2_ram
#define Lun_1_ram_2_mem at45dbx_ram_2_df
#define LUN_1_NAME "\"AT45DBX Data Flash\""
//! @}
/*! \name LUN 2 Definitions
*/
//! @{
#define SD_MMC_SPI_MEM LUN_2
#define LUN_ID_SD_MMC_SPI_MEM LUN_ID_2
#define LUN_2_INCLUDE "sd_mmc_spi_mem.h"
#define Lun_2_test_unit_ready sd_mmc_spi_test_unit_ready
#define Lun_2_read_capacity sd_mmc_spi_read_capacity
#define Lun_2_wr_protect sd_mmc_spi_wr_protect
#define Lun_2_removal sd_mmc_spi_removal
#define Lun_2_usb_read_10 sd_mmc_spi_usb_read_10
#define Lun_2_usb_write_10 sd_mmc_spi_usb_write_10
#define Lun_2_mem_2_ram sd_mmc_spi_mem_2_ram
#define Lun_2_ram_2_mem sd_mmc_spi_ram_2_mem
#define LUN_2_NAME "\"SD/MMC Card over SPI\""
//! @}
/*! \name USB LUNs Definitions
*/
//! @{
#define MEM_USB LUN_USB
#define LUN_ID_MEM_USB LUN_ID_USB
#define LUN_USB_INCLUDE "host_mem.h"
#define Lun_usb_test_unit_ready(lun) host_test_unit_ready(lun)
#define Lun_usb_read_capacity(lun, nb_sect) host_read_capacity(lun, nb_sect)
#define Lun_usb_read_sector_size(lun) host_read_sector_size(lun)
#define Lun_usb_wr_protect(lun) host_wr_protect(lun)
#define Lun_usb_removal() host_removal()
#define Lun_usb_mem_2_ram(addr, ram) host_read_10_ram(addr, ram)
#define Lun_usb_ram_2_mem(addr, ram) host_write_10_ram(addr, ram)
#define LUN_USB_NAME "\"Host Mass-Storage Memory\""
//! @}
/*! \name Actions Associated with Memory Accesses
*
* Write here the action to associate with each memory access.
*
* \warning Be careful not to waste time in order not to disturb the functions.
*/
//! @{
#define memory_start_read_action(nb_sectors)
#define memory_stop_read_action()
#define memory_start_write_action(nb_sectors)
#define memory_stop_write_action()
//! @}
/*! \name Activation of Interface Features
*/
//! @{
#define ACCESS_USB DISABLED //!< MEM <-> USB interface.
#define ACCESS_MEM_TO_RAM ENABLED //!< MEM <-> RAM interface.
#define ACCESS_STREAM ENABLED //!< Streaming MEM <-> MEM interface. //mlf
#define ACCESS_STREAM_RECORD DISABLED //!< Streaming MEM <-> MEM interface in record mode.
#define ACCESS_MEM_TO_MEM DISABLED //!< MEM <-> MEM interface.
#define ACCESS_CODEC DISABLED //!< Codec interface.
//! @}
/*! \name Specific Options for Access Control
*/
//! @{
#define GLOBAL_WR_PROTECT DISABLED //!< Management of a global write protection.
//! @}
#endif // _CONF_ACCESS_H_

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT45DBX configuration file.
*
* This file contains the possible external configuration of the AT45DBX.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _CONF_AT45DBX_H_
#define _CONF_AT45DBX_H_
#include "conf_access.h"
#if AT45DBX_MEM == DISABLE
#error conf_at45dbx.h is #included although AT45DBX_MEM is disabled
#endif
#include "at45dbx.h"
//_____ D E F I N I T I O N S ______________________________________________
//! Size of AT45DBX data flash memories to manage.
#define AT45DBX_MEM_SIZE AT45DBX_1MB
//! Number of AT45DBX components to manage.
#define AT45DBX_MEM_CNT 1
//! First chip select used by AT45DBX components on the SPI module instance.
//! AT45DBX_SPI_NPCS0_PIN always corresponds to this first NPCS, whatever it is.
#define AT45DBX_SPI_FIRST_NPCS AT45DBX_SPI_NPCS
//! SPI master speed in Hz.
#define AT45DBX_SPI_MASTER_SPEED 12000000
//! Number of bits in each SPI transfer.
#define AT45DBX_SPI_BITS 8
#endif // _CONF_AT45DBX_H_

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief CONF_EBI EBI/SMC driver for AVR32 UC3.
*
* \note The values defined in this file are device-specific. See the device
* datasheet for further information.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SMC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _CONF_EBI_H_
#define _CONF_EBI_H_
#include "compiler.h"
#include "board.h"
#if (ET024006DHU_SMC_USE_NCS == 0)
#define SMC_USE_NCS0
#define SMC_COMPONENT_CS0 ET024006DHU_SMC_COMPONENT_CS
#else
#if (ET024006DHU_SMC_USE_NCS == 2)
#define SMC_USE_NCS2
#define SMC_COMPONENT_CS2 ET024006DHU_SMC_COMPONENT_CS
#else
#error This board is not supported
#endif
#endif
#define EBI_DATA_0 ET024006DHU_EBI_DATA_0
#define EBI_DATA_1 ET024006DHU_EBI_DATA_1
#define EBI_DATA_2 ET024006DHU_EBI_DATA_2
#define EBI_DATA_3 ET024006DHU_EBI_DATA_3
#define EBI_DATA_4 ET024006DHU_EBI_DATA_4
#define EBI_DATA_5 ET024006DHU_EBI_DATA_5
#define EBI_DATA_6 ET024006DHU_EBI_DATA_6
#define EBI_DATA_7 ET024006DHU_EBI_DATA_7
#define EBI_DATA_8 ET024006DHU_EBI_DATA_8
#define EBI_DATA_9 ET024006DHU_EBI_DATA_9
#define EBI_DATA_10 ET024006DHU_EBI_DATA_10
#define EBI_DATA_11 ET024006DHU_EBI_DATA_11
#define EBI_DATA_12 ET024006DHU_EBI_DATA_12
#define EBI_DATA_13 ET024006DHU_EBI_DATA_13
#define EBI_DATA_14 ET024006DHU_EBI_DATA_14
#define EBI_DATA_15 ET024006DHU_EBI_DATA_15
#if BOARD==EVK1105
#ifdef EVK1105_REV3
#define EBI_ADDR_19 AVR32_EBI_ADDR_19
#define EBI_NCS_2 ET024006DHU_EBI_NCS
#else
#define EBI_ADDR_21 ET024006DHU_EBI_ADDR_21
#define EBI_NCS_0 ET024006DHU_EBI_NCS
#endif
#elif BOARD == UC3C_EK
#define EBI_ADDR_22 AVR32_EBI_ADDR_22
#define EBI_NCS_0 ET024006DHU_EBI_NCS
#elif BOARD == EVK1104
#define EBI_ADDR_21 ET024006DHU_EBI_ADDR_21
#define EBI_NCS_0 ET024006DHU_EBI_NCS
#endif
#define EBI_NWE0 ET024006DHU_EBI_NWE
#define EBI_NRD ET024006DHU_EBI_NRD
#endif // _CONF_EBI_H_

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief SD/MMC configuration file.
*
* This file contains the possible external configuration of the SD/MMC.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _CONF_SD_MMC_SPI_H_
#define _CONF_SD_MMC_SPI_H_
#include "conf_access.h"
#if SD_MMC_SPI_MEM == DISABLE
#error conf_sd_mmc_spi.h is #included although SD_MMC_SPI_MEM is disabled
#endif
#include "sd_mmc_spi.h"
//_____ D E F I N I T I O N S ______________________________________________
//! SPI master speed in Hz.
#define SD_MMC_SPI_MASTER_SPEED 12000000
//! Number of bits in each SPI transfer.
#define SD_MMC_SPI_BITS 8
#endif // _CONF_SD_MMC_SPI_H_

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/* This file is part of the ATMEL AVR32-SoftwareFramework-AT32UC3A-1.4.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AVR32 UC3 ISP trampoline.
*
* In order to be able to program a project with both BatchISP and JTAGICE mkII
* without having to take the general-purpose fuses into consideration, add this
* file to the project and change the program entry point to _trampoline.
*
* The pre-programmed ISP will be erased if JTAGICE mkII is used.
*
* - Compiler: GNU GCC for AVR32
* - Supported devices: All AVR32UC devices can be used.
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (C) 2006-2008, Atmel Corporation All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of ATMEL may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE EXPRESSLY AND
* SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT,
* INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "conf_isp.h"
//! @{
//! \verbatim
// This must be linked @ 0x80000000 if it is to be run upon reset.
.section .reset, "ax", @progbits
.global _trampoline
.type _trampoline, @function
_trampoline:
// Jump to program start.
rjmp program_start
.org PROGRAM_START_OFFSET
program_start:
// Jump to the C runtime startup routine.
lda.w pc, _stext
//! \endverbatim
//! @}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT32UC3A EVK1100 board header file.
*
* This file contains definitions and services related to the features of the
* EVK1100 board rev. B and C.
*
* To use this board, define BOARD=EVK1100.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 AT32UC3A devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _ARDUINO_H_
#define _ARDUINO_H_
#include "compiler.h"
#ifdef __AVR32_ABI_COMPILER__ // Automatically defined when compiling for AVR32, not when assembling.
# include "led.h"
#endif // __AVR32_ABI_COMPILER__
/*! \name Oscillator Definitions
*/
//! @{
// RCOsc has no custom calibration by default. Set the following definition to
// the appropriate value if a custom RCOsc calibration has been applied to your
// part.
//#define FRCOSC AVR32_PM_RCOSC_FREQUENCY //!< RCOsc frequency: Hz.
#define FOSC32 32768 //!< Osc32 frequency: Hz.
#define OSC32_STARTUP AVR32_PM_OSCCTRL32_STARTUP_8192_RCOSC //!< Osc32 startup time: RCOsc periods.
#define FOSC0 12000000 //!< Osc0 frequency: Hz.
#define OSC0_STARTUP AVR32_PM_OSCCTRL0_STARTUP_2048_RCOSC //!< Osc0 startup time: RCOsc periods.
// Osc1 crystal is not mounted by default. Set the following definitions to the
// appropriate values if a custom Osc1 crystal is mounted on your board.
//#define FOSC1 12000000 //!< Osc1 frequency: Hz.
//#define OSC1_STARTUP AVR32_PM_OSCCTRL1_STARTUP_2048_RCOSC //!< Osc1 startup time: RCOsc periods.
//! @}
//! Number of LEDs.
#define LED_COUNT 0
/*! \name GPIO Connections of LEDs
*/
//! @{
#define LED0_GPIO AVR32_PIN_PB19
#define LED1_GPIO AVR32_PIN_PB20
#define LED2_GPIO AVR32_PIN_PB21
#define DEB_PIN_GPIO AVR32_PIN_PA20
#define DEB2_PIN_GPIO AVR32_PIN_PB00
//! @}
/*! \name PWM Channels of LEDs
*/
//! @{
#define LED0_PWM 0
#define LED1_PWM 1
#define LED2_PWM 2
//! @}
/*! \name PWM Functions of LEDs
*/
//! @{
#define LED0_PWM_FUNCTION AVR32_PWM_0_FUNCTION
#define LED1_PWM_FUNCTION AVR32_PWM_1_FUNCTION
#define LED2_PWM_FUNCTION AVR32_PWM_2_FUNCTION
//! @}
/*! \name Color Identifiers of LEDs to Use with LED Functions
*/
//! @{
#define LED_MONO0_GREEN LED0
#define LED_MONO1_RED LED1
#define LED_MONO2_BLU LED2
//! @}
#if 0
/*! \name SPI Connections of the DIP204 LCD
*/
//! @{
#define DIP204_SPI (&AVR32_SPI1)
#define DIP204_SPI_NPCS 2
#define DIP204_SPI_SCK_PIN AVR32_SPI1_SCK_0_0_PIN
#define DIP204_SPI_SCK_FUNCTION AVR32_SPI1_SCK_0_0_FUNCTION
#define DIP204_SPI_MISO_PIN AVR32_SPI1_MISO_0_0_PIN
#define DIP204_SPI_MISO_FUNCTION AVR32_SPI1_MISO_0_0_FUNCTION
#define DIP204_SPI_MOSI_PIN AVR32_SPI1_MOSI_0_0_PIN
#define DIP204_SPI_MOSI_FUNCTION AVR32_SPI1_MOSI_0_0_FUNCTION
#define DIP204_SPI_NPCS_PIN AVR32_SPI1_NPCS_2_0_PIN
#define DIP204_SPI_NPCS_FUNCTION AVR32_SPI1_NPCS_2_0_FUNCTION
//! @}
/*! \name GPIO and PWM Connections of the DIP204 LCD Backlight
*/
//! @{
#define DIP204_BACKLIGHT_PIN AVR32_PIN_PB18
#define DIP204_PWM_CHANNEL 6
#define DIP204_PWM_PIN AVR32_PWM_6_PIN
#define DIP204_PWM_FUNCTION AVR32_PWM_6_FUNCTION
//! @}
#endif
/*! \name SPI Connections of the AT45DBX Data Flash Memory
*/
//! @{
#define AT45DBX_SPI (&AVR32_SPI1)
#define AT45DBX_SPI_NPCS 2
#define AT45DBX_SPI_SCK_PIN AVR32_SPI1_SCK_0_0_PIN
#define AT45DBX_SPI_SCK_FUNCTION AVR32_SPI1_SCK_0_0_FUNCTION
#define AT45DBX_SPI_MISO_PIN AVR32_SPI1_MISO_0_0_PIN
#define AT45DBX_SPI_MISO_FUNCTION AVR32_SPI1_MISO_0_0_FUNCTION
#define AT45DBX_SPI_MOSI_PIN AVR32_SPI1_MOSI_0_0_PIN
#define AT45DBX_SPI_MOSI_FUNCTION AVR32_SPI1_MOSI_0_0_FUNCTION
#define AT45DBX_SPI_NPCS2_PIN AVR32_SPI1_NPCS_2_0_PIN
#define AT45DBX_SPI_NPCS2_FUNCTION AVR32_SPI1_NPCS_2_0_FUNCTION
#define AT45DBX_CHIP_RESET AVR32_PIN_PA02
//! @}
/*! \name GPIO and SPI Connections of the SD/MMC Connector
*/
//! @{
//#define SD_MMC_CARD_DETECT_PIN AVR32_PIN_PA02
//#define SD_MMC_WRITE_PROTECT_PIN AVR32_PIN_PA07
#define SD_MMC_SPI (&AVR32_SPI1)
#define SD_MMC_SPI_NPCS 1
#define SD_MMC_SPI_SCK_PIN AVR32_SPI1_SCK_0_0_PIN
#define SD_MMC_SPI_SCK_FUNCTION AVR32_SPI1_SCK_0_0_FUNCTION
#define SD_MMC_SPI_MISO_PIN AVR32_SPI1_MISO_0_0_PIN
#define SD_MMC_SPI_MISO_FUNCTION AVR32_SPI1_MISO_0_0_FUNCTION
#define SD_MMC_SPI_MOSI_PIN AVR32_SPI1_MOSI_0_0_PIN
#define SD_MMC_SPI_MOSI_FUNCTION AVR32_SPI1_MOSI_0_0_FUNCTION
#define SD_MMC_SPI_NPCS_PIN AVR32_SPI1_NPCS_1_0_PIN
#define SD_MMC_SPI_NPCS_FUNCTION AVR32_SPI1_NPCS_1_0_FUNCTION
//! @}
/* Timer Counter to generate clock for WiFi chip*/
# define WIFI_TC (&AVR32_TC)
# define WIFI_TC_CHANNEL_ID 0
# define WIFI_TC_CHANNEL_PIN AVR32_TC_A0_0_0_PIN
# define WIFI_TC_CHANNEL_FUNCTION AVR32_TC_A0_0_0_FUNCTION
// Note that TC_A0_0_0 pin is pin 6 (PB23) on AT32UC3A1512 QFP100.
/* Pin related to WiFi chip communication */
#ifndef USE_POLL
#define USE_POLL
#endif
#define SPI_CS 0
#define AVR32_SPI AVR32_SPI1
#define GPIO_IRQ_PIN AVR32_PIN_PA03
#define GPIO_IRQ AVR32_GPIO_IRQ_7
#define GPIO_W_RESET_PIN AVR32_PIN_PA07
#define GPIO_W_SHUTDOWN_PIN AVR32_PIN_PA09
/* Pin related to shield communication */
#define ARDUINO_HANDSHAKE_PIN AVR32_PIN_PA25
#define ARDUINO_EXTINT_PIN AVR32_PIN_PA04 //not used
#define AVR32_PDCA_PID_TX AVR32_PDCA_PID_SPI1_TX
#define AVR32_PDCA_PID_RX AVR32_PDCA_PID_SPI1_RX
#if 0
/*! \name TWI Connections of the Spare TWI Connector
*/
//! @{
#define SPARE_TWI (&AVR32_TWI)
#define SPARE_TWI_SCL_PIN AVR32_TWI_SCL_0_0_PIN
#define SPARE_TWI_SCL_FUNCTION AVR32_TWI_SCL_0_0_FUNCTION
#define SPARE_TWI_SDA_PIN AVR32_TWI_SDA_0_0_PIN
#define SPARE_TWI_SDA_FUNCTION AVR32_TWI_SDA_0_0_FUNCTION
//! @}
/*! \name SPI Connections of the Spare SPI Connector
*/
//! @{
#define SPARE_SPI (&AVR32_SPI0)
#define SPARE_SPI_NPCS 0
#define SPARE_SPI_SCK_PIN AVR32_SPI0_SCK_0_0_PIN
#define SPARE_SPI_SCK_FUNCTION AVR32_SPI0_SCK_0_0_FUNCTION
#define SPARE_SPI_MISO_PIN AVR32_SPI0_MISO_0_0_PIN
#define SPARE_SPI_MISO_FUNCTION AVR32_SPI0_MISO_0_0_FUNCTION
#define SPARE_SPI_MOSI_PIN AVR32_SPI0_MOSI_0_0_PIN
#define SPARE_SPI_MOSI_FUNCTION AVR32_SPI0_MOSI_0_0_FUNCTION
#define SPARE_SPI_NPCS_PIN AVR32_SPI0_NPCS_0_0_PIN
#define SPARE_SPI_NPCS_FUNCTION AVR32_SPI0_NPCS_0_0_FUNCTION
//! @}
#endif
#endif // _ARDUINO_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT32UC3A EVK1100 board LEDs support package.
*
* This file contains definitions and services related to the LED features of
* the EVK1100 board.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 AT32UC3A devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <avr32/io.h>
#include "preprocessor.h"
#include "compiler.h"
#include "arduino.h"
#include "led.h"
//! Structure describing LED hardware connections.
typedef const struct
{
struct
{
U32 PORT; //!< LED GPIO port.
U32 PIN_MASK; //!< Bit-mask of LED pin in GPIO port.
} GPIO; //!< LED GPIO descriptor.
struct
{
S32 CHANNEL; //!< LED PWM channel (< 0 if N/A).
S32 FUNCTION; //!< LED pin PWM function (< 0 if N/A).
} PWM; //!< LED PWM descriptor.
} tLED_DESCRIPTOR;
//! Hardware descriptors of all LEDs.
static tLED_DESCRIPTOR LED_DESCRIPTOR[LED_COUNT] =
{
#define INSERT_LED_DESCRIPTOR(LED_NO, unused) \
{ \
{LED##LED_NO##_GPIO / 32, 1 << (LED##LED_NO##_GPIO % 32)},\
{LED##LED_NO##_PWM, LED##LED_NO##_PWM_FUNCTION } \
},
MREPEAT(LED_COUNT, INSERT_LED_DESCRIPTOR, ~)
#undef INSERT_LED_DESCRIPTOR
};
//! Saved state of all LEDs.
static volatile U32 LED_State = (1 << LED_COUNT) - 1;
U32 LED_Read_Display(void)
{
return LED_State;
}
void LED_Display(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor;
volatile avr32_gpio_port_t *led_gpio_port;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
LED_State = leds;
// For all LEDs...
for (led_descriptor = &LED_DESCRIPTOR[0];
led_descriptor < LED_DESCRIPTOR + LED_COUNT;
led_descriptor++)
{
// Set the LED to the requested state.
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
if (leds & 1)
{
led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;
}
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= 1;
}
}
U32 LED_Read_Display_Mask(U32 mask)
{
return Rd_bits(LED_State, mask);
}
void LED_Display_Mask(U32 mask, U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
mask &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Wr_bits(LED_State, mask, leds);
// While there are specified LEDs left to manage...
while (mask)
{
// Select the next specified LED and set it to the requested state.
led_shift = 1 + ctz(mask);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
leds >>= led_shift - 1;
if (leds & 1)
{
led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;
}
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= 1;
mask >>= led_shift;
}
}
Bool LED_Test(U32 leds)
{
return Tst_bits(LED_State, leds);
}
void LED_Off(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Clr_bits(LED_State, leds);
// While there are specified LEDs left to manage...
while (leds)
{
// Select the next specified LED and turn it off.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= led_shift;
}
}
void LED_On(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Set_bits(LED_State, leds);
// While there are specified LEDs left to manage...
while (leds)
{
// Select the next specified LED and turn it on.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= led_shift;
}
}
void LED_Toggle(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Tgl_bits(LED_State, leds);
// While there are specified LEDs left to manage...
while (leds)
{
// Select the next specified LED and toggle it.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
led_gpio_port->ovrt = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= led_shift;
}
}
U32 LED_Read_Display_Field(U32 field)
{
return Rd_bitfield(LED_State, field);
}
void LED_Display_Field(U32 field, U32 leds)
{
// Move the bit-field to the appropriate position for the bit-mask.
LED_Display_Mask(field, leds << ctz(field));
}
U8 LED_Get_Intensity(U32 led)
{
tLED_DESCRIPTOR *led_descriptor;
// Check that the argument value is valid.
led = ctz(led);
led_descriptor = &LED_DESCRIPTOR[led];
if (led >= LED_COUNT || led_descriptor->PWM.CHANNEL < 0) return 0;
// Return the duty cycle value if the LED PWM channel is enabled, else 0.
return (AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)) ?
AVR32_PWM.channel[led_descriptor->PWM.CHANNEL].cdty : 0;
}
void LED_Set_Intensity(U32 leds, U8 intensity)
{
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_pwm_channel_t *led_pwm_channel;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// For each specified LED...
for (leds &= (1 << LED_COUNT) - 1; leds; leds >>= led_shift)
{
// Select the next specified LED and check that it has a PWM channel.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
if (led_descriptor->PWM.CHANNEL < 0) continue;
// Initialize or update the LED PWM channel.
led_pwm_channel = &AVR32_PWM.channel[led_descriptor->PWM.CHANNEL];
if (!(AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)))
{
led_pwm_channel->cmr = (AVR32_PWM_CPRE_MCK << AVR32_PWM_CPRE_OFFSET) &
~(AVR32_PWM_CALG_MASK |
AVR32_PWM_CPOL_MASK |
AVR32_PWM_CPD_MASK);
led_pwm_channel->cprd = 0x000000FF;
led_pwm_channel->cdty = intensity;
AVR32_PWM.ena = 1 << led_descriptor->PWM.CHANNEL;
}
else
{
AVR32_PWM.isr;
while (!(AVR32_PWM.isr & (1 << led_descriptor->PWM.CHANNEL)));
led_pwm_channel->cupd = intensity;
}
// Switch the LED pin to its PWM function.
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
if (led_descriptor->PWM.FUNCTION & 0x1)
{
led_gpio_port->pmr0s = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->pmr0c = led_descriptor->GPIO.PIN_MASK;
}
if (led_descriptor->PWM.FUNCTION & 0x2)
{
led_gpio_port->pmr1s = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->pmr1c = led_descriptor->GPIO.PIN_MASK;
}
led_gpio_port->gperc = led_descriptor->GPIO.PIN_MASK;
}
}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT32UC3A EVK1100 board LEDs support package.
*
* This file contains definitions and services related to the LED features of
* the EVK1100 board.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 AT32UC3A devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _LED_H_
#define _LED_H_
#include "compiler.h"
/*! \name Identifiers of LEDs to Use with LED Functions
*/
//! @{
#define LED0 0x01
#define LED1 0x02
#define LED2 0x04
#define LED3 0x08
#define LED4 0x10
#define LED5 0x20
#define LED6 0x40
#define LED7 0x80
//! @}
/*! \brief Gets the last state of all LEDs set through the LED API.
*
* \return State of all LEDs (1 bit per LED).
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U32 LED_Read_Display(void);
/*! \brief Sets the state of all LEDs.
*
* \param leds New state of all LEDs (1 bit per LED).
*
* \note The pins of all LEDs are set to GPIO output mode.
*/
extern void LED_Display(U32 leds);
/*! \brief Gets the last state of the specified LEDs set through the LED API.
*
* \param mask LEDs of which to get the state (1 bit per LED).
*
* \return State of the specified LEDs (1 bit per LED).
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U32 LED_Read_Display_Mask(U32 mask);
/*! \brief Sets the state of the specified LEDs.
*
* \param mask LEDs of which to set the state (1 bit per LED).
*
* \param leds New state of the specified LEDs (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Display_Mask(U32 mask, U32 leds);
/*! \brief Tests the last state of the specified LEDs set through the LED API.
*
* \param leds LEDs of which to test the state (1 bit per LED).
*
* \return \c TRUE if at least one of the specified LEDs has a state on, else
* \c FALSE.
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern Bool LED_Test(U32 leds);
/*! \brief Turns off the specified LEDs.
*
* \param leds LEDs to turn off (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Off(U32 leds);
/*! \brief Turns on the specified LEDs.
*
* \param leds LEDs to turn on (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_On(U32 leds);
/*! \brief Toggles the specified LEDs.
*
* \param leds LEDs to toggle (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Toggle(U32 leds);
/*! \brief Gets as a bit-field the last state of the specified LEDs set through
* the LED API.
*
* \param field LEDs of which to get the state (1 bit per LED).
*
* \return State of the specified LEDs (1 bit per LED, beginning with the first
* specified LED).
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U32 LED_Read_Display_Field(U32 field);
/*! \brief Sets as a bit-field the state of the specified LEDs.
*
* \param field LEDs of which to set the state (1 bit per LED).
* \param leds New state of the specified LEDs (1 bit per LED, beginning with
* the first specified LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Display_Field(U32 field, U32 leds);
/*! \brief Gets the intensity of the specified LED.
*
* \param led LED of which to get the intensity (1 bit per LED; only the least
* significant set bit is used).
*
* \return Intensity of the specified LED (0x00 to 0xFF).
*
* \warning The PWM channel of the specified LED is supposed to be used only by
* this module.
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U8 LED_Get_Intensity(U32 led);
/*! \brief Sets the intensity of the specified LEDs.
*
* \param leds LEDs of which to set the intensity (1 bit per LED).
* \param intensity New intensity of the specified LEDs (0x00 to 0xFF).
*
* \warning The PWM channels of the specified LEDs are supposed to be used only
* by this module.
*
* \note The pins of the specified LEDs are set to PWM output mode.
*/
extern void LED_Set_Intensity(U32 leds, U8 intensity);
#endif // _LED_H_

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT32UC3A EVK1105 board header file.
*
* This file contains definitions and services related to the features of the
* EVK1105 board rev. B.
*
* To use this board, define BOARD=EVK1105.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 AT32UC3A devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _EVK1105_H_
#define _EVK1105_H_
#ifdef EVK1105_REV3
# include "evk1105_rev3.h"
#else
#include "compiler.h"
#ifdef __AVR32_ABI_COMPILER__ // Automatically defined when compiling for AVR32, not when assembling.
# include "led.h"
#endif // __AVR32_ABI_COMPILER__
/*! \name Oscillator Definitions
*/
//! @{
// RCOsc has no custom calibration by default. Set the following definition to
// the appropriate value if a custom RCOsc calibration has been applied to your
// part.
//#define FRCOSC AVR32_PM_RCOSC_FREQUENCY //!< RCOsc frequency: Hz.
#define FOSC32 32768 //!< Osc32 frequency: Hz.
#define OSC32_STARTUP AVR32_PM_OSCCTRL32_STARTUP_8192_RCOSC //!< Osc32 startup time: RCOsc periods.
#define FOSC0 12000000 //!< Osc0 frequency: Hz.
#define OSC0_STARTUP AVR32_PM_OSCCTRL0_STARTUP_2048_RCOSC //!< Osc0 startup time: RCOsc periods.
#define FOSC1 11289600 //!< Osc1 frequency: Hz
#define OSC1_STARTUP AVR32_PM_OSCCTRL1_STARTUP_2048_RCOSC //!< Osc1 startup time: RCOsc periods.
//! @}
/*! \name SDRAM Definitions
*/
//! @{
//! Part header file of used SDRAM(s).
#define SDRAM_PART_HDR "MT48LC16M16A2TG7E/mt48lc16m16a2tg7e.h"
//! Data bus width to use the SDRAM(s) with (16 or 32 bits; always 16 bits on
//! UC3).
#define SDRAM_DBW 16
//! @}
/*! \name USB Definitions
*/
//! @{
//! Multiplexed pin used for USB_ID: AVR32_USBB_USB_ID_x_x.
//! To be selected according to the AVR32_USBB_USB_ID_x_x_PIN and
//! AVR32_USBB_USB_ID_x_x_FUNCTION definitions from <avr32/uc3axxxx.h>.
#define AVR32_USBB_USB_ID_0_2_PIN 21
#define AVR32_USBB_USB_ID_0_2_FUNCTION 2
#define USB_ID AVR32_USBB_USB_ID_0_2
//! Multiplexed pin used for USB_VBOF: AVR32_USBB_USB_VBOF_x_x.
//! To be selected according to the AVR32_USBB_USB_VBOF_x_x_PIN and
//! AVR32_USBB_USB_VBOF_x_x_FUNCTION definitions from <avr32/uc3axxxx.h>.
# define USB_VBOF AVR32_USBB_USB_VBOF_0_1
//! Active level of the USB_VBOF output pin.
# define USB_VBOF_ACTIVE_LEVEL LOW
//! USB overcurrent detection pin.
# define USB_OVERCURRENT_DETECT_PIN AVR32_PIN_PX15
//! @}
//! GPIO connection of the MAC PHY PWR_DOWN/INT signal.
# define MACB_INTERRUPT_PIN AVR32_PIN_PA26
//! Number of LEDs.
#define LED_COUNT 4
/*! \name GPIO Connections of LEDs
*/
//! @{
# define LED0_GPIO AVR32_PIN_PB27
# define LED1_GPIO AVR32_PIN_PB28
# define LED2_GPIO AVR32_PIN_PA05
# define LED3_GPIO AVR32_PIN_PA06
//! @}
/*! \name Color Identifiers of LEDs to Use with LED Functions
*/
//! @{
#define LED_MONO0_GREEN LED0
#define LED_MONO1_GREEN LED1
#define LED_MONO2_GREEN LED2
#define LED_MONO3_GREEN LED3
//! @}
/*! \name PWM Channels of LEDs
*/
//! @{
#define LED0_PWM 4
#define LED1_PWM 5
#define LED2_PWM (-1)
#define LED3_PWM (-1)
//! @}
/*! \name PWM Functions of LEDs
*/
//! @{
/* TODO: Implement PWM functionality */
#define LED0_PWM_FUNCTION (-1)//AVR32_PWM_0_FUNCTION
#define LED1_PWM_FUNCTION (-1)//AVR32_PWM_1_FUNCTION
#define LED2_PWM_FUNCTION (-1)
#define LED3_PWM_FUNCTION (-1)
//! @}
//! External interrupt connection of touch sensor.
#define QT1081_EIC_EXTINT_PIN AVR32_EIC_EXTINT_1_PIN
#define QT1081_EIC_EXTINT_FUNCTION AVR32_EIC_EXTINT_1_FUNCTION
#define QT1081_EIC_EXTINT_IRQ AVR32_EIC_IRQ_1
#define QT1081_EIC_EXTINT_INT AVR32_EIC_INT1
/*! \name Touch sensor low power mode select
*/
#define QT1081_LP_MODE AVR32_PIN_PB29
/*! \name GPIO Connections of touch buttons
*/
//! @{
#define QT1081_TOUCH_SENSOR_0 AVR32_PIN_PB22
#define QT1081_TOUCH_SENSOR_0_PRESSED 1
#define QT1081_TOUCH_SENSOR_1 AVR32_PIN_PB23
#define QT1081_TOUCH_SENSOR_1_PRESSED 1
#define QT1081_TOUCH_SENSOR_2 AVR32_PIN_PB24
#define QT1081_TOUCH_SENSOR_2_PRESSED 1
#define QT1081_TOUCH_SENSOR_3 AVR32_PIN_PB25
#define QT1081_TOUCH_SENSOR_3_PRESSED 1
#define QT1081_TOUCH_SENSOR_4 AVR32_PIN_PB26
#define QT1081_TOUCH_SENSOR_4_PRESSED 1
#define QT1081_TOUCH_SENSOR_ENTER QT1081_TOUCH_SENSOR_4
#define QT1081_TOUCH_SENSOR_ENTER_PRESSED QT1081_TOUCH_SENSOR_4_PRESSED
#define QT1081_TOUCH_SENSOR_LEFT QT1081_TOUCH_SENSOR_3
#define QT1081_TOUCH_SENSOR_LEFT_PRESSED QT1081_TOUCH_SENSOR_3_PRESSED
#define QT1081_TOUCH_SENSOR_RIGHT QT1081_TOUCH_SENSOR_2
#define QT1081_TOUCH_SENSOR_RIGHT_PRESSED QT1081_TOUCH_SENSOR_2_PRESSED
#define QT1081_TOUCH_SENSOR_UP QT1081_TOUCH_SENSOR_0
#define QT1081_TOUCH_SENSOR_UP_PRESSED QT1081_TOUCH_SENSOR_0_PRESSED
#define QT1081_TOUCH_SENSOR_DOWN QT1081_TOUCH_SENSOR_1
#define QT1081_TOUCH_SENSOR_DOWN_PRESSED QT1081_TOUCH_SENSOR_1_PRESSED
//! @}
/*! \name SPI Connections of the AT45DBX Data Flash Memory
*/
//! @{
#define AT45DBX_SPI (&AVR32_SPI0)
#define AT45DBX_SPI_NPCS 0
#define AT45DBX_SPI_SCK_PIN AVR32_SPI0_SCK_0_0_PIN
#define AT45DBX_SPI_SCK_FUNCTION AVR32_SPI0_SCK_0_0_FUNCTION
#define AT45DBX_SPI_MISO_PIN AVR32_SPI0_MISO_0_0_PIN
#define AT45DBX_SPI_MISO_FUNCTION AVR32_SPI0_MISO_0_0_FUNCTION
#define AT45DBX_SPI_MOSI_PIN AVR32_SPI0_MOSI_0_0_PIN
#define AT45DBX_SPI_MOSI_FUNCTION AVR32_SPI0_MOSI_0_0_FUNCTION
#define AT45DBX_SPI_NPCS0_PIN AVR32_SPI0_NPCS_0_0_PIN
#define AT45DBX_SPI_NPCS0_FUNCTION AVR32_SPI0_NPCS_0_0_FUNCTION
//! @}
/*! \name GPIO and SPI Connections of the SD/MMC Connector
*/
//! @{
#define SD_MMC_CARD_DETECT_PIN AVR32_PIN_PA02
#define SD_MMC_WRITE_PROTECT_PIN AVR32_PIN_PA18
#define SD_MMC_SPI (&AVR32_SPI0)
#define SD_MMC_SPI_NPCS 1
#define SD_MMC_SPI_SCK_PIN AVR32_SPI0_SCK_0_0_PIN
#define SD_MMC_SPI_SCK_FUNCTION AVR32_SPI0_SCK_0_0_FUNCTION
#define SD_MMC_SPI_MISO_PIN AVR32_SPI0_MISO_0_0_PIN
#define SD_MMC_SPI_MISO_FUNCTION AVR32_SPI0_MISO_0_0_FUNCTION
#define SD_MMC_SPI_MOSI_PIN AVR32_SPI0_MOSI_0_0_PIN
#define SD_MMC_SPI_MOSI_FUNCTION AVR32_SPI0_MOSI_0_0_FUNCTION
#define SD_MMC_SPI_NPCS_PIN AVR32_SPI0_NPCS_1_0_PIN
#define SD_MMC_SPI_NPCS_FUNCTION AVR32_SPI0_NPCS_1_0_FUNCTION
//! @}
/*! \name TWI expansion
*/
//! @{
#define EXPANSION_TWI (&AVR32_TWI)
#define EXPANSION_RESET AVR32_PIN_PX16
#define EXPANSION_TWI_SCL_PIN AVR32_TWI_SCL_0_0_PIN
#define EXPANSION_TWI_SCL_FUNCTION AVR32_TWI_SCL_0_0_FUNCTION
#define EXPANSION_TWI_SDA_PIN AVR32_TWI_SDA_0_0_PIN
#define EXPANSION_TWI_SDA_FUNCTION AVR32_TWI_SDA_0_0_FUNCTION
//! @}
/*! \name Wireless expansion
*/
#define WEXPANSION_EXTINT_PIN AVR32_EIC_EXTINT_8_PIN
#define WEXPANSION_EXTINT_FUNCTION AVR32_EIC_EXTINT_8_FUNCTION
#define WEXPANSION_GPIO1 AVR32_PIN_PB30
#define WEXPANSION_GPIO2 AVR32_PIN_PB31
#define WEXPANSION_SPI (&AVR32_SPI0)
#define WEXPANSION_SPI_NPCS 2
#define WEXPANSION_SPI_SCK_PIN AVR32_SPI0_SCK_0_0_PIN
#define WEXPANSION_SPI_SCK_FUNCTION AVR32_SPI0_SCK_0_0_FUNCTION
#define WEXPANSION_SPI_MISO_PIN AVR32_SPI0_MISO_0_0_PIN
#define WEXPANSION_SPI_MISO_FUNCTION AVR32_SPI0_MISO_0_0_FUNCTION
#define WEXPANSION_SPI_MOSI_PIN AVR32_SPI0_MOSI_0_0_PIN
#define WEXPANSION_SPI_MOSI_FUNCTION AVR32_SPI0_MOSI_0_0_FUNCTION
#define WEXPANSION_SPI_NPCS_PIN AVR32_SPI0_NPCS_2_0_PIN
#define WEXPANSION_SPI_NPCS_FUNCTION AVR32_SPI0_NPCS_2_0_FUNCTION
//! @}
/*! \name ET024006DHU TFT display
*/
//! @{
#define ET024006DHU_TE_PIN AVR32_PIN_PX19
#define ET024006DHU_RESET_PIN AVR32_PIN_PX22
#define ET024006DHU_BL_PIN AVR32_PWM_6_PIN
#define ET024006DHU_BL_FUNCTION AVR32_PWM_6_FUNCTION
#define ET024006DHU_DNC_PIN AVR32_EBI_ADDR_21_1_PIN
#define ET024006DHU_DNC_FUNCTION AVR32_EBI_ADDR_21_1_FUNCTION
#define ET024006DHU_EBI_NCS_PIN AVR32_EBI_NCS_0_1_PIN
#define ET024006DHU_EBI_NCS_FUNCTION AVR32_EBI_NCS_0_1_FUNCTION
//! @}
/*! \name Optional SPI connection to the TFT
*/
//! @{
#define ET024006DHU_SPI (&AVR32_SPI0)
#define ET024006DHU_SPI_NPCS 3
#define ET024006DHU_SPI_SCK_PIN AVR32_SPI0_SCK_0_0_PIN
#define ET024006DHU_SPI_SCK_FUNCTION AVR32_SPI0_SCK_0_0_FUNCTION
#define ET024006DHU_SPI_MISO_PIN AVR32_SPI0_MISO_0_0_PIN
#define ET024006DHU_SPI_MISO_FUNCTION AVR32_SPI0_MISO_0_0_FUNCTION
#define ET024006DHU_SPI_MOSI_PIN AVR32_SPI0_MOSI_0_0_PIN
#define ET024006DHU_SPI_MOSI_FUNCTION AVR32_SPI0_MOSI_0_0_FUNCTION
#define ET024006DHU_SPI_NPCS_PIN AVR32_SPI1_NPCS_3_0_PIN
#define ET024006DHU_SPI_NPCS_FUNCTION AVR32_SPI1_NPCS_3_0_FUNCTION
//! @}
/*! \name Audio amplifier connection to the DAC
*/
//! @{
#define TPA6130_ABDAC (&AVR32_ABDAC)
#define TPA6130_DATA0_PIN AVR32_ABDAC_DATA_0_1_PIN
#define TPA6130_DATA0_FUNCTION AVR32_ABDAC_DATA_0_1_FUNCTION
#define TPA6130_DATAN0_PIN AVR32_ABDAC_DATAN_0_1_PIN
#define TPA6130_DATAN0_FUNCTION AVR32_ABDAC_DATAN_0_1_FUNCTION
#define TPA6130_DATA1_PIN AVR32_ABDAC_DATA_1_1_PIN
#define TPA6130_DATA1_FUNCTION AVR32_ABDAC_DATA_1_1_FUNCTION
#define TPA6130_DATAN1_PIN AVR32_ABDAC_DATAN_1_1_PIN
#define TPA6130_DATAN1_FUNCTION AVR32_ABDAC_DATAN_1_1_FUNCTION
#define TPA6130_ABDAC_PDCA_PID AVR32_PDCA_PID_ABDAC_TX
#define TPA6130_ABDAC_PDCA_CHANNEL 0
#define TPA6130_ABDAC_PDCA_IRQ AVR32_PDCA_IRQ_0
#define TPA6130_ABDAC_PDCA_INT_LEVEL AVR32_INTC_INT3
#define TPA6130_TWI (&AVR32_TWI)
#define TPA6130_TWI_SCL_PIN AVR32_TWI_SCL_0_0_PIN
#define TPA6130_TWI_SCL_FUNCTION AVR32_TWI_SCL_0_0_FUNCTION
#define TPA6130_TWI_SDA_PIN AVR32_TWI_SDA_0_0_PIN
#define TPA6130_TWI_SDA_FUNCTION AVR32_TWI_SDA_0_0_FUNCTION
//! }@
/*! \name TI TLV320AIC23B sound chip
*/
//! @{
#define TLV320_SSC (&AVR32_SSC)
#define TLV320_SSC_TX_CLOCK_PIN AVR32_SSC_TX_CLOCK_0_PIN
#define TLV320_SSC_TX_CLOCK_FUNCTION AVR32_SSC_TX_CLOCK_0_FUNCTION
#define TLV320_SSC_TX_DATA_PIN AVR32_SSC_TX_DATA_0_PIN
#define TLV320_SSC_TX_DATA_FUNCTION AVR32_SSC_TX_DATA_0_FUNCTION
#define TLV320_SSC_TX_FRAME_SYNC_PIN AVR32_SSC_TX_FRAME_SYNC_0_PIN
#define TLV320_SSC_TX_FRAME_SYNC_FUNCTION AVR32_SSC_TX_FRAME_SYNC_0_FUNCTION
#define TLV320_TWI (&AVR32_TWI)
#define TLV320_TWI_SCL_PIN AVR32_TWI_SCL_0_0_PIN
#define TLV320_TWI_SCL_FUNCTION AVR32_TWI_SCL_0_0_FUNCTION
#define TLV320_TWI_SDA_PIN AVR32_TWI_SDA_0_0_PIN
#define TLV320_TWI_SDA_FUNCTION AVR32_TWI_SDA_0_0_FUNCTION
#define TLV320_PM_GCLK_PIN AVR32_PM_GCLK_0_0_PIN
#define TLV320_PM_GCLK_FUNCTION AVR32_PM_GCLK_0_0_FUNCTION
//! @}
////! \name SPI: Apple Authentication Chip Hardware Connections
////! @{
#define IPOD_AUTH_CHIP_SPI (&AVR32_SPI0)
#define IPOD_AUTH_CHIP_SPI_IRQ AVR32_SPI0_IRQ
#define IPOD_AUTH_CHIP_SPI_NPCS 2
#define IPOD_AUTH_CHIP_SPI_SCK_PIN AVR32_SPI0_SCK_0_0_PIN
#define IPOD_AUTH_CHIP_SPI_SCK_FUNCTION AVR32_SPI0_SCK_0_0_FUNCTION
#define IPOD_AUTH_CHIP_SPI_MISO_PIN AVR32_SPI0_MISO_0_0_PIN
#define IPOD_AUTH_CHIP_SPI_MISO_FUNCTION AVR32_SPI0_MISO_0_0_FUNCTION
#define IPOD_AUTH_CHIP_SPI_MOSI_PIN AVR32_SPI0_MOSI_0_0_PIN
#define IPOD_AUTH_CHIP_SPI_MOSI_FUNCTION AVR32_SPI0_MOSI_0_0_FUNCTION
#define IPOD_AUTH_CHIP_SPI_NPCS_PIN AVR32_SPI0_NPCS_2_0_PIN
#define IPOD_AUTH_CHIP_SPI_NPCS_FUNCTION AVR32_SPI0_NPCS_2_0_FUNCTION
#define IPOD_AUTH_CHIP_SPI_N_RESET_PIN AVR32_PIN_PB30
#define IPOD_AUTH_CHIP_SPI_CP_READY_PIN AVR32_PIN_PB31
//! }@
/*! \name Connections of the iPOD Authentication Coprocessor
*/
//! @{
#define IPOD_AUTH_CHIP_TWI (&AVR32_TWI)
#define IPOD_AUTH_CHIP_TWI_SCL_PIN AVR32_TWI_SCL_0_0_PIN
#define IPOD_AUTH_CHIP_TWI_SCL_FUNCTION AVR32_TWI_SCL_0_0_FUNCTION
#define IPOD_AUTH_CHIP_TWI_SDA_PIN AVR32_TWI_SDA_0_0_PIN
#define IPOD_AUTH_CHIP_TWI_SDA_FUNCTION AVR32_TWI_SDA_0_0_FUNCTION
#define IPOD_AUTH_CHIP_TWI_N_RESET_PIN AVR32_PIN_PX16
//! @}
/*! \name USART connection to the UC3B board controller
*/
//! @{
#define USART0_RXD_PIN AVR32_USART0_RXD_0_0_PIN
#define USART0_RXD_FUNCTION AVR32_USART0_RXD_0_0_FUNCTION
#define USART0_TXD_PIN AVR32_USART0_TXD_0_0_PIN
#define USART0_TXD_FUNCTION AVR32_USART0_TXD_0_0_FUNCTION
#define USART0_RTS_PIN AVR32_USART0_RTS_0_0_PIN
#define USART0_RTS_FUNCTION AVR32_USART0_RTS_0_0_FUNCTION
#define USART0_CTS_PIN AVR32_USART0_CTS_0_0_PIN
#define USART0_CTS_FUNCTION AVR32_USART0_CTS_0_0_FUNCTION
//! @}
#define ADC_VEXT_PIN AVR32_ADC_AD_7_PIN
#define ADC_VEXT_FUNCTION AVR32_ADC_AD_7_FUNCTION
/*! \name LCD Connections of the ET024006DHU display
*/
//! @{
#define ET024006DHU_SMC_USE_NCS 0
#define ET024006DHU_SMC_COMPONENT_CS "smc_et024006dhu.h"
#define ET024006DHU_EBI_DATA_0 AVR32_EBI_DATA_0
#define ET024006DHU_EBI_DATA_1 AVR32_EBI_DATA_1
#define ET024006DHU_EBI_DATA_2 AVR32_EBI_DATA_2
#define ET024006DHU_EBI_DATA_3 AVR32_EBI_DATA_3
#define ET024006DHU_EBI_DATA_4 AVR32_EBI_DATA_4
#define ET024006DHU_EBI_DATA_5 AVR32_EBI_DATA_5
#define ET024006DHU_EBI_DATA_6 AVR32_EBI_DATA_6
#define ET024006DHU_EBI_DATA_7 AVR32_EBI_DATA_7
#define ET024006DHU_EBI_DATA_8 AVR32_EBI_DATA_8
#define ET024006DHU_EBI_DATA_9 AVR32_EBI_DATA_9
#define ET024006DHU_EBI_DATA_10 AVR32_EBI_DATA_10
#define ET024006DHU_EBI_DATA_11 AVR32_EBI_DATA_11
#define ET024006DHU_EBI_DATA_12 AVR32_EBI_DATA_12
#define ET024006DHU_EBI_DATA_13 AVR32_EBI_DATA_13
#define ET024006DHU_EBI_DATA_14 AVR32_EBI_DATA_14
#define ET024006DHU_EBI_DATA_15 AVR32_EBI_DATA_15
#define ET024006DHU_EBI_ADDR_21 AVR32_EBI_ADDR_21_1
#define ET024006DHU_EBI_NWE AVR32_EBI_NWE0_0
#define ET024006DHU_EBI_NRD AVR32_EBI_NRD_0
#define ET024006DHU_EBI_NCS AVR32_EBI_NCS_0_1
//! @}
#endif // !EVK1105_REVA
#endif // _EVK1105_H_

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@ -0,0 +1,346 @@
/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT32UC3A EVK1105 board LEDs support package.
*
* This file contains definitions and services related to the LED features of
* the EVK1105 board.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 AT32UC3A devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <avr32/io.h>
#include "preprocessor.h"
#include "compiler.h"
#include "evk1105.h"
#include "led.h"
//! Structure describing LED hardware connections.
typedef const struct
{
struct
{
U32 PORT; //!< LED GPIO port.
U32 PIN_MASK; //!< Bit-mask of LED pin in GPIO port.
} GPIO; //!< LED GPIO descriptor.
struct
{
S32 CHANNEL; //!< LED PWM channel (< 0 if N/A).
S32 FUNCTION; //!< LED pin PWM function (< 0 if N/A).
} PWM; //!< LED PWM descriptor.
} tLED_DESCRIPTOR;
//! Hardware descriptors of all LEDs.
static tLED_DESCRIPTOR LED_DESCRIPTOR[LED_COUNT] =
{
#define INSERT_LED_DESCRIPTOR(LED_NO, unused) \
{ \
{LED##LED_NO##_GPIO / 32, 1 << (LED##LED_NO##_GPIO % 32)},\
{LED##LED_NO##_PWM, LED##LED_NO##_PWM_FUNCTION } \
},
MREPEAT(LED_COUNT, INSERT_LED_DESCRIPTOR, ~)
#undef INSERT_LED_DESCRIPTOR
};
//! Saved state of all LEDs.
static volatile U32 LED_State = (1 << LED_COUNT) - 1;
U32 LED_Read_Display(void)
{
return LED_State;
}
void LED_Display(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor;
volatile avr32_gpio_port_t *led_gpio_port;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
LED_State = leds;
// For all LEDs...
for (led_descriptor = &LED_DESCRIPTOR[0];
led_descriptor < LED_DESCRIPTOR + LED_COUNT;
led_descriptor++)
{
// Set the LED to the requested state.
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
if (leds & 1)
{
led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;
}
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= 1;
}
}
U32 LED_Read_Display_Mask(U32 mask)
{
return Rd_bits(LED_State, mask);
}
void LED_Display_Mask(U32 mask, U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
mask &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Wr_bits(LED_State, mask, leds);
// While there are specified LEDs left to manage...
while (mask)
{
// Select the next specified LED and set it to the requested state.
led_shift = 1 + ctz(mask);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
leds >>= led_shift - 1;
if (leds & 1)
{
led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;
}
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= 1;
mask >>= led_shift;
}
}
Bool LED_Test(U32 leds)
{
return Tst_bits(LED_State, leds);
}
void LED_Off(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Clr_bits(LED_State, leds);
// While there are specified LEDs left to manage...
while (leds)
{
// Select the next specified LED and turn it off.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= led_shift;
}
}
void LED_On(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Set_bits(LED_State, leds);
// While there are specified LEDs left to manage...
while (leds)
{
// Select the next specified LED and turn it on.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= led_shift;
}
}
void LED_Toggle(U32 leds)
{
// Use the LED descriptors to get the connections of a given LED to the MCU.
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// Make sure only existing LEDs are specified.
leds &= (1 << LED_COUNT) - 1;
// Update the saved state of all LEDs with the requested changes.
Tgl_bits(LED_State, leds);
// While there are specified LEDs left to manage...
while (leds)
{
// Select the next specified LED and toggle it.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
led_gpio_port->ovrt = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
leds >>= led_shift;
}
}
U32 LED_Read_Display_Field(U32 field)
{
return Rd_bitfield(LED_State, field);
}
void LED_Display_Field(U32 field, U32 leds)
{
// Move the bit-field to the appropriate position for the bit-mask.
LED_Display_Mask(field, leds << ctz(field));
}
U8 LED_Get_Intensity(U32 led)
{
tLED_DESCRIPTOR *led_descriptor;
// Check that the argument value is valid.
led = ctz(led);
led_descriptor = &LED_DESCRIPTOR[led];
if (led >= LED_COUNT || led_descriptor->PWM.CHANNEL < 0) return 0;
// Return the duty cycle value if the LED PWM channel is enabled, else 0.
return (AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)) ?
AVR32_PWM.channel[led_descriptor->PWM.CHANNEL].cdty : 0;
}
void LED_Set_Intensity(U32 leds, U8 intensity)
{
tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
volatile avr32_pwm_channel_t *led_pwm_channel;
volatile avr32_gpio_port_t *led_gpio_port;
U8 led_shift;
// For each specified LED...
for (leds &= (1 << LED_COUNT) - 1; leds; leds >>= led_shift)
{
// Select the next specified LED and check that it has a PWM channel.
led_shift = 1 + ctz(leds);
led_descriptor += led_shift;
if (led_descriptor->PWM.CHANNEL < 0) continue;
// Initialize or update the LED PWM channel.
led_pwm_channel = &AVR32_PWM.channel[led_descriptor->PWM.CHANNEL];
if (!(AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)))
{
led_pwm_channel->cmr = (AVR32_PWM_CPRE_MCK << AVR32_PWM_CPRE_OFFSET) &
~(AVR32_PWM_CALG_MASK |
AVR32_PWM_CPOL_MASK |
AVR32_PWM_CPD_MASK);
led_pwm_channel->cprd = 0x000000FF;
led_pwm_channel->cdty = intensity;
AVR32_PWM.ena = 1 << led_descriptor->PWM.CHANNEL;
}
else
{
AVR32_PWM.isr;
while (!(AVR32_PWM.isr & (1 << led_descriptor->PWM.CHANNEL)));
led_pwm_channel->cupd = intensity;
}
// Switch the LED pin to its PWM function.
led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
if (led_descriptor->PWM.FUNCTION & 0x1)
{
led_gpio_port->pmr0s = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->pmr0c = led_descriptor->GPIO.PIN_MASK;
}
if (led_descriptor->PWM.FUNCTION & 0x2)
{
led_gpio_port->pmr1s = led_descriptor->GPIO.PIN_MASK;
}
else
{
led_gpio_port->pmr1c = led_descriptor->GPIO.PIN_MASK;
}
led_gpio_port->gperc = led_descriptor->GPIO.PIN_MASK;
}
}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief AT32UC3A EVK1105 board LEDs support package.
*
* This file contains definitions and services related to the LED features of
* the EVK1105 board.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 AT32UC3A devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _LED_H_
#define _LED_H_
#include "compiler.h"
/*! \name Identifiers of LEDs to Use with LED Functions
*/
//! @{
#define LED0 0x01
#define LED1 0x02
#define LED2 0x04
#define LED3 0x08
//! @}
/*! \brief Gets the last state of all LEDs set through the LED API.
*
* \return State of all LEDs (1 bit per LED).
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U32 LED_Read_Display(void);
/*! \brief Sets the state of all LEDs.
*
* \param leds New state of all LEDs (1 bit per LED).
*
* \note The pins of all LEDs are set to GPIO output mode.
*/
extern void LED_Display(U32 leds);
/*! \brief Gets the last state of the specified LEDs set through the LED API.
*
* \param mask LEDs of which to get the state (1 bit per LED).
*
* \return State of the specified LEDs (1 bit per LED).
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U32 LED_Read_Display_Mask(U32 mask);
/*! \brief Sets the state of the specified LEDs.
*
* \param mask LEDs of which to set the state (1 bit per LED).
*
* \param leds New state of the specified LEDs (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Display_Mask(U32 mask, U32 leds);
/*! \brief Tests the last state of the specified LEDs set through the LED API.
*
* \param leds LEDs of which to test the state (1 bit per LED).
*
* \return \c TRUE if at least one of the specified LEDs has a state on, else
* \c FALSE.
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern Bool LED_Test(U32 leds);
/*! \brief Turns off the specified LEDs.
*
* \param leds LEDs to turn off (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Off(U32 leds);
/*! \brief Turns on the specified LEDs.
*
* \param leds LEDs to turn on (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_On(U32 leds);
/*! \brief Toggles the specified LEDs.
*
* \param leds LEDs to toggle (1 bit per LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Toggle(U32 leds);
/*! \brief Gets as a bit-field the last state of the specified LEDs set through
* the LED API.
*
* \param field LEDs of which to get the state (1 bit per LED).
*
* \return State of the specified LEDs (1 bit per LED, beginning with the first
* specified LED).
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U32 LED_Read_Display_Field(U32 field);
/*! \brief Sets as a bit-field the state of the specified LEDs.
*
* \param field LEDs of which to set the state (1 bit per LED).
* \param leds New state of the specified LEDs (1 bit per LED, beginning with
* the first specified LED).
*
* \note The pins of the specified LEDs are set to GPIO output mode.
*/
extern void LED_Display_Field(U32 field, U32 leds);
/*! \brief Gets the intensity of the specified LED.
*
* \param led LED of which to get the intensity (1 bit per LED; only the least
* significant set bit is used).
*
* \return Intensity of the specified LED (0x00 to 0xFF).
*
* \warning The PWM channel of the specified LED is supposed to be used only by
* this module.
*
* \note The GPIO pin configuration of all LEDs is left unchanged.
*/
extern U8 LED_Get_Intensity(U32 led);
/*! \brief Sets the intensity of the specified LEDs.
*
* \param leds LEDs of which to set the intensity (1 bit per LED).
* \param intensity New intensity of the specified LEDs (0x00 to 0xFF).
*
* \warning The PWM channels of the specified LEDs are supposed to be used only
* by this module.
*
* \note The pins of the specified LEDs are set to PWM output mode.
*/
extern void LED_Set_Intensity(U32 leds, U8 intensity);
#endif // _LED_H_

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Standard board header file.
*
* This file includes the appropriate board header file according to the
* defined board.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _BOARD_H_
#define _BOARD_H_
#include <avr32/io.h>
/*! \name Base Boards
*/
//! @{
#define EVK1100 1 //!< AT32UC3A EVK1100 board.
#define EVK1101 2 //!< AT32UC3B EVK1101 board.
#define UC3C_EK 3 //!< AT32UC3C UC3C_EK board.
#define EVK1104 4 //!< AT32UC3A3 EVK1104 board.
#define EVK1105 5 //!< AT32UC3A EVK1105 board.
#define STK1000 6 //!< AT32AP7000 STK1000 board.
#define NGW100 7 //!< AT32AP7000 NGW100 board.
#define STK600_RCUC3L0 8 //!< STK600 RCUC3L0 board.
#define UC3L_EK 9 //!< AT32UC3L-EK board.
#define USER_BOARD 99 //!< User-reserved board (if any).
//! @}
/*! \name Extension Boards
*/
//! @{
#define EXT1102 1 //!< AT32UC3B EXT1102 board.
#define MC300 2 //!< AT32UC3 MC300 board.
#define USER_EXT_BOARD 99 //!< User-reserved extension board (if any).
//! @}
#if BOARD == EVK1100
#include "EVK1100/evk1100.h"
#elif BOARD == EVK1101
#include "EVK1101/evk1101.h"
#elif BOARD == UC3C_EK
#include "UC3C_EK/uc3c_ek.h"
#elif BOARD == EVK1104
#include "EVK1104/evk1104.h"
#elif BOARD == EVK1105
#include "EVK1105/evk1105.h"
#elif BOARD == STK1000
#include "STK1000/stk1000.h"
#elif BOARD == NGW100
#include "NGW100/ngw100.h"
#elif BOARD == STK600_RCUC3L0
#include "STK600/RCUC3L0/stk600_rcuc3l0.h"
#elif BOARD == UC3L_EK
#include "UC3L_EK/uc3l_ek.h"
#elif BOARD == ARDUINO
#include "ARDUINO/arduino.h"
#else
#error No known AVR32 board defined
#endif
#if (defined EXT_BOARD)
#if EXT_BOARD == EXT1102
#include "EXT1102/ext1102.h"
#elif EXT_BOARD == MC300
#include "MC300/mc300.h"
#elif EXT_BOARD == USER_EXT_BOARD
// User-reserved area: #include the header file of your extension board here
// (if any).
#endif
#endif
#ifndef FRCOSC
#define FRCOSC AVR32_PM_RCOSC_FREQUENCY //!< Default RCOsc frequency.
#endif
#endif // _BOARD_H_

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Standard board header file.
*
* This file includes the appropriate board header file according to the
* defined board.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _BOARD_H_
#define _BOARD_H_
#include <avr32/io.h>
/*! \name Base Boards
*/
//! @{
#define EVK1100 1 //!< AT32UC3A EVK1100 board.
#define EVK1101 2 //!< AT32UC3B EVK1101 board.
#define UC3C_EK 3 //!< AT32UC3C UC3C_EK board.
#define EVK1104 4 //!< AT32UC3A3 EVK1104 board.
#define EVK1105 5 //!< AT32UC3A EVK1105 board.
#define STK1000 6 //!< AT32AP7000 STK1000 board.
#define NGW100 7 //!< AT32AP7000 NGW100 board.
#define STK600_RCUC3L0 8 //!< STK600 RCUC3L0 board.
#define UC3L_EK 9 //!< AT32UC3L-EK board.
#define USER_BOARD 99 //!< User-reserved board (if any).
//! @}
/*! \name Extension Boards
*/
//! @{
#define EXT1102 1 //!< AT32UC3B EXT1102 board.
#define MC300 2 //!< AT32UC3 MC300 board.
#define USER_EXT_BOARD 99 //!< User-reserved extension board (if any).
//! @}
#if BOARD == EVK1100
#include "EVK1100/evk1100.h"
#elif BOARD == EVK1101
#include "EVK1101/evk1101.h"
#elif BOARD == UC3C_EK
#include "UC3C_EK/uc3c_ek.h"
#elif BOARD == EVK1104
#include "EVK1104/evk1104.h"
#elif BOARD == EVK1105
#include "EVK1105/evk1105.h"
#elif BOARD == STK1000
#include "STK1000/stk1000.h"
#elif BOARD == NGW100
#include "NGW100/ngw100.h"
#elif BOARD == STK600_RCUC3L0
#include "STK600/RCUC3L0/stk600_rcuc3l0.h"
#elif BOARD == UC3L_EK
#include "UC3L_EK/uc3l_ek.h"
#elif BOARD == ARDUINO
#include "ARDUINO/arduino.h"
#else
#error No known AVR32 board defined
#endif
#if (defined EXT_BOARD)
#if EXT_BOARD == EXT1102
#include "EXT1102/ext1102.h"
#elif EXT_BOARD == MC300
#include "MC300/mc300.h"
#elif EXT_BOARD == USER_EXT_BOARD
// User-reserved area: #include the header file of your extension board here
// (if any).
#endif
#endif
#ifndef FRCOSC
#define FRCOSC AVR32_PM_RCOSC_FREQUENCY //!< Default RCOsc frequency.
#endif
#endif // _BOARD_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Management of the AT45DBX data flash controller through SPI.
*
* This file manages the accesses to the AT45DBX data flash components.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
//_____ I N C L U D E S ___________________________________________________
#include "conf_access.h"
#if AT45DBX_MEM == ENABLE
#include "compiler.h"
#include "board.h"
#include "gpio.h"
#include "spi.h"
#include "conf_at45dbx.h"
#include "at45dbx.h"
#if AT45DBX_MEM_CNT > 4
#error AT45DBX_MEM_CNT must not exceed 4
#endif
//_____ D E F I N I T I O N S ______________________________________________
/*! \name AT45DBX Group A Commands
*/
//! @{
#define AT45DBX_CMDA_RD_PAGE 0xD2 //!< Main Memory Page Read (Serial/8-bit Mode).
#define AT45DBX_CMDA_RD_ARRAY_LEG 0xE8 //!< Continuous Array Read, Legacy Command (Serial/8-bit Mode).
#define AT45DBX_CMDA_RD_ARRAY_LF_SM 0x03 //!< Continuous Array Read, Low-Frequency Mode (Serial Mode).
#define AT45DBX_CMDA_RD_ARRAY_AF_SM 0x0B //!< Continuous Array Read, Any-Frequency Mode (Serial Mode).
#define AT45DBX_CMDA_RD_SECTOR_PROT_REG 0x32 //!< Read Sector Protection Register (Serial/8-bit Mode).
#define AT45DBX_CMDA_RD_SECTOR_LKDN_REG 0x35 //!< Read Sector Lockdown Register (Serial/8-bit Mode).
#define AT45DBX_CMDA_RD_SECURITY_REG 0x77 //!< Read Security Register (Serial/8-bit Mode).
//! @}
/*! \name AT45DBX Group B Commands
*/
//! @{
#define AT45DBX_CMDB_ER_PAGE 0x81 //!< Page Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_ER_BLOCK 0x50 //!< Block Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_ER_SECTOR 0x7C //!< Sector Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_ER_CHIP 0xC794809A //!< Chip Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_XFR_PAGE_TO_BUF1 0x53 //!< Main Memory Page to Buffer 1 Transfer (Serial/8-bit Mode).
#define AT45DBX_CMDB_XFR_PAGE_TO_BUF2 0x55 //!< Main Memory Page to Buffer 2 Transfer (Serial/8-bit Mode).
#define AT45DBX_CMDB_CMP_PAGE_TO_BUF1 0x60 //!< Main Memory Page to Buffer 1 Compare (Serial/8-bit Mode).
#define AT45DBX_CMDB_CMP_PAGE_TO_BUF2 0x61 //!< Main Memory Page to Buffer 2 Compare (Serial/8-bit Mode).
#define AT45DBX_CMDB_PR_BUF1_TO_PAGE_ER 0x83 //!< Buffer 1 to Main Memory Page Program with Built-in Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_PR_BUF2_TO_PAGE_ER 0x86 //!< Buffer 2 to Main Memory Page Program with Built-in Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_PR_BUF1_TO_PAGE 0x88 //!< Buffer 1 to Main Memory Page Program without Built-in Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_PR_BUF2_TO_PAGE 0x89 //!< Buffer 2 to Main Memory Page Program without Built-in Erase (Serial/8-bit Mode).
#define AT45DBX_CMDB_PR_PAGE_TH_BUF1 0x82 //!< Main Memory Page Program through Buffer 1 (Serial/8-bit Mode).
#define AT45DBX_CMDB_PR_PAGE_TH_BUF2 0x85 //!< Main Memory Page Program through Buffer 2 (Serial/8-bit Mode).
#define AT45DBX_CMDB_RWR_PAGE_TH_BUF1 0x58 //!< Auto Page Rewrite through Buffer 1 (Serial/8-bit Mode).
#define AT45DBX_CMDB_RWR_PAGE_TH_BUF2 0x59 //!< Auto Page Rewrite through Buffer 2 (Serial/8-bit Mode).
//! @}
/*! \name AT45DBX Group C Commands
*/
//! @{
#define AT45DBX_CMDC_RD_BUF1_LF_SM 0xD1 //!< Buffer 1 Read, Low-Frequency Mode (Serial Mode).
#define AT45DBX_CMDC_RD_BUF2_LF_SM 0xD3 //!< Buffer 2 Read, Low-Frequency Mode (Serial Mode).
#define AT45DBX_CMDC_RD_BUF1_AF_SM 0xD4 //!< Buffer 1 Read, Any-Frequency Mode (Serial Mode).
#define AT45DBX_CMDC_RD_BUF2_AF_SM 0xD6 //!< Buffer 2 Read, Any-Frequency Mode (Serial Mode).
#define AT45DBX_CMDC_RD_BUF1_AF_8M 0x54 //!< Buffer 1 Read, Any-Frequency Mode (8-bit Mode).
#define AT45DBX_CMDC_RD_BUF2_AF_8M 0x56 //!< Buffer 2 Read, Any-Frequency Mode (8-bit Mode).
#define AT45DBX_CMDC_WR_BUF1 0x84 //!< Buffer 1 Write (Serial/8-bit Mode).
#define AT45DBX_CMDC_WR_BUF2 0x87 //!< Buffer 2 Write (Serial/8-bit Mode).
#define AT45DBX_CMDC_RD_STATUS_REG 0xD7 //!< Status Register Read (Serial/8-bit Mode).
#define AT45DBX_CMDC_RD_MNFCT_DEV_ID_SM 0x9F //!< Manufacturer and Device ID Read (Serial Mode).
//! @}
/*! \name AT45DBX Group D Commands
*/
//! @{
#define AT45DBX_CMDD_EN_SECTOR_PROT 0x3D2A7FA9 //!< Enable Sector Protection (Serial/8-bit Mode).
#define AT45DBX_CMDD_DIS_SECTOR_PROT 0x3D2A7F9A //!< Disable Sector Protection (Serial/8-bit Mode).
#define AT45DBX_CMDD_ER_SECTOR_PROT_REG 0x3D2A7FCF //!< Erase Sector Protection Register (Serial/8-bit Mode).
#define AT45DBX_CMDD_PR_SECTOR_PROT_REG 0x3D2A7FFC //!< Program Sector Protection Register (Serial/8-bit Mode).
#define AT45DBX_CMDD_LKDN_SECTOR 0x3D2A7F30 //!< Sector Lockdown (Serial/8-bit Mode).
#define AT45DBX_CMDD_PR_SECURITY_REG 0x9B000000 //!< Program Security Register (Serial/8-bit Mode).
#define AT45DBX_CMDD_PR_CONF_REG 0x3D2A80A6 //!< Program Configuration Register (Serial/8-bit Mode).
#define AT45DBX_CMDD_DEEP_PWR_DN 0xB9 //!< Deep Power-down (Serial/8-bit Mode).
#define AT45DBX_CMDD_RSM_DEEP_PWR_DN 0xAB //!< Resume from Deep Power-down (Serial/8-bit Mode).
//! @}
/*! \name Bit-Masks and Values for the Status Register
*/
//! @{
#define AT45DBX_MSK_BUSY 0x80 //!< Busy status bit-mask.
#define AT45DBX_BUSY 0x00 //!< Busy status value (0x00 when busy, 0x80 when ready).
#define AT45DBX_MSK_DENSITY 0x3C //!< Device density bit-mask.
//! @}
#if AT45DBX_MEM_SIZE == AT45DBX_1MB
/*! \name AT45DB081 Memories
*/
//! @{
#define AT45DBX_DENSITY 0x24 //!< Device density value.
#define AT45DBX_BYTE_ADDR_BITS 9 //!< Address bits for byte position within buffer.
//! @}
#elif AT45DBX_MEM_SIZE == AT45DBX_2MB
/*! \name AT45DB161 Memories
*/
//! @{
#define AT45DBX_DENSITY 0x2C //!< Device density value.
#define AT45DBX_BYTE_ADDR_BITS 10 //!< Address bits for byte position within buffer.
//! @}
#elif AT45DBX_MEM_SIZE == AT45DBX_4MB
/*! \name AT45DB321 Memories
*/
//! @{
#define AT45DBX_DENSITY 0x34 //!< Device density value.
#define AT45DBX_BYTE_ADDR_BITS 10 //!< Address bits for byte position within buffer.
//! @}
#elif AT45DBX_MEM_SIZE == AT45DBX_8MB
/*! \name AT45DB642 Memories
*/
//! @{
#define AT45DBX_DENSITY 0x3C //!< Device density value.
#define AT45DBX_BYTE_ADDR_BITS 11 //!< Address bits for byte position within buffer.
//! @}
#else
#error AT45DBX_MEM_SIZE is not defined to a supported value
#endif
//! Address bits for page selection.
#define AT45DBX_PAGE_ADDR_BITS (AT45DBX_MEM_SIZE - AT45DBX_PAGE_BITS)
//! Number of bits for addresses within pages.
#define AT45DBX_PAGE_BITS (AT45DBX_BYTE_ADDR_BITS - 1)
//! Page size in bytes.
#define AT45DBX_PAGE_SIZE (1 << AT45DBX_PAGE_BITS)
//! Bit-mask for byte position within buffer in \ref gl_ptr_mem.
#define AT45DBX_MSK_PTR_BYTE ((1 << AT45DBX_PAGE_BITS) - 1)
//! Bit-mask for page selection in \ref gl_ptr_mem.
#define AT45DBX_MSK_PTR_PAGE (((1 << AT45DBX_PAGE_ADDR_BITS) - 1) << AT45DBX_PAGE_BITS)
//! Bit-mask for byte position within sector in \ref gl_ptr_mem.
#define AT45DBX_MSK_PTR_SECTOR ((1 << AT45DBX_SECTOR_BITS) - 1)
/*! \brief Sends a dummy byte through SPI.
*/
#define spi_write_dummy() spi_write(AT45DBX_SPI, 0xFF)
//! Boolean indicating whether memory is in busy state.
static Bool at45dbx_busy;
//! Memory data pointer.
static U32 gl_ptr_mem;
//! Sector buffer.
static U8 sector_buf[AT45DBX_SECTOR_SIZE];
/*! \name Control Functions
*/
//! @{
Bool at45dbx_init(spi_options_t spiOptions, unsigned int pba_hz)
{
// Setup SPI registers according to spiOptions.
for (spiOptions.reg = AT45DBX_SPI_FIRST_NPCS;
spiOptions.reg < AT45DBX_SPI_FIRST_NPCS + AT45DBX_MEM_CNT;
spiOptions.reg++)
{
if (spi_setupChipReg(AT45DBX_SPI, &spiOptions, pba_hz) != SPI_OK) return KO;
}
// Memory ready.
at45dbx_busy = FALSE;
return OK;
}
/*! \brief Selects or unselects a DF memory.
*
* \param memidx Memory ID of DF to select or unselect.
* \param bSelect Boolean indicating whether the DF memory has to be selected.
*/
static void at45dbx_chipselect_df(U8 memidx, Bool bSelect)
{
if (bSelect)
{
// Select SPI chip.
spi_selectChip(AT45DBX_SPI, AT45DBX_SPI_FIRST_NPCS + memidx);
}
else
{
// Unselect SPI chip.
spi_unselectChip(AT45DBX_SPI, AT45DBX_SPI_FIRST_NPCS + memidx);
}
}
Bool at45dbx_mem_check(void)
{
U8 df;
U16 status = 0;
// DF memory check.
for (df = 0; df < AT45DBX_MEM_CNT; df++)
{
// Select the DF memory to check.
at45dbx_chipselect_df(df, TRUE);
// Send the Status Register Read command.
spi_write(AT45DBX_SPI, AT45DBX_CMDC_RD_STATUS_REG);
// Send a dummy byte to read the status register.
spi_write_dummy();
spi_read(AT45DBX_SPI, &status);
// Unselect the checked DF memory.
at45dbx_chipselect_df(df, FALSE);
// Unexpected device density value.
if ((status & AT45DBX_MSK_DENSITY) < AT45DBX_DENSITY) return KO;
}
return OK;
}
/*! \brief Waits until the DF is ready.
*/
static void at45dbx_wait_ready(void)
{
U16 status;
// Select the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, TRUE);
// Send the Status Register Read command.
spi_write(AT45DBX_SPI, AT45DBX_CMDC_RD_STATUS_REG);
// Read the status register until the DF is ready.
do
{
// Send a dummy byte to read the status register.
spi_write_dummy();
spi_read(AT45DBX_SPI, &status);
} while ((status & AT45DBX_MSK_BUSY) == AT45DBX_BUSY);
// Unselect the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
}
Bool at45dbx_read_open(U32 sector)
{
U32 addr;
// Set the global memory pointer to a byte address.
gl_ptr_mem = sector << AT45DBX_SECTOR_BITS; // gl_ptr_mem = sector * AT45DBX_SECTOR_SIZE.
// If the DF memory is busy, wait until it's ready.
if (at45dbx_busy) at45dbx_wait_ready();
at45dbx_busy = FALSE;
// Select the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, TRUE);
// Initiate a page read at a given sector.
// Send the Main Memory Page Read command.
spi_write(AT45DBX_SPI, AT45DBX_CMDA_RD_PAGE);
// Send the three address bytes, which comprise:
// - (24 - (AT45DBX_PAGE_ADDR_BITS + AT45DBX_BYTE_ADDR_BITS)) reserved bits;
// - then AT45DBX_PAGE_ADDR_BITS bits specifying the page in main memory to be read;
// - then AT45DBX_BYTE_ADDR_BITS bits specifying the starting byte address within that page.
// NOTE: The bits of gl_ptr_mem above the AT45DBX_MEM_SIZE bits are useless for the local
// DF addressing. They are used for DF discrimination when there are several DFs.
addr = (Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_PAGE) << AT45DBX_BYTE_ADDR_BITS) |
Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_BYTE);
spi_write(AT45DBX_SPI, LSB2W(addr));
spi_write(AT45DBX_SPI, LSB1W(addr));
spi_write(AT45DBX_SPI, LSB0W(addr));
// Send 32 don't care clock cycles to initialize the read operation.
spi_write_dummy();
spi_write_dummy();
spi_write_dummy();
spi_write_dummy();
return OK;
}
void at45dbx_read_close(void)
{
// Unselect the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Memory ready.
at45dbx_busy = FALSE;
}
Bool at45dbx_write_open(U32 sector)
{
U32 addr;
// Set the global memory pointer to a byte address.
gl_ptr_mem = sector << AT45DBX_SECTOR_BITS; // gl_ptr_mem = sector * AT45DBX_SECTOR_SIZE.
// If the DF memory is busy, wait until it's ready.
if (at45dbx_busy) at45dbx_wait_ready();
at45dbx_busy = FALSE;
#if AT45DBX_PAGE_SIZE > AT45DBX_SECTOR_SIZE
// Select the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, TRUE);
// Transfer the content of the current page to buffer 1.
// Send the Main Memory Page to Buffer 1 Transfer command.
spi_write(AT45DBX_SPI, AT45DBX_CMDB_XFR_PAGE_TO_BUF1);
// Send the three address bytes, which comprise:
// - (24 - (AT45DBX_PAGE_ADDR_BITS + AT45DBX_BYTE_ADDR_BITS)) reserved bits;
// - then AT45DBX_PAGE_ADDR_BITS bits specifying the page in main memory to be read;
// - then AT45DBX_BYTE_ADDR_BITS don't care bits.
// NOTE: The bits of gl_ptr_mem above the AT45DBX_MEM_SIZE bits are useless for the local
// DF addressing. They are used for DF discrimination when there are several DFs.
addr = Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_PAGE) << AT45DBX_BYTE_ADDR_BITS;
spi_write(AT45DBX_SPI, LSB2W(addr));
spi_write(AT45DBX_SPI, LSB1W(addr));
spi_write(AT45DBX_SPI, LSB0W(addr));
// Unselect the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Wait for end of page transfer.
at45dbx_wait_ready();
#endif
// Select the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, TRUE);
// Initiate a page write at a given sector.
// Send the Main Memory Page Program through Buffer 1 command.
spi_write(AT45DBX_SPI, AT45DBX_CMDB_PR_PAGE_TH_BUF1);
// Send the three address bytes, which comprise:
// - (24 - (AT45DBX_PAGE_ADDR_BITS + AT45DBX_BYTE_ADDR_BITS)) reserved bits;
// - then AT45DBX_PAGE_ADDR_BITS bits specifying the page in main memory to be written;
// - then AT45DBX_BYTE_ADDR_BITS bits specifying the starting byte address within that page.
// NOTE: The bits of gl_ptr_mem above the AT45DBX_MEM_SIZE bits are useless for the local
// DF addressing. They are used for DF discrimination when there are several DFs.
addr = (Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_PAGE) << AT45DBX_BYTE_ADDR_BITS) |
Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_BYTE);
spi_write(AT45DBX_SPI, LSB2W(addr));
spi_write(AT45DBX_SPI, LSB1W(addr));
spi_write(AT45DBX_SPI, LSB0W(addr));
return OK;
}
void at45dbx_write_close(void)
{
// While end of logical sector not reached, zero-fill remaining memory bytes.
while (Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_SECTOR))
{
spi_write(AT45DBX_SPI, 0x00);
gl_ptr_mem++;
}
// Unselect the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Memory busy.
at45dbx_busy = TRUE;
}
//! @}
/*! \name Single-Byte Access Functions
*/
//! @{
U8 at45dbx_read_byte(void)
{
U16 data;
// Memory busy.
if (at45dbx_busy)
{
// Being here, we know that we previously finished a page read.
// => We have to access the next page.
// Memory ready.
at45dbx_busy = FALSE;
// Eventually select the next DF and open the next page.
// NOTE: at45dbx_read_open input parameter is a sector.
at45dbx_read_open(gl_ptr_mem >> AT45DBX_SECTOR_BITS); // gl_ptr_mem / AT45DBX_SECTOR_SIZE.
}
// Send a dummy byte to read the next data byte.
spi_write_dummy();
spi_read(AT45DBX_SPI, &data);
gl_ptr_mem++;
// If end of page reached,
if (!Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_BYTE))
{
// unselect the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Memory busy.
at45dbx_busy = TRUE;
}
return data;
}
Bool at45dbx_write_byte(U8 b)
{
// Memory busy.
if (at45dbx_busy)
{
// Being here, we know that we previously launched a page programming.
// => We have to access the next page.
// Eventually select the next DF and open the next page.
// NOTE: at45dbx_write_open input parameter is a sector.
at45dbx_write_open(gl_ptr_mem >> AT45DBX_SECTOR_BITS); // gl_ptr_mem / AT45DBX_SECTOR_SIZE.
}
// Write the next data byte.
spi_write(AT45DBX_SPI, b);
gl_ptr_mem++;
// If end of page reached,
if (!Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_BYTE))
{
// unselect the DF memory gl_ptr_mem points to in order to program the page.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Memory busy.
at45dbx_busy = TRUE;
}
return OK;
}
//! @}
/*! \name Multiple-Sector Access Functions
*/
//! @{
Bool at45dbx_read_multiple_sector(U16 nb_sector)
{
while (nb_sector--)
{
// Read the next sector.
at45dbx_read_sector_2_ram(sector_buf);
at45dbx_read_multiple_sector_callback(sector_buf);
}
return OK;
}
Bool at45dbx_write_multiple_sector(U16 nb_sector)
{
while (nb_sector--)
{
// Write the next sector.
at45dbx_write_multiple_sector_callback(sector_buf);
at45dbx_write_sector_from_ram(sector_buf);
}
return OK;
}
//! @}
/*! \name Single-Sector Access Functions
*/
//! @{
Bool at45dbx_read_sector_2_ram(void *ram)
{
U8 *_ram = ram;
U16 i;
U16 data;
// Memory busy.
if (at45dbx_busy)
{
// Being here, we know that we previously finished a page read.
// => We have to access the next page.
// Memory ready.
at45dbx_busy = FALSE;
// Eventually select the next DF and open the next page.
// NOTE: at45dbx_read_open input parameter is a sector.
at45dbx_read_open(gl_ptr_mem >> AT45DBX_SECTOR_BITS); // gl_ptr_mem / AT45DBX_SECTOR_SIZE.
}
// Read the next sector.
for (i = AT45DBX_SECTOR_SIZE; i; i--)
{
// Send a dummy byte to read the next data byte.
spi_write_dummy();
spi_read(AT45DBX_SPI, &data);
*_ram++ = data;
}
// Update the memory pointer.
gl_ptr_mem += AT45DBX_SECTOR_SIZE;
#if AT45DBX_PAGE_SIZE > AT45DBX_SECTOR_SIZE
// If end of page reached,
if (!Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_BYTE))
#endif
{
// unselect the DF memory gl_ptr_mem points to.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Memory busy.
at45dbx_busy = TRUE;
}
return OK;
}
Bool at45dbx_write_sector_from_ram(const void *ram)
{
const U8 *_ram = ram;
U16 i;
// Memory busy.
if (at45dbx_busy)
{
// Being here, we know that we previously launched a page programming.
// => We have to access the next page.
// Eventually select the next DF and open the next page.
// NOTE: at45dbx_write_open input parameter is a sector.
at45dbx_write_open(gl_ptr_mem >> AT45DBX_SECTOR_BITS); // gl_ptr_mem / AT45DBX_SECTOR_SIZE.
}
// Write the next sector.
for (i = AT45DBX_SECTOR_SIZE; i; i--)
{
// Write the next data byte.
spi_write(AT45DBX_SPI, *_ram++);
}
// Update the memory pointer.
gl_ptr_mem += AT45DBX_SECTOR_SIZE;
#if AT45DBX_PAGE_SIZE > AT45DBX_SECTOR_SIZE
// If end of page reached,
if (!Rd_bitfield(gl_ptr_mem, AT45DBX_MSK_PTR_BYTE))
#endif
{
// unselect the DF memory gl_ptr_mem points to in order to program the page.
at45dbx_chipselect_df(gl_ptr_mem >> AT45DBX_MEM_SIZE, FALSE);
// Memory busy.
at45dbx_busy = TRUE;
}
return OK;
}
//! @}
#endif // AT45DBX_MEM == ENABLE

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Management of the AT45DBX data flash controller through SPI.
*
* This file manages the accesses to the AT45DBX data flash components.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _AT45DBX_H_
#define _AT45DBX_H_
#include "conf_access.h"
#if AT45DBX_MEM == DISABLE
#error at45dbx.h is #included although AT45DBX_MEM is disabled
#endif
#include "spi.h"
//_____ D E F I N I T I O N S ______________________________________________
/*! \name Available AT45DBX Sizes
*
* Number of address bits of available AT45DBX data flash memories.
*
* \note Only memories with page sizes of at least 512 bytes (sector size) are
* supported.
*/
//! @{
#define AT45DBX_1MB 20
#define AT45DBX_2MB 21
#define AT45DBX_4MB 22
#define AT45DBX_8MB 23
//! @}
// AT45DBX_1MB
#define AT45DBX_SECTOR_BITS 8 //! Number of bits for addresses within sectors.
// AT45DBX_2MB AT45DBX_4MB AT45DBX_8MB
//#define AT45DBX_SECTOR_BITS 9 //! Number of bits for addresses within sectors.
//! Sector size in bytes.
#define AT45DBX_SECTOR_SIZE (1 << AT45DBX_SECTOR_BITS)
//_____ D E C L A R A T I O N S ____________________________________________
/*! \name Control Functions
*/
//! @{
/*! \brief Initializes the data flash controller and the SPI channel by which
* the DF is controlled.
*
* \param spiOptions Initialization options of the DF SPI channel.
* \param pba_hz SPI module input clock frequency (PBA clock, Hz).
*
* \retval OK Success.
* \retval KO Failure.
*/
extern Bool at45dbx_init(spi_options_t spiOptions, unsigned int pba_hz);
/*! \brief Performs a memory check on all DFs.
*
* \retval OK Success.
* \retval KO Failure.
*/
extern Bool at45dbx_mem_check(void);
/*! \brief Opens a DF memory in read mode at a given sector.
*
* \param sector Start sector.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note Sector may be page-unaligned (depending on the DF page size).
*/
extern Bool at45dbx_read_open(U32 sector);
/*! \brief Unselects the current DF memory.
*/
extern void at45dbx_read_close(void);
/*! \brief This function opens a DF memory in write mode at a given sector.
*
* \param sector Start sector.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note Sector may be page-unaligned (depending on the DF page size).
*
* \note If \ref AT45DBX_PAGE_SIZE > \ref AT45DBX_SECTOR_SIZE, page content is
* first loaded in buffer to then be partially updated by write byte or
* write sector functions.
*/
extern Bool at45dbx_write_open(U32 sector);
/*! \brief Fills the end of the current logical sector and launches page programming.
*/
extern void at45dbx_write_close(void);
//! @}
/*! \name Single-Byte Access Functions
*/
//! @{
/*! \brief Performs a single byte read from DF memory.
*
* \return The read byte.
*
* \note First call must be preceded by a call to the \ref at45dbx_read_open
* function.
*/
extern U8 at45dbx_read_byte(void);
/*! \brief Performs a single byte write to DF memory.
*
* \param b The byte to write.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note First call must be preceded by a call to the \ref at45dbx_write_open
* function.
*/
extern Bool at45dbx_write_byte(U8 b);
//! @}
/*! \name Multiple-Sector Access Functions
*/
//! @{
/*! \brief Reads \a nb_sector sectors from DF memory.
*
* Data flow is: DF -> callback.
*
* \param nb_sector Number of contiguous sectors to read.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note First call must be preceded by a call to the \ref at45dbx_read_open
* function.
*
* \note As \ref AT45DBX_PAGE_SIZE is always a multiple of
* \ref AT45DBX_SECTOR_SIZE, there is no need to check page end for each
* byte.
*/
extern Bool at45dbx_read_multiple_sector(U16 nb_sector);
/*! \brief Callback function invoked after each sector read during
* \ref at45dbx_read_multiple_sector.
*
* \param psector Pointer to read sector.
*/
extern void at45dbx_read_multiple_sector_callback(const void *psector);
/*! \brief Writes \a nb_sector sectors to DF memory.
*
* Data flow is: callback -> DF.
*
* \param nb_sector Number of contiguous sectors to write.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note First call must be preceded by a call to the \ref at45dbx_write_open
* function.
*
* \note As \ref AT45DBX_PAGE_SIZE is always a multiple of
* \ref AT45DBX_SECTOR_SIZE, there is no need to check page end for each
* byte.
*/
extern Bool at45dbx_write_multiple_sector(U16 nb_sector);
/*! \brief Callback function invoked before each sector write during
* \ref at45dbx_write_multiple_sector.
*
* \param psector Pointer to sector to write.
*/
extern void at45dbx_write_multiple_sector_callback(void *psector);
//! @}
/*! \name Single-Sector Access Functions
*/
//! @{
/*! \brief Reads 1 DF sector to a RAM buffer.
*
* Data flow is: DF -> RAM.
*
* \param ram Pointer to RAM buffer.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note First call must be preceded by a call to the \ref at45dbx_read_open
* function.
*/
extern Bool at45dbx_read_sector_2_ram(void *ram);
/*! \brief Writes 1 DF sector from a RAM buffer.
*
* Data flow is: RAM -> DF.
*
* \param ram Pointer to RAM buffer.
*
* \retval OK Success.
* \retval KO Failure.
*
* \note First call must be preceded by a call to the \ref at45dbx_write_open
* function.
*/
extern Bool at45dbx_write_sector_from_ram(const void *ram);
//! @}
#endif // _AT45DBX_H_

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@ -0,0 +1,234 @@
/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief CTRL_ACCESS interface for the AT45DBX data flash controller.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
//_____ I N C L U D E S ___________________________________________________
#include "conf_access.h"
#if AT45DBX_MEM == ENABLE
#include "conf_at45dbx.h"
#include "at45dbx.h"
#include "at45dbx_mem.h"
//_____ D E F I N I T I O N S ______________________________________________
//! Whether to detect write accesses to the memory.
#define AT45DBX_MEM_TEST_CHANGE_STATE ENABLED
#if (ACCESS_USB == ENABLED || ACCESS_MEM_TO_RAM == ENABLED) && AT45DBX_MEM_TEST_CHANGE_STATE == ENABLED
//! Memory data modified flag.
static volatile Bool s_b_data_modify = FALSE;
#endif
/*! \name Control Interface
*/
//! @{
Ctrl_status at45dbx_test_unit_ready(void)
{
return (at45dbx_mem_check() == OK) ? CTRL_GOOD : CTRL_NO_PRESENT;
}
Ctrl_status at45dbx_read_capacity(U32 *u32_nb_sector)
{
*u32_nb_sector = (AT45DBX_MEM_CNT << (AT45DBX_MEM_SIZE - AT45DBX_SECTOR_BITS)) - 1;
return CTRL_GOOD;
}
Bool at45dbx_wr_protect(void)
{
return FALSE;
}
Bool at45dbx_removal(void)
{
return FALSE;
}
//! @}
#if ACCESS_USB == ENABLED
#include "usb_drv.h"
#include "scsi_decoder.h"
/*! \name MEM <-> USB Interface
*/
//! @{
Ctrl_status at45dbx_usb_read_10(U32 addr, U16 nb_sector)
{
if (addr + nb_sector > AT45DBX_MEM_CNT << (AT45DBX_MEM_SIZE - AT45DBX_SECTOR_BITS)) return CTRL_FAIL;
at45dbx_read_open(addr);
at45dbx_read_multiple_sector(nb_sector);
at45dbx_read_close();
return CTRL_GOOD;
}
void at45dbx_read_multiple_sector_callback(const void *psector)
{
U16 data_to_transfer = AT45DBX_SECTOR_SIZE;
// Transfer read sector to the USB interface.
while (data_to_transfer)
{
while (!Is_usb_in_ready(g_scsi_ep_ms_in))
{
if(!Is_usb_endpoint_enabled(g_scsi_ep_ms_in))
return; // USB Reset
}
Usb_reset_endpoint_fifo_access(g_scsi_ep_ms_in);
data_to_transfer = usb_write_ep_txpacket(g_scsi_ep_ms_in, psector,
data_to_transfer, &psector);
Usb_ack_in_ready_send(g_scsi_ep_ms_in);
}
}
Ctrl_status at45dbx_usb_write_10(U32 addr, U16 nb_sector)
{
if (addr + nb_sector > AT45DBX_MEM_CNT << (AT45DBX_MEM_SIZE - AT45DBX_SECTOR_BITS)) return CTRL_FAIL;
#if AT45DBX_MEM_TEST_CHANGE_STATE == ENABLED
if (nb_sector) s_b_data_modify = TRUE;
#endif
at45dbx_write_open(addr);
at45dbx_write_multiple_sector(nb_sector);
at45dbx_write_close();
return CTRL_GOOD;
}
void at45dbx_write_multiple_sector_callback(void *psector)
{
U16 data_to_transfer = AT45DBX_SECTOR_SIZE;
// Transfer sector to write from the USB interface.
while (data_to_transfer)
{
while (!Is_usb_out_received(g_scsi_ep_ms_out))
{
if(!Is_usb_endpoint_enabled(g_scsi_ep_ms_out))
return; // USB Reset
}
Usb_reset_endpoint_fifo_access(g_scsi_ep_ms_out);
data_to_transfer = usb_read_ep_rxpacket(g_scsi_ep_ms_out, psector,
data_to_transfer, &psector);
Usb_ack_out_received_free(g_scsi_ep_ms_out);
}
}
//! @}
#endif // ACCESS_USB == ENABLED
#if ACCESS_MEM_TO_RAM == ENABLED
/*! \name MEM <-> RAM Interface
*/
//! @{
Ctrl_status at45dbx_df_2_ram(U32 addr, void *ram)
{
if (addr + 1 > AT45DBX_MEM_CNT << (AT45DBX_MEM_SIZE - AT45DBX_SECTOR_BITS)) return CTRL_FAIL;
at45dbx_read_open(addr);
at45dbx_read_sector_2_ram(ram);
at45dbx_read_close();
return CTRL_GOOD;
}
Ctrl_status at45dbx_ram_2_df(U32 addr, const void *ram)
{
if (addr + 1 > AT45DBX_MEM_CNT << (AT45DBX_MEM_SIZE - AT45DBX_SECTOR_BITS)) return CTRL_FAIL;
#if AT45DBX_MEM_TEST_CHANGE_STATE == ENABLED
s_b_data_modify = TRUE;
#endif
at45dbx_write_open(addr);
at45dbx_write_sector_from_ram(ram);
at45dbx_write_close();
return CTRL_GOOD;
}
//! @}
#endif // ACCESS_MEM_TO_RAM == ENABLED
#endif // AT45DBX_MEM == ENABLE

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief CTRL_ACCESS interface for the AT45DBX data flash controller.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _AT45DBX_MEM_H_
#define _AT45DBX_MEM_H_
#include "conf_access.h"
#if AT45DBX_MEM == DISABLE
#error at45dbx_mem.h is #included although AT45DBX_MEM is disabled
#endif
#include "ctrl_access.h"
//_____ D E C L A R A T I O N S ____________________________________________
/*! \name Control Interface
*/
//! @{
/*! \brief Tests the memory state and initializes the memory if required.
*
* The TEST UNIT READY SCSI primary command allows an application client to poll
* a LUN until it is ready without having to allocate memory for returned data.
*
* This command may be used to check the media status of LUNs with removable
* media.
*
* \return Status.
*/
extern Ctrl_status at45dbx_test_unit_ready(void);
/*! \brief Returns the address of the last valid sector in the memory.
*
* \param u32_nb_sector Pointer to the address of the last valid sector.
*
* \return Status.
*/
extern Ctrl_status at45dbx_read_capacity(U32 *u32_nb_sector);
/*! \brief Returns the write-protection state of the memory.
*
* \return \c TRUE if the memory is write-protected, else \c FALSE.
*
* \note Only used by removable memories with hardware-specific write
* protection.
*/
extern Bool at45dbx_wr_protect(void);
/*! \brief Tells whether the memory is removable.
*
* \return \c TRUE if the memory is removable, else \c FALSE.
*/
extern Bool at45dbx_removal(void);
//! @}
#if ACCESS_USB == ENABLED
/*! \name MEM <-> USB Interface
*/
//! @{
/*! \brief Tranfers data from the memory to USB.
*
* \param addr Address of first memory sector to read.
* \param nb_sector Number of sectors to transfer.
*
* \return Status.
*/
extern Ctrl_status at45dbx_usb_read_10(U32 addr, U16 nb_sector);
/*! \brief Tranfers data from USB to the memory.
*
* \param addr Address of first memory sector to write.
* \param nb_sector Number of sectors to transfer.
*
* \return Status.
*/
extern Ctrl_status at45dbx_usb_write_10(U32 addr, U16 nb_sector);
//! @}
#endif
#if ACCESS_MEM_TO_RAM == ENABLED
/*! \name MEM <-> RAM Interface
*/
//! @{
/*! \brief Copies 1 data sector from the memory to RAM.
*
* \param addr Address of first memory sector to read.
* \param ram Pointer to RAM buffer to write.
*
* \return Status.
*/
extern Ctrl_status at45dbx_df_2_ram(U32 addr, void *ram);
/*! \brief Copies 1 data sector from RAM to the memory.
*
* \param addr Address of first memory sector to write.
* \param ram Pointer to RAM buffer to read.
*
* \return Status.
*/
extern Ctrl_status at45dbx_ram_2_df(U32 addr, const void *ram);
//! @}
#endif
#endif // _AT45DBX_MEM_H_

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#ifndef WL_OS_H
#define WL_OS_H
#include <stdarg.h>
#include <stdlib.h>
void *owl_os_alloc(size_t size);
void *owl_os_realloc(void *ptr, size_t size);
void owl_os_free(void *p);
void *owl_os_memcpy(void *dst, const void *src, size_t n);
void *owl_os_memset(void *s, int c, size_t n);
void *owl_os_memmove(void *dst, const void *src, size_t n);
size_t owl_os_strlen(char *s);
char *owl_os_strncpy(char *dst, const char *src, size_t n);
int owl_os_strncmp(const char *s1, const char *s2, size_t n);
int owl_os_strcmp(const char *s1, const char *s2);
char *owl_os_strcpy(char *dst, const char *src);
char *owl_os_strdup(const char *s);
char *owl_os_strndup(const char *s, size_t n);
int owl_os_memcmp(const void *s1, const void *s2, size_t n);
long int owl_os_strtol(const char *nptr, char **endptr, int base);
char *owl_os_strchr(const char *s, int c);
char *owl_os_strrchr(const char *s, int c);
int owl_os_strcasecmp(const char *s1, const char *s2);
char *owl_os_strstr(const char *haystack, const char *needle);
int owl_os_snprintf(char *str, size_t size, const char *format, ...)
__attribute__((format(printf, 3, 4)));
int owl_os_vprintf(const char *format, va_list arg); /* debug only */
int owl_os_printf(const char *format, ...) /* debug only */
__attribute__((format(printf, 1, 2)));
#endif /* WL_OS_H */

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/*!
* \file wl_sdio.h
* \brief SDIO interface for wl_api.
* Copyright (C) 2010 HD Wireless AB
*
* You should have received a copy of the license along with this library.
*/
#ifndef WL_SDIO_H
#define WL_SDIO_H
/** \defgroup wl_sdio SDIO Interface
*
* These functions implement the interface that the wl_api library
* needs to work with a SDIO transport layer.
*
* The functions prototyped here must be implemented when porting the
* wl_api library to a new platform with a different SDIO configuration
*
* On platforms supported by H&D Wireless these functions are
* implemented in the file avr32_sdio.c
*
* @{
*/
/**
* Maximum transfer size. This will set an upper limit on the len parameter
* passed to owl_sdio_tx() and owl_sdio_rx().
*
*/
#define MAX_BLOCK_LEN 512
/**
* This flag might be set when owl_sdio_cmd() is called in case the cmd will
* be followed by a data transfer. If the flag is set, the transfer direction is
* from the device to the host (read). Otherwise, the transfer direction is
* from the host to the device (write).
*
*/
#define CMD_FLAG_TO_HOST (1 << 0)
/**
* Indicates that the sdio driver needs to be polled in order to make
* forward progress, i.e. it does not support interrupts
*
* The actual polling will result in owl_sdio_cmd() being called to
* request status information from the device.
*
* To activate polling, this flag should be set in owl_sdio_init().
*/
#define SDIO_FLAG_POLL (1 << 0)
/**
* Indicates that the sdio driver only supports 1-bit mode.
*
* To set 1-bit mode, this flag should be set in owl_sdio_init().
*/
#define SDIO_FLAG_1BIT_MODE (1 << 1)
/**
* This function will be invoked when wlan initialization should be performed,
* this happens when the wl_fw_download() function in the transport group of
* wl_api is invoked.
*
* The wifi device supports sdio high speed mode and clock frequencies up to
* 50 MHz.
*
* The function is responsible for doing any necessary sdio initialization such
* as allocating gpio's, setting up the mci master, one time allocations of
* dma buffers etc.
*
* @param flags is an out parameter that should hold any sdio flags upon return.
* The avaible flags are prefixed with SDIO_FLAG_
*
*
*/
void owl_sdio_init(uint8_t *flags);
/**
* This function will be invoked when an sdio cmd should be sent to the
* device.
*
* @param idx is the sdio command number
* @param arg is the sdio command argument
* @param flags specifies other options, such as any transfer direction.
* @param rsp should hold the command response upon return. If null, the
* response can be ignored.
* @param data holds a pointer to any data that might follow the command. This
* allows the sdio driver to setup dma transfers while waiting for the
* command response. NULL if no data transfer will follow. Note that
* the same data pointer will be passed to owl_sdio_tx(), which should
* start the actual transfer.
* @param len is the length of the data buffer.
*
*/
void owl_sdio_cmd(uint8_t idx, uint32_t arg, uint8_t flags, uint32_t *rsp,
const uint8_t *data, uint16_t len);
/**
* This function will be invoked when data should be transmitted to the device.
*
* If wl_fw_downlad() was called with the size_align parameter set to non-zero,
* the pad parameter should be used. If the pad parameter is not 0, additional
* data must be transmitted after the data buffer has be sent. Depending on
* how the data buffer was first allocated (probably by an TCP/IP stack), it
* might be safe or unsafe to continue reading beyond the data buffer to
* transmit the additional padding bytes.
*
* @param data holds a pointer to the data to transmit, the pointer is the
* same as the one passed to wl_tx().
* @param len is the number of bytes that should be transmitted, including
* padding.
* @param pad is the number of padding bytes to send.
*
*/
void owl_sdio_tx(const uint8_t *data, uint16_t len, uint8_t pad);
/**
* This function will be invoked when data should be received from the device.
*
* @param data should hold the read data upon return.
* @param len is the number of bytes to read.
*
*/
void owl_sdio_rx(uint8_t *data, uint16_t len);
/**
* Invoked when sdio rx interrupts from the device should be enabled or
* disabled.
*
* If SDIO_FLAG_POLL was set in wl_spi_init(), then this function can be
* left empty.
*
* @param enable specifies if interrupts should be enabled or disabled.
*
*/
void owl_sdio_irq(uint8_t enable);
/**
* Delay executiom for the specified number of ms. This function will be called
* with delays in the 10-20 ms range during fw download and startup of the
* Wi-Fi device. This function can be implemented with a simple for-loop if
* desired (beware of optimization). The timing does not have to be accurate as
* long as the actual delay becomes at least the specified number of ms.
*
* @param ms is the minimal amount of time to wait [ms].
*
*/
void owl_sdio_mdelay(uint32_t ms);
/**
* This function should be called whenever an interrupt is detected. It can
* be called from an interrupt context.
*
* If SDIO_FLAG_POLL was set in owl_sdio_init(), then wl_sdio_irq()
* should never be called.
*
*/
extern void wl_sdio_irq(void);
/*! @} */
#endif

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/*!
* \file wl_spi.h
* \brief SPI interface for wl_api.
* Copyright (C) 2010 HD Wireless AB
*
* You should have received a copy of the license along with this library.
*/
#ifndef WL_SPI_H
#define WL_SPI_H
#ifndef WITHOUT_STDINT
#include <stdint.h>
#endif
/** \defgroup wl_spi SPI Interface
*
* These functions implement the interface that the wl_api library
* needs to work with a SPI transport layer.
*
* The functions prototyped here must be implemented when porting the
* wl_api library to a new platform with a different SPI configuration
*
* On platforms supported by H&D Wireless these functions are
* implemented in the file avr32_spi.c
*
* @{
*/
/**
* Maximum transfer size. This will set an upper limit on the len parameter
* passed to owl_spi_txrx().
*
*
*/
#define MAX_BLOCK_LEN 512
/**
* Indicates that the spi driver needs to be polled in order to make
* forward progress, i.e. it does not support interrupts through SD pin 8.
*
* The actual polling will result in owl_spi_txrx() being call to
* request status information from the device.
*
* To activate polling, this flag should be set in owl_spi_init().
*
* See wl_poll() and wl_register_rx_isr() for more information regarding
* polled and interrupt modes.
*
*/
#define SPI_FLAG_POLL (1 << 0)
/**
* This function will be invoked when wlan device initialization should be
* performed, this happens when the wl_fw_download() function in the transport
* group of wl_api is invoked.
*
* The wifi device requires spi mode 3, i.e. clock polarity high and sample
* on second phase. This corresponds to CPOL=1, CPHA=1. Maximum frequency on
* spi clock is 30 MHz.
*
* The function is also responsible for doing any necessary spi initialization
* such as allocating gpio's, setting up the SPI master, one time allocations of
* dma buffers etc.
*
*
* If the SPB105 device is used, two signals; POWER (pin 10 on SPB105) and
* SHUTDOWN (pin 4 on SPB105) might be connected to gpio's on the host.
* The GPIO_POWER_PIN is the main power supply to the device. The
* GPIO_SHUTDOWN_PIN (active low) should be defined as an input.
*
* After GPIO_POWER_PIN is pulled high by the host, the device will pull the
* GPIO_SHUTDOWN_PIN high once the device is properly powered.
*
* However, if pin 4 (GPIO_SHUTDOWN_PIN) is not connected to the host, a delay
* of up to 250 ms must be added after GPIO_POWER_PIN is pulled high to ensure
* that startup is completed. The actual time is usually much shorter, therefore
* one might try to reduce the delay for a particualar hardware design.
*
* On SPB104, the GPIO_POWER_PIN will be connected to VCC and GPIO_SHUTDOWN_PIN
* will be unconnected; hence we have to make sure that we have enough delay
* after powering on the host. Since the device power-on usually happens at the
* same time as the host power-on, the startup time of the host can be
* subtracted from any delay put into owl_spi_init().
*
* @param flags is an out parameter that should hold any spi flags upon return.
* The avaible flags are prefixed with SPI_FLAG_
*
* @return 0 on success
* -1 if any error occurs
*
*/
int owl_spi_init(uint8_t *flags);
/**
* Invoked when a spi transfer should be performed.
*
* All buffers that are allocated by the wl library will have a size that is
* aligned to 4. If size-unaligned data is passed to this function, it is
* always allocated by the ip stack. If 4-byte size alignment (e.g. for DMA)
* is required, 1-3 extra padding bytes can be transmitted after the in buffer.
* These bytes must be 0xff.
*
* Since size-unaligned data always comes from the ip stack, the out ptr is
* always NULL for such data.
*
* @param in points a buffer which holds the data to be transmitted. If NULL,
* then \a len bytes with the value 0xff should be transmitted on the
* bus.
* @param out points a buffer should hold the data received from the device. If
* NULL, any received data can be discarded.
* @param len is the length of the in and out buffers.
*
*/
void owl_spi_txrx(const uint8_t *in, uint8_t* out, uint16_t len);
/**
* Invoked when spi rx interrupts from the device should be enabled or disabled.
* Note that the spi interrupts are obtained from pin 8 on SPB104 or pin 3 from
* SPB105. This pin can be be connected to a gpio on the host. The irq line
* will signal an interrupt on both edges.
*
* In general, the wifi device will not issue a new interrupt unless the
* last interrupt has been handled. Also, during normal operation (i.e after
* the complete callback registered in wl_init() has been invoked),
* owl_spi_irq() will never be invoked so interrupts will be enabled all
* the time. For the SPI-mode, the purpose of owl_spi_irq() is basically to
* make sure that the first interrupt (coming after the reset performed in
* owl_spi_init()) is ignored.
*
* If SPI_FLAG_POLL was set in owl_spi_init(), then this function can be
* left empty and the wifi device will be used in polled mode. In polled mode,
* the interrupt line is not used. Regardless of polled or interrupt-mode,
* wl_poll() must be called to ensure progress of the driver.
*
* @param enable specifies if interrupts should be enabled or disabled.
*
*/
void owl_spi_irq(uint8_t enable);
/**
* Invoked when the spi cs for the wifi device should be enabled. Note that
* multiple calls to owl_spi_txrx() might be done during a 'single' chip
* select.
*
* @param enable specifies whether chip select should be asserted or deasserted,
* The chip select signal is active low, so if enable is '1' then the
* chip select connected to the wifi device should be set to '0'.
*
*/
void owl_spi_cs(uint8_t enable);
/**
* Delay executiom for the specified number of ms. This function will be called
* with delays in the 10-20 ms range during fw download and startup of the
* Wi-Fi device. This function can be implemented with a simple for-loop if
* desired (beware of optimization). The timing does not have to be accurate as
* long as the actual delay becomes at least the specified number of ms.
*
* @param ms is the minimal amount of time to wait [ms].
*
*/
void owl_spi_mdelay(uint32_t ms);
/**
* This function should be called whenever an interrupt is detected. It can
* be called from an interrupt context.
*
* If SPI_FLAG_POLL was set in owl_spi_init(), then wl_spi_irq()
* should never be called.
*
*/
extern void wl_spi_irq(void);
/*! @} */
#endif

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/*
* Programming interface for wlap_api.
* Copyright (C) 2011 HD Wireless AB
*
* You should have received a copy of the license along with this library.
*/
/*! \file wlap_api.h *************************************************************
*
* \brief WiFi AP API
*
* This file provides the wlap_api interface.
*
* - Compiler: GNU GCC for AVR32
* - Supported devices:
* \li SPB104 + EVK1100
* \li SPB104 + EVK1101
* \li SPB104 + EVK1104
* \li SPB104 + EVK1105 (SPI)
* \li SPB104 + EVK1105 (SPI + irq)
* \li SPB105 + EVK1105 (SPI)
* - AppNote:
*
* \author H&D Wireless AB: \n
*
*****************************************************************************
*
* \section intro Introduction
* This is the documentation for the WiFi AP Driver API \a wlap_api.
*
* \section files Main Files
* - wlap_api.h : WiFi driver interface.
* - libwlap_api_*.*.a - Driver library.
*
*/
#ifndef WLAP_API_H
#define WLAP_API_H
#define WLAP_API_RELEASE_NAME "unknown"
#include <wl_api.h>
/** \defgroup wl_softap Access Point Mode
*
* \brief Support the WiFi Access Point mode.
*
* @{
*/
/*
* Station representation
*
*/
struct wl_sta_t
{
struct wl_mac_addr_t bssid; /**< The BSSID of the network. */
uint8_t queued_pkt_cnt; /**< Number of queueud packets for
this STA. */
uint8_t in_ps; /**< Is the STA in power save mode. */
uint8_t aid; /**< STA AID */
};
/* Station list representation. Array of pointers to wl_sta_t entries. */
struct wl_sta_list_t
{
struct wl_sta_t **sta; /**< The list of pointers to stations */
size_t cnt; /**< Number of stations */
};
/*! \brief Get the list of currently associated stations (SoftAP).
*
* Retrieves the list of current stations from
* the driver.
*
* This function is not thread safe. It must be called in the
* same execution context as wl_poll().
*
* @param network_list Output buffer. The API call returns
* a pointer to allocated memory containing the network list.
* @return
* - WL_SUCCESS
* - WL_FAILURE.
*/
wl_err_t wlap_get_sta_list(struct wl_sta_list_t **network_list);
/*! Callback used to read data from a TX packet.
* This function is supplied by the user of the API.
*
* @param dst Destination buffer. The data should be copied
* to this buffer.
* @param src_handle Handle to the source packet from where
* the data should be copied. This handle is the same one that
* is passed in parameter \a pkt_handle to \a wl_process_tx().
* @param read_len Number of bytes to copy from \a src_handle
* to \a dst.
* @param offset The offset in bytes, counting from the
* beginning of the Ethernet header, from where to copy data.
* @return
* - The number of bytes copied. This number may be smaller
* than the length requested in \a read_len but it may not
* be shorter than the length of the packet counting from
* \a offset. In other words, if the caller of this function
* receives a return count that is shorter than \a read_len
* he will assume that all packet data has been read.
* - < 0 on error.
*/
typedef ssize_t (*wl_pkt_read_cb_t)(char *dst,
void *src_handle,
size_t read_len,
int offset);
/*! \brief Register a data access function for TX packets (SoftAP).
*
* When a TX data packet has a different representation than a single
* contiguous buffer in memory then a packet read function must be
* implemented and registered with this call. Whenever the library
* needs to read packet data it will call this function to do it.
*
* This function can be ignored if the TX packet representation is
* a single contiguous buffer. This function is only needed in SoftAP
* mode.
*
* @param pkt_read_cb Read callback.
* @param ctx Context
*/
void wl_register_pkt_read_cb(wl_pkt_read_cb_t pkt_read_cb);
/*! \brief Start a network using the SoftAP mode.
*
* This call will cause the WiFi chip to start sending beacons
* and accept associations from WiFi stations.
*
*/
wl_err_t wlap_start_ap(const char *ssid,
const size_t ssid_len,
const uint8_t channel,
const enum wl_auth_mode auth_mode,
const enum wl_enc_type enc_type);
/*! \brief Disconnect a STA (SoftAP)
*
* @param bssid The BSSID of the station to disconnect.
* @return
* - WL_SUCCESS
* - WL_FAILURE.
*/
wl_err_t wlap_disconnect_sta(const struct wl_mac_addr_t bssid);
/*! @} */ /* End wl_softap group */
#endif

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Cycle counter driver.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32UC devices.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _CYCLE_COUNTER_H_
#define _CYCLE_COUNTER_H_
#include "compiler.h"
//! Structure holding private information, automatically initialized by the
//! cpu_set_timeout() function.
typedef struct
{
//! The cycle count at the begining of the timeout.
unsigned long delay_start_cycle;
//! The cycle count at the end of the timeout.
unsigned long delay_end_cycle;
//! Enable/disable the timout detection
unsigned char timer_state;
#define CPU_TIMER_STATE_STARTED 0
#define CPU_TIMER_STATE_REACHED 1
#define CPU_TIMER_STATE_STOPPED 2
} t_cpu_time;
/*!
* \brief Convert milli-seconds into CPU cycles.
*
* \param ms: Number of millisecond.
* \param fcpu_hz: CPU frequency in Hz.
*
* \return the converted number of CPU cycles.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ U32 cpu_ms_2_cy(unsigned long ms, unsigned long fcpu_hz)
{
return ((unsigned long long)ms * fcpu_hz + 999) / 1000;
}
/*!
* \brief Convert micro-seconds into CPU cycles.
*
* \param us: Number of microsecond.
* \param fcpu_hz: CPU frequency in Hz.
*
* \return the converted number of CPU cycles.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ U32 cpu_us_2_cy(unsigned long us, unsigned long fcpu_hz)
{
return ((unsigned long long)us * fcpu_hz + 999999) / 1000000;
}
/*!
* \brief Convert CPU cycles into milli-seconds.
*
* \param cy: Number of CPU cycles.
* \param fcpu_hz: CPU frequency in Hz.
*
* \return the converted number of milli-second.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ U32 cpu_cy_2_ms(unsigned long cy, unsigned long fcpu_hz)
{
return ((unsigned long long)cy * 1000 + fcpu_hz-1) / fcpu_hz;
}
/*!
* \brief Convert CPU cycles into micro-seconds.
*
* \param cy: Number of CPU cycles.
* \param fcpu_hz: CPU frequency in Hz.
*
* \return the converted number of micro-second.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ U32 cpu_cy_2_us(unsigned long cy, unsigned long fcpu_hz)
{
return ((unsigned long long)cy * 1000000 + fcpu_hz-1) / fcpu_hz;
}
/*!
* \brief Set a timer variable.
*
* Ex: t_cpu_time timer;
* cpu_set_timeout( cpu_ms_2_cy(10, FOSC0), &timer ); // timeout in 10 ms
* if( cpu_is_timeout(&timer) )
* cpu_stop_timeout(&timer);
* ../..
*
* \param delay: (input) delay in CPU cycles before timeout.
* \param cpu_time: (output) internal information used by the timer API.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void cpu_set_timeout(unsigned long delay, t_cpu_time *cpu_time)
{
cpu_time->delay_start_cycle = Get_system_register(AVR32_COUNT);
cpu_time->delay_end_cycle = cpu_time->delay_start_cycle + delay;
cpu_time->timer_state = CPU_TIMER_STATE_STARTED;
}
/*!
* \brief Test if a timer variable reached its timeout.
*
* Once the timeout is reached, the function will always return TRUE,
* until the cpu_stop_timeout() function is called.
*
* Ex: t_cpu_time timer;
* cpu_set_timeout( 10, FOSC0, &timer ); // timeout in 10 ms
* if( cpu_is_timeout(&timer) )
* cpu_stop_timeout(&timer);
* ../..
*
* \param cpu_time: (input) internal information used by the timer API.
*
* \return TRUE if timeout occured, otherwise FALSE.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ unsigned long cpu_is_timeout(t_cpu_time *cpu_time)
{
unsigned long current_cycle_count = Get_system_register(AVR32_COUNT);
if( cpu_time->timer_state==CPU_TIMER_STATE_STOPPED )
return FALSE;
// Test if the timeout as already occured.
else if (cpu_time->timer_state == CPU_TIMER_STATE_REACHED)
return TRUE;
// If the ending cycle count of this timeout is wrapped, ...
else if (cpu_time->delay_start_cycle > cpu_time->delay_end_cycle)
{
if (current_cycle_count < cpu_time->delay_start_cycle && current_cycle_count > cpu_time->delay_end_cycle)
{
cpu_time->timer_state = CPU_TIMER_STATE_REACHED;
return TRUE;
}
return FALSE;
}
else
{
if (current_cycle_count < cpu_time->delay_start_cycle || current_cycle_count > cpu_time->delay_end_cycle)
{
cpu_time->timer_state = CPU_TIMER_STATE_REACHED;
return TRUE;
}
return FALSE;
}
}
/*!
* \brief Stop a timeout detection.
*
* Ex: t_cpu_time timer;
* cpu_set_timeout( 10, FOSC0, &timer ); // timeout in 10 ms
* if( cpu_is_timeout(&timer) )
* cpu_stop_timeout(&timer);
* ../..
*
* \param cpu_time: (input) internal information used by the timer API.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void cpu_stop_timeout(t_cpu_time *cpu_time)
{
cpu_time->timer_state = CPU_TIMER_STATE_STOPPED;
}
/*!
* \brief Test if a timer is stopped.
*
* \param cpu_time: (input) internal information used by the timer API.
*
* \return TRUE if timer is stopped, otherwise FALSE.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ unsigned long cpu_is_timer_stopped(t_cpu_time *cpu_time)
{
if( cpu_time->timer_state==CPU_TIMER_STATE_STOPPED )
return TRUE;
else
return FALSE;
}
/*!
* \brief Waits during at least the specified delay (in millisecond) before returning.
*
* \param delay: Number of millisecond to wait.
* \param fcpu_hz: CPU frequency in Hz.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void cpu_delay_ms(unsigned long delay, unsigned long fcpu_hz)
{
t_cpu_time timer;
cpu_set_timeout( cpu_ms_2_cy(delay, fcpu_hz), &timer);
while( !cpu_is_timeout(&timer) );
}
/*!
* \brief Waits during at least the specified delay (in microsecond) before returning.
*
* \param delay: Number of microsecond to wait.
* \param fcpu_hz: CPU frequency in Hz.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void cpu_delay_us(unsigned long delay, unsigned long fcpu_hz)
{
t_cpu_time timer;
cpu_set_timeout( cpu_us_2_cy(delay, fcpu_hz), &timer);
while( !cpu_is_timeout(&timer) );
}
/*!
* \brief Waits during at least the specified delay (in CPU cycles) before returning.
*
* \param delay: Number of CPU cycles to wait.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void cpu_delay_cy(unsigned long delay)
{
t_cpu_time timer;
cpu_set_timeout( delay, &timer);
while( !cpu_is_timeout(&timer) );
}
#define Get_sys_count() ( Get_system_register(AVR32_COUNT) )
#define Set_sys_count(x) ( Set_system_register(AVR32_COUNT, (x)) )
#define Get_sys_compare() ( Get_system_register(AVR32_COMPARE) )
#define Set_sys_compare(x) ( Set_system_register(AVR32_COMPARE, (x)) )
#endif // _CYCLE_COUNTER_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief SMC on EBI driver for AVR32 UC3.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a SMC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "compiler.h"
#include "preprocessor.h"
#include "gpio.h"
#include "smc.h"
// Configure the SM Controller with SM setup and timing information for all chip select
#define SMC_CS_SETUP(ncs) { \
U32 nwe_setup = ((NWE_SETUP * hsb_mhz_up + 999) / 1000); \
U32 ncs_wr_setup = ((NCS_WR_SETUP * hsb_mhz_up + 999) / 1000); \
U32 nrd_setup = ((NRD_SETUP * hsb_mhz_up + 999) / 1000); \
U32 ncs_rd_setup = ((NCS_RD_SETUP * hsb_mhz_up + 999) / 1000); \
U32 nwe_pulse = ((NWE_PULSE * hsb_mhz_up + 999) / 1000); \
U32 ncs_wr_pulse = ((NCS_WR_PULSE * hsb_mhz_up + 999) / 1000); \
U32 nrd_pulse = ((NRD_PULSE * hsb_mhz_up + 999) / 1000); \
U32 ncs_rd_pulse = ((NCS_RD_PULSE * hsb_mhz_up + 999) / 1000); \
U32 nwe_cycle = ((NWE_CYCLE * hsb_mhz_up + 999) / 1000); \
U32 nrd_cycle = ((NRD_CYCLE * hsb_mhz_up + 999) / 1000); \
\
/* Some coherence checks... */ \
/* Ensures CS is active during Rd or Wr */ \
if( ncs_rd_setup + ncs_rd_pulse < nrd_setup + nrd_pulse ) \
ncs_rd_pulse = nrd_setup + nrd_pulse - ncs_rd_setup; \
if( ncs_wr_setup + ncs_wr_pulse < nwe_setup + nwe_pulse ) \
ncs_wr_pulse = nwe_setup + nwe_pulse - ncs_wr_setup; \
\
/* ncs_hold = n_cycle - ncs_setup - ncs_pulse */ \
/* n_hold = n_cycle - n_setup - n_pulse */ \
/* */ \
/* All holds parameters must be positive or null, so: */ \
/* nwe_cycle shall be >= ncs_wr_setup + ncs_wr_pulse */ \
if( nwe_cycle < ncs_wr_setup + ncs_wr_pulse ) \
nwe_cycle = ncs_wr_setup + ncs_wr_pulse; \
\
/* nwe_cycle shall be >= nwe_setup + nwe_pulse */ \
if( nwe_cycle < nwe_setup + nwe_pulse ) \
nwe_cycle = nwe_setup + nwe_pulse; \
\
/* nrd_cycle shall be >= ncs_rd_setup + ncs_rd_pulse */ \
if( nrd_cycle < ncs_rd_setup + ncs_rd_pulse ) \
nrd_cycle = ncs_rd_setup + ncs_rd_pulse; \
\
/* nrd_cycle shall be >= nrd_setup + nrd_pulse */ \
if( nrd_cycle < nrd_setup + nrd_pulse ) \
nrd_cycle = nrd_setup + nrd_pulse; \
\
AVR32_SMC.cs[ncs].setup = (nwe_setup << AVR32_SMC_SETUP0_NWE_SETUP_OFFSET) | \
(ncs_wr_setup << AVR32_SMC_SETUP0_NCS_WR_SETUP_OFFSET) | \
(nrd_setup << AVR32_SMC_SETUP0_NRD_SETUP_OFFSET) | \
(ncs_rd_setup << AVR32_SMC_SETUP0_NCS_RD_SETUP_OFFSET); \
AVR32_SMC.cs[ncs].pulse = (nwe_pulse << AVR32_SMC_PULSE0_NWE_PULSE_OFFSET) | \
(ncs_wr_pulse << AVR32_SMC_PULSE0_NCS_WR_PULSE_OFFSET) | \
(nrd_pulse << AVR32_SMC_PULSE0_NRD_PULSE_OFFSET) | \
(ncs_rd_pulse << AVR32_SMC_PULSE0_NCS_RD_PULSE_OFFSET); \
AVR32_SMC.cs[ncs].cycle = (nwe_cycle << AVR32_SMC_CYCLE0_NWE_CYCLE_OFFSET) | \
(nrd_cycle << AVR32_SMC_CYCLE0_NRD_CYCLE_OFFSET); \
AVR32_SMC.cs[ncs].mode = (((NCS_CONTROLLED_READ) ? AVR32_SMC_MODE0_READ_MODE_NCS_CONTROLLED : \
AVR32_SMC_MODE0_READ_MODE_NRD_CONTROLLED) << AVR32_SMC_MODE0_READ_MODE_OFFSET) | \
+ (((NCS_CONTROLLED_WRITE) ? AVR32_SMC_MODE0_WRITE_MODE_NCS_CONTROLLED : \
AVR32_SMC_MODE0_WRITE_MODE_NWE_CONTROLLED) << AVR32_SMC_MODE0_WRITE_MODE_OFFSET) | \
(NWAIT_MODE << AVR32_SMC_MODE0_EXNW_MODE_OFFSET) | \
(((SMC_8_BIT_CHIPS) ? AVR32_SMC_MODE0_BAT_BYTE_WRITE : \
AVR32_SMC_MODE0_BAT_BYTE_SELECT) << AVR32_SMC_MODE0_BAT_OFFSET) | \
(((SMC_DBW <= 8 ) ? AVR32_SMC_MODE0_DBW_8_BITS : \
(SMC_DBW <= 16) ? AVR32_SMC_MODE0_DBW_16_BITS : \
AVR32_SMC_MODE0_DBW_32_BITS) << AVR32_SMC_MODE0_DBW_OFFSET) | \
(TDF_CYCLES << AVR32_SMC_MODE0_TDF_CYCLES_OFFSET) | \
(TDF_OPTIM << AVR32_SMC_MODE0_TDF_MODE_OFFSET) | \
(PAGE_MODE << AVR32_SMC_MODE0_PMEN_OFFSET) | \
(PAGE_SIZE << AVR32_SMC_MODE0_PS_OFFSET); \
smc_tab_cs_size[ncs] = (U8)EXT_SM_SIZE; \
}
static U8 smc_tab_cs_size[6];
static void smc_enable_muxed_pins(void);
void smc_init(unsigned long hsb_hz)
{
unsigned long hsb_mhz_up = (hsb_hz + 999999) / 1000000;
//! Whether to use the NCS0 pin
#ifdef SMC_USE_NCS0
#include SMC_COMPONENT_CS0
// Setup SMC for NCS0
SMC_CS_SETUP(0)
#ifdef SMC_DBW_GLOBAL
#if (SMC_DBW_GLOBAL < SMC_DBW)
#undef SMC_DBW_GLOBAL
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#else
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#ifdef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS_GLOBAL < SMC_8_BIT)
#undef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#else
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#ifdef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE_GLOBAL < NWAIT_MODE)
#undef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#else
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#undef EXT_SM_SIZE
#undef SMC_DBW
#undef SMC_8_BIT_CHIPS
#undef NWE_SETUP
#undef NCS_WR_SETUP
#undef NRD_SETUP
#undef NCS_RD_SETUP
#undef NCS_WR_PULSE
#undef NWE_PULSE
#undef NCS_RD_PULSE
#undef NRD_PULSE
#undef NCS_WR_HOLD
#undef NWE_HOLD
#undef NWE_CYCLE
#undef NCS_RD_HOLD
#undef NRD_CYCLE
#undef TDF_CYCLES
#undef TDF_OPTIM
#undef PAGE_MODE
#undef PAGE_SIZE
#undef NCS_CONTROLLED_READ
#undef NCS_CONTROLLED_WRITE
#undef NWAIT_MODE
#endif
//! Whether to use the NCS1 pin
#ifdef SMC_USE_NCS1
#include SMC_COMPONENT_CS1
// Enable SM mode for CS1 if necessary.
AVR32_HMATRIX.sfr[AVR32_EBI_HMATRIX_NR] &= ~(1 << AVR32_EBI_SDRAM_CS);
AVR32_HMATRIX.sfr[AVR32_EBI_HMATRIX_NR];
// Setup SMC for NCS1
SMC_CS_SETUP(1)
#ifdef SMC_DBW_GLOBAL
#if (SMC_DBW_GLOBAL < SMC_DBW)
#undef SMC_DBW_GLOBAL
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#else
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#ifdef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS_GLOBAL < SMC_8_BIT)
#undef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#else
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#ifdef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE_GLOBAL < NWAIT_MODE)
#undef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#else
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#undef EXT_SM_SIZE
#undef SMC_DBW
#undef SMC_8_BIT_CHIPS
#undef NWE_SETUP
#undef NCS_WR_SETUP
#undef NRD_SETUP
#undef NCS_RD_SETUP
#undef NCS_WR_PULSE
#undef NWE_PULSE
#undef NCS_RD_PULSE
#undef NRD_PULSE
#undef NCS_WR_HOLD
#undef NWE_HOLD
#undef NWE_CYCLE
#undef NCS_RD_HOLD
#undef NRD_CYCLE
#undef TDF_CYCLES
#undef TDF_OPTIM
#undef PAGE_MODE
#undef PAGE_SIZE
#undef NCS_CONTROLLED_READ
#undef NCS_CONTROLLED_WRITE
#undef NWAIT_MODE
#endif
//! Whether to use the NCS2 pin
#ifdef SMC_USE_NCS2
#include SMC_COMPONENT_CS2
// Setup SMC for NCS2
SMC_CS_SETUP(2)
#ifdef SMC_DBW_GLOBAL
#if (SMC_DBW_GLOBAL < SMC_DBW)
#undef SMC_DBW_GLOBAL
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#else
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#ifdef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS_GLOBAL < SMC_8_BIT)
#undef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#else
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#ifdef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE_GLOBAL < NWAIT_MODE)
#undef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#else
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#undef EXT_SM_SIZE
#undef SMC_DBW
#undef SMC_8_BIT_CHIPS
#undef NWE_SETUP
#undef NCS_WR_SETUP
#undef NRD_SETUP
#undef NCS_RD_SETUP
#undef NCS_WR_PULSE
#undef NWE_PULSE
#undef NCS_RD_PULSE
#undef NRD_PULSE
#undef NCS_WR_HOLD
#undef NWE_HOLD
#undef NWE_CYCLE
#undef NCS_RD_HOLD
#undef NRD_CYCLE
#undef TDF_CYCLES
#undef TDF_OPTIM
#undef PAGE_MODE
#undef PAGE_SIZE
#undef NCS_CONTROLLED_READ
#undef NCS_CONTROLLED_WRITE
#undef NWAIT_MODE
#endif
//! Whether to use the NCS3 pin
#ifdef SMC_USE_NCS3
#include SMC_COMPONENT_CS3
// Setup SMC for NCS3
SMC_CS_SETUP(3)
#ifdef SMC_DBW_GLOBAL
#if (SMC_DBW_GLOBAL < SMC_DBW)
#undef SMC_DBW_GLOBAL
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#else
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#ifdef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS_GLOBAL < SMC_8_BIT)
#undef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#else
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#ifdef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE_GLOBAL < NWAIT_MODE)
#undef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#else
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#undef EXT_SM_SIZE
#undef SMC_DBW
#undef SMC_8_BIT_CHIPS
#undef NWE_SETUP
#undef NCS_WR_SETUP
#undef NRD_SETUP
#undef NCS_RD_SETUP
#undef NCS_WR_PULSE
#undef NWE_PULSE
#undef NCS_RD_PULSE
#undef NRD_PULSE
#undef NCS_WR_HOLD
#undef NWE_HOLD
#undef NWE_CYCLE
#undef NCS_RD_HOLD
#undef NRD_CYCLE
#undef TDF_CYCLES
#undef TDF_OPTIM
#undef PAGE_MODE
#undef PAGE_SIZE
#undef NCS_CONTROLLED_READ
#undef NCS_CONTROLLED_WRITE
#undef NWAIT_MODE
#endif
//! Whether to use the NCS4 pin
#ifdef SMC_USE_NCS4
#include SMC_COMPONENT_CS4
// Setup SMC for NCS4
SMC_CS_SETUP(4)
#ifdef SMC_DBW_GLOBAL
#if (SMC_DBW_GLOBAL < SMC_DBW)
#undef SMC_DBW_GLOBAL
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#else
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#ifdef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS_GLOBAL < SMC_8_BIT)
#undef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#else
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#ifdef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE_GLOBAL < NWAIT_MODE)
#undef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#else
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#undef EXT_SM_SIZE
#undef SMC_DBW
#undef SMC_8_BIT_CHIPS
#undef NWE_SETUP
#undef NCS_WR_SETUP
#undef NRD_SETUP
#undef NCS_RD_SETUP
#undef NCS_WR_PULSE
#undef NWE_PULSE
#undef NCS_RD_PULSE
#undef NRD_PULSE
#undef NCS_WR_HOLD
#undef NWE_HOLD
#undef NWE_CYCLE
#undef NCS_RD_HOLD
#undef NRD_CYCLE
#undef TDF_CYCLES
#undef TDF_OPTIM
#undef PAGE_MODE
#undef PAGE_SIZE
#undef NCS_CONTROLLED_READ
#undef NCS_CONTROLLED_WRITE
#undef NWAIT_MODE
#endif
//! Whether to use the NCS5 pin
#ifdef SMC_USE_NCS5
#include SMC_COMPONENT_CS5
// Setup SMC for NCS5
SMC_CS_SETUP(5)
#ifdef SMC_DBW_GLOBAL
#if (SMC_DBW_GLOBAL < SMC_DBW)
#undef SMC_DBW_GLOBAL
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#else
#if (SMC_DBW == 8)
#define SMC_DBW_GLOBAL 8
#elif (SMC_DBW == 16)
#define SMC_DBW_GLOBAL 16
#elif (SMC_DBW == 32)
#define SMC_DBW_GLOBAL 32
#else
#error error in SMC_DBW size
#endif
#endif
#ifdef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS_GLOBAL < SMC_8_BIT)
#undef SMC_8_BIT_CHIPS_GLOBAL
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#else
#if (SMC_8_BIT_CHIPS == TRUE)
#define SMC_8_BIT_CHIPS_GLOBAL TRUE
#elif (SMC_8_BIT_CHIPS == FALSE)
#define SMC_8_BIT_CHIPS_GLOBAL FALSE
#else
#error error in SMC_8_BIT_CHIPS size
#endif
#endif
#ifdef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE_GLOBAL < NWAIT_MODE)
#undef NWAIT_MODE_GLOBAL
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#else
#if (NWAIT_MODE == AVR32_SMC_EXNW_MODE_DISABLED)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_DISABLED
#elif (NWAIT_MODE == AVR32_SMC_EXNW_MODE_FROZEN)
#define NWAIT_MODE_GLOBAL AVR32_SMC_EXNW_MODE_FROZEN
#else
#error error in NWAIT_MODE size
#endif
#endif
#undef EXT_SM_SIZE
#undef SMC_DBW
#undef SMC_8_BIT_CHIPS
#undef NWE_SETUP
#undef NCS_WR_SETUP
#undef NRD_SETUP
#undef NCS_RD_SETUP
#undef NCS_WR_PULSE
#undef NWE_PULSE
#undef NCS_RD_PULSE
#undef NRD_PULSE
#undef NCS_WR_HOLD
#undef NWE_HOLD
#undef NWE_CYCLE
#undef NCS_RD_HOLD
#undef NRD_CYCLE
#undef TDF_CYCLES
#undef TDF_OPTIM
#undef PAGE_MODE
#undef PAGE_SIZE
#undef NCS_CONTROLLED_READ
#undef NCS_CONTROLLED_WRITE
#undef NWAIT_MODE
#endif
// Put the multiplexed MCU pins used for the SM under control of the SMC.
smc_enable_muxed_pins();
}
/*! \brief Puts the multiplexed MCU pins used for the SMC
*
*/
static void smc_enable_muxed_pins(void)
{
static const gpio_map_t SMC_EBI_GPIO_MAP =
{
// Enable data pins.
#ifdef EBI_DATA_0
{ATPASTE2(EBI_DATA_0,_PIN),ATPASTE2(EBI_DATA_0,_FUNCTION)},
#endif
#ifdef EBI_DATA_1
{ATPASTE2(EBI_DATA_1,_PIN),ATPASTE2(EBI_DATA_1,_FUNCTION)},
#endif
#ifdef EBI_DATA_2
{ATPASTE2(EBI_DATA_2,_PIN),ATPASTE2(EBI_DATA_2,_FUNCTION)},
#endif
#ifdef EBI_DATA_3
{ATPASTE2(EBI_DATA_3,_PIN),ATPASTE2(EBI_DATA_3,_FUNCTION)},
#endif
#ifdef EBI_DATA_4
{ATPASTE2(EBI_DATA_4,_PIN),ATPASTE2(EBI_DATA_4,_FUNCTION)},
#endif
#ifdef EBI_DATA_5
{ATPASTE2(EBI_DATA_5,_PIN),ATPASTE2(EBI_DATA_5,_FUNCTION)},
#endif
#ifdef EBI_DATA_6
{ATPASTE2(EBI_DATA_6,_PIN),ATPASTE2(EBI_DATA_6,_FUNCTION)},
#endif
#ifdef EBI_DATA_7
{ATPASTE2(EBI_DATA_7,_PIN),ATPASTE2(EBI_DATA_7,_FUNCTION)},
#endif
#ifdef EBI_DATA_8
{ATPASTE2(EBI_DATA_8,_PIN),ATPASTE2(EBI_DATA_8,_FUNCTION)},
#endif
#ifdef EBI_DATA_9
{ATPASTE2(EBI_DATA_9,_PIN),ATPASTE2(EBI_DATA_9,_FUNCTION)},
#endif
#ifdef EBI_DATA_10
{ATPASTE2(EBI_DATA_10,_PIN),ATPASTE2(EBI_DATA_10,_FUNCTION)},
#endif
#ifdef EBI_DATA_11
{ATPASTE2(EBI_DATA_11,_PIN),ATPASTE2(EBI_DATA_11,_FUNCTION)},
#endif
#ifdef EBI_DATA_12
{ATPASTE2(EBI_DATA_12,_PIN),ATPASTE2(EBI_DATA_12,_FUNCTION)},
#endif
#ifdef EBI_DATA_13
{ATPASTE2(EBI_DATA_13,_PIN),ATPASTE2(EBI_DATA_13,_FUNCTION)},
#endif
#ifdef EBI_DATA_14
{ATPASTE2(EBI_DATA_14,_PIN),ATPASTE2(EBI_DATA_14,_FUNCTION)},
#endif
#ifdef EBI_DATA_15
{ATPASTE2(EBI_DATA_15,_PIN),ATPASTE2(EBI_DATA_15,_FUNCTION)},
#endif
#ifdef EBI_DATA_16
{ATPASTE2(EBI_DATA_16,_PIN),ATPASTE2(EBI_DATA_16,_FUNCTION)},
#endif
#ifdef EBI_DATA_17
{ATPASTE2(EBI_DATA_17,_PIN),ATPASTE2(EBI_DATA_17,_FUNCTION)},
#endif
#ifdef EBI_DATA_18
{ATPASTE2(EBI_DATA_18,_PIN),ATPASTE2(EBI_DATA_18,_FUNCTION)},
#endif
#ifdef EBI_DATA_19
{ATPASTE2(EBI_DATA_19,_PIN),ATPASTE2(EBI_DATA_19,_FUNCTION)},
#endif
#ifdef EBI_DATA_20
{ATPASTE2(EBI_DATA_20,_PIN),ATPASTE2(EBI_DATA_20,_FUNCTION)},
#endif
#ifdef EBI_DATA_21
{ATPASTE2(EBI_DATA_21,_PIN),ATPASTE2(EBI_DATA_21,_FUNCTION)},
#endif
#ifdef EBI_DATA_22
{ATPASTE2(EBI_DATA_22,_PIN),ATPASTE2(EBI_DATA_22,_FUNCTION)},
#endif
#ifdef EBI_DATA_23
{ATPASTE2(EBI_DATA_23,_PIN),ATPASTE2(EBI_DATA_23,_FUNCTION)},
#endif
#ifdef EBI_DATA_24
{ATPASTE2(EBI_DATA_24,_PIN),ATPASTE2(EBI_DATA_24,_FUNCTION)},
#endif
#ifdef EBI_DATA_25
{ATPASTE2(EBI_DATA_25,_PIN),ATPASTE2(EBI_DATA_25,_FUNCTION)},
#endif
#ifdef EBI_DATA_26
{ATPASTE2(EBI_DATA_26,_PIN),ATPASTE2(EBI_DATA_26,_FUNCTION)},
#endif
#ifdef EBI_DATA_27
{ATPASTE2(EBI_DATA_27,_PIN),ATPASTE2(EBI_DATA_27,_FUNCTION)},
#endif
#ifdef EBI_DATA_28
{ATPASTE2(EBI_DATA_28,_PIN),ATPASTE2(EBI_DATA_28,_FUNCTION)},
#endif
#ifdef EBI_DATA_29
{ATPASTE2(EBI_DATA_29,_PIN),ATPASTE2(EBI_DATA_29,_FUNCTION)},
#endif
#ifdef EBI_DATA_30
{ATPASTE2(EBI_DATA_30,_PIN),ATPASTE2(EBI_DATA_30,_FUNCTION)},
#endif
#ifdef EBI_DATA_31
{ATPASTE2(EBI_DATA_31,_PIN),ATPASTE2(EBI_DATA_31,_FUNCTION)},
#endif
// Enable address pins.
#if SMC_DBW_GLOBAL <= 8
#ifdef EBI_ADDR_0
{ATPASTE2(EBI_ADDR_0,_PIN),ATPASTE2(EBI_ADDR_0,_FUNCTION)},
#endif
#endif
#if SMC_DBW_GLOBAL <= 16
#ifdef EBI_ADDR_1
{ATPASTE2(EBI_ADDR_1,_PIN),ATPASTE2(EBI_ADDR_1,_FUNCTION)},
#endif
#endif
#ifdef EBI_ADDR_2
{ATPASTE2(EBI_ADDR_2,_PIN),ATPASTE2(EBI_ADDR_2,_FUNCTION)},
#endif
#ifdef EBI_ADDR_3
{ATPASTE2(EBI_ADDR_3,_PIN),ATPASTE2(EBI_ADDR_3,_FUNCTION)},
#endif
#ifdef EBI_ADDR_4
{ATPASTE2(EBI_ADDR_4,_PIN),ATPASTE2(EBI_ADDR_4,_FUNCTION)},
#endif
#ifdef EBI_ADDR_5
{ATPASTE2(EBI_ADDR_5,_PIN),ATPASTE2(EBI_ADDR_5,_FUNCTION)},
#endif
#ifdef EBI_ADDR_6
{ATPASTE2(EBI_ADDR_6,_PIN),ATPASTE2(EBI_ADDR_6,_FUNCTION)},
#endif
#ifdef EBI_ADDR_7
{ATPASTE2(EBI_ADDR_7,_PIN),ATPASTE2(EBI_ADDR_7,_FUNCTION)},
#endif
#ifdef EBI_ADDR_8
{ATPASTE2(EBI_ADDR_8,_PIN),ATPASTE2(EBI_ADDR_8,_FUNCTION)},
#endif
#ifdef EBI_ADDR_9
{ATPASTE2(EBI_ADDR_9,_PIN),ATPASTE2(EBI_ADDR_9,_FUNCTION)},
#endif
#ifdef EBI_ADDR_10
{ATPASTE2(EBI_ADDR_10,_PIN),ATPASTE2(EBI_ADDR_10,_FUNCTION)},
#endif
#ifdef EBI_ADDR_11
{ATPASTE2(EBI_ADDR_11,_PIN),ATPASTE2(EBI_ADDR_11,_FUNCTION)},
#endif
#ifdef EBI_ADDR_12
{ATPASTE2(EBI_ADDR_12,_PIN),ATPASTE2(EBI_ADDR_12,_FUNCTION)},
#endif
#ifdef EBI_ADDR_13
{ATPASTE2(EBI_ADDR_13,_PIN),ATPASTE2(EBI_ADDR_13,_FUNCTION)},
#endif
#ifdef EBI_ADDR_14
{ATPASTE2(EBI_ADDR_14,_PIN),ATPASTE2(EBI_ADDR_14,_FUNCTION)},
#endif
#ifdef EBI_ADDR_15
{ATPASTE2(EBI_ADDR_15,_PIN),ATPASTE2(EBI_ADDR_15,_FUNCTION)},
#endif
#ifdef EBI_ADDR_16
{ATPASTE2(EBI_ADDR_16,_PIN),ATPASTE2(EBI_ADDR_16,_FUNCTION)},
#endif
#ifdef EBI_ADDR_17
{ATPASTE2(EBI_ADDR_17,_PIN),ATPASTE2(EBI_ADDR_17,_FUNCTION)},
#endif
#ifdef EBI_ADDR_18
{ATPASTE2(EBI_ADDR_18,_PIN),ATPASTE2(EBI_ADDR_18,_FUNCTION)},
#endif
#ifdef EBI_ADDR_19
{ATPASTE2(EBI_ADDR_19,_PIN),ATPASTE2(EBI_ADDR_19,_FUNCTION)},
#endif
#ifdef EBI_ADDR_20
{ATPASTE2(EBI_ADDR_20,_PIN),ATPASTE2(EBI_ADDR_20,_FUNCTION)},
#endif
#ifdef EBI_ADDR_21
{ATPASTE2(EBI_ADDR_21,_PIN),ATPASTE2(EBI_ADDR_21,_FUNCTION)},
#endif
#ifdef EBI_ADDR_22
{ATPASTE2(EBI_ADDR_22,_PIN),ATPASTE2(EBI_ADDR_22,_FUNCTION)},
#endif
#ifdef EBI_ADDR_23
{ATPASTE2(EBI_ADDR_23,_PIN),ATPASTE2(EBI_ADDR_23,_FUNCTION)},
#endif
#if SMC_DBW_GLOBAL <= 8
#undef SMC_8_BIT_CHIPS
#define SMC_8_BIT_CHIPS TRUE
#endif
// Enable data mask pins.
#if !SMC_8_BIT_CHIPS_GLOBAL
#ifdef EBI_ADDR_0
{ATPASTE2(EBI_ADDR_0,_PIN),ATPASTE2(EBI_ADDR_0,_FUNCTION)},
#endif
#endif
#ifdef EBI_NWE0
{ATPASTE2(EBI_NWE0,_PIN),ATPASTE2(EBI_NWE0,_FUNCTION)},
#endif
#if SMC_DBW_GLOBAL >= 16
#ifdef EBI_NWE1
{ATPASTE2(EBI_NWE1,_PIN),ATPASTE2(EBI_NWE1,_FUNCTION)},
#endif
#if SMC_DBW_GLOBAL >= 32
#ifdef EBI_ADDR_1
{ATPASTE2(EBI_ADDR_1,_PIN),ATPASTE2(EBI_ADDR_1,_FUNCTION)},
#endif
#ifdef EBI_NWE3
{ATPASTE2(EBI_NWE3,_PIN),ATPASTE2(EBI_NWE3,_FUNCTION)},
#endif
#endif
#endif
#ifdef EBI_NRD
{ATPASTE2(EBI_NRD,_PIN),ATPASTE2(EBI_NRD,_FUNCTION)},
#endif
// Enable control pins.
#if NWAIT_MODE_GLOBAL != AVR32_SMC_EXNW_MODE_DISABLED
#ifdef EBI_NWAIT
{ATPASTE2(EBI_NWAIT,_PIN),ATPASTE2(EBI_NWAIT,_FUNCTION)},
#endif
#endif
#ifdef SMC_USE_NCS0
#ifdef EBI_NCS_0
{ATPASTE2(EBI_NCS_0,_PIN),ATPASTE2(EBI_NCS_0,_FUNCTION)},
#endif
#endif
#ifdef SMC_USE_NCS1
#ifdef EBI_NCS_1
{ATPASTE2(EBI_NCS_1,_PIN),ATPASTE2(EBI_NCS_1,_FUNCTION)},
#endif
#endif
#ifdef SMC_USE_NCS2
#ifdef EBI_NCS_2
{ATPASTE2(EBI_NCS_2,_PIN),ATPASTE2(EBI_NCS_2,_FUNCTION)},
#endif
#endif
#ifdef SMC_USE_NCS3
#ifdef EBI_NCS_3
{ATPASTE2(EBI_NCS_3,_PIN),ATPASTE2(EBI_NCS_3,_FUNCTION)},
#endif
#endif
#ifdef SMC_USE_NCS4
#ifdef EBI_NCS_4
{ATPASTE2(EBI_NCS_4,_PIN),ATPASTE2(EBI_NCS_4,_FUNCTION)},
#endif
#endif
#ifdef SMC_USE_NCS5
#ifdef EBI_NCS_5
{ATPASTE2(EBI_NCS_5,_PIN),ATPASTE2(EBI_NCS_5,_FUNCTION)},
#endif
#endif
};
gpio_enable_module(SMC_EBI_GPIO_MAP, sizeof(SMC_EBI_GPIO_MAP) / sizeof(SMC_EBI_GPIO_MAP[0]));
}
unsigned char smc_get_cs_size(unsigned char cs)
{
return smc_tab_cs_size[cs];
}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief SMC on EBI driver for AVR32 UC3.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a SMC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _SMC_H_
#define _SMC_H_
#include <avr32/io.h>
#include "compiler.h"
#include "conf_ebi.h"
/*! \brief Initializes the AVR32 SMC module and the connected SRAM(s).
* \param hsb_hz HSB frequency in Hz (the HSB frequency is applied to the SMC).
* \note Each access to the SMC address space validates the mode of the SMC
* and generates an operation corresponding to this mode.
*/
extern void smc_init(unsigned long hsb_hz);
/*! \brief Return the size of the peripheral connected .
* \param cs The chip select value
*/
extern unsigned char smc_get_cs_size(unsigned char cs);
#endif // _SMC_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief EIC driver for AVR32 UC3.
*
* AVR32 External Interrupt Controller driver module.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an EIC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <avr32/io.h>
#include "compiler.h"
#include "preprocessor.h"
#include "eic.h"
void eic_init(volatile avr32_eic_t *eic, const eic_options_t *opt, unsigned int nb_lines)
{
int i;
for (i = 0; i < nb_lines; i++)
{
// Set up mode level
eic->mode = (opt[i].eic_mode == 1) ? (eic->mode | (1 << opt[i].eic_line)) : (eic->mode & ~(1 << opt[i].eic_line));
// Set up edge type
eic->edge = (opt[i].eic_edge == 1) ? (eic->edge | (1 << opt[i].eic_line)) : (eic->edge & ~(1 << opt[i].eic_line));
// Set up level
eic->level = (opt[i].eic_level == 1) ? (eic->level | (1 << opt[i].eic_line)) : (eic->level & ~(1 << opt[i].eic_line));
// Set up if filter is used
eic->filter = (opt[i].eic_filter == 1) ? (eic->filter | (1 << opt[i].eic_line)) : (eic->filter & ~(1 << opt[i].eic_line));
// Set up which mode is used : asynchronous mode/ synchronous mode
eic->async = (opt[i].eic_async == 1) ? (eic->async | (1 << opt[i].eic_line)) : (eic->async & ~(1 << opt[i].eic_line));
}
}
void eic_enable_lines(volatile avr32_eic_t *eic, unsigned int mask_lines)
{
eic->en = mask_lines;
}
void eic_enable_line(volatile avr32_eic_t *eic, unsigned int line_number)
{
// Enable line line_number
eic->en = 1 << line_number;
}
void eic_disable_lines(volatile avr32_eic_t *eic, unsigned int mask_lines)
{
eic->dis = mask_lines;
}
void eic_disable_line(volatile avr32_eic_t *eic, unsigned int line_number)
{
// Disable line line_number
eic->dis = 1 << line_number;
}
Bool eic_is_line_enabled(volatile avr32_eic_t *eic, unsigned int line_number)
{
return (eic->ctrl & (1 << line_number)) != 0;
}
void eic_enable_interrupt_lines(volatile avr32_eic_t *eic, unsigned int mask_lines)
{
eic->ier = mask_lines;
}
void eic_enable_interrupt_line(volatile avr32_eic_t *eic, unsigned int line_number)
{
// Enable line line_number
eic->ier = 1 << line_number;
}
void eic_disable_interrupt_lines(volatile avr32_eic_t *eic, unsigned int mask_lines)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
eic->idr = mask_lines;
eic->imr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void eic_disable_interrupt_line(volatile avr32_eic_t *eic, unsigned int line_number)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
// Disable line line_number
if (global_interrupt_enabled) Disable_global_interrupt();
eic->idr = 1 << line_number;
eic->imr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
Bool eic_is_interrupt_line_enabled(volatile avr32_eic_t *eic, unsigned int line_number)
{
return (eic->imr & (1 << line_number)) != 0;
}
void eic_clear_interrupt_lines(volatile avr32_eic_t *eic, unsigned int mask_lines)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
eic->icr = mask_lines;
eic->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void eic_clear_interrupt_line(volatile avr32_eic_t *eic, unsigned int line_number)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
// Clear line line_number
if (global_interrupt_enabled) Disable_global_interrupt();
eic->icr = 1 << line_number;
eic->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
Bool eic_is_interrupt_line_pending(volatile avr32_eic_t *eic, unsigned int line_number)
{
return (eic->isr & (1 << line_number)) != 0;
}
#if !defined(AVR32_EIC_301_H_INCLUDED)
void eic_enable_interrupt_scan(volatile avr32_eic_t *eic,unsigned int presc)
{
// Enable SCAN function with PRESC value
eic->scan |= (presc << AVR32_EIC_SCAN_PRESC_OFFSET) | (1 << AVR32_EIC_SCAN_EN_OFFSET);
}
void eic_disable_interrupt_scan(volatile avr32_eic_t *eic)
{
// Disable SCAN function
eic->scan = 0 << AVR32_EIC_SCAN_EN_OFFSET;
}
unsigned long eic_get_interrupt_pad_scan(volatile avr32_eic_t *eic)
{
// Return pad number that causes interrupt
return(eic->scan>>AVR32_EIC_SCAN_PIN_OFFSET);
}
#endif

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief EIC driver for AVR32 UC3.
*
* AVR32 External Interrupt Controller driver module.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an EIC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _EIC_H_
#define _EIC_H_
#include "compiler.h"
/*! \name External Interrupt lines
*/
//! @{
#if (UC3A || UC3B)
#define EXT_INT0 AVR32_EIC_INT0 //!< Line 0
#define EXT_INT1 AVR32_EIC_INT1 //!< Line 1
#define EXT_INT2 AVR32_EIC_INT2 //!< Line 2
#define EXT_INT3 AVR32_EIC_INT3 //!< Line 3
#define EXT_INT4 AVR32_EIC_INT4 //!< Line 4
#define EXT_INT5 AVR32_EIC_INT5 //!< Line 5
#define EXT_INT6 AVR32_EIC_INT6 //!< Line 6
#define EXT_INT7 AVR32_EIC_INT7 //!< Line 7
#define EXT_NMI AVR32_EIC_NMI //!< Line 8
#else
#define EXT_INT0 AVR32_EIC_INT1 //!< Line 0
#define EXT_INT1 AVR32_EIC_INT2 //!< Line 1
#define EXT_INT2 AVR32_EIC_INT3 //!< Line 2
#define EXT_INT3 AVR32_EIC_INT4 //!< Line 3
#define EXT_INT4 AVR32_EIC_INT5 //!< Line 4
#define EXT_INT5 AVR32_EIC_INT6 //!< Line 5
#define EXT_INT6 AVR32_EIC_INT7 //!< Line 6
#define EXT_INT7 AVR32_EIC_INT8 //!< Line 7
#define EXT_NMI AVR32_EIC_NMI //!< Line 8
#endif
//! @}
/*! \name Mode Trigger Options
*/
//! @{
#define EIC_MODE_EDGE_TRIGGERED AVR32_EIC_EDGE_IRQ //!<
#define EIC_MODE_LEVEL_TRIGGERED AVR32_EIC_LEVEL_IRQ //!<
//! @}
/*! \name Edge level Options
*/
//! @{
#define EIC_EDGE_FALLING_EDGE AVR32_EIC_FALLING_EDGE //!<
#define EIC_EDGE_RISING_EDGE AVR32_EIC_RISING_EDGE //!<
//! @}
/*! \name Level Options
*/
//! @{
#define EIC_LEVEL_LOW_LEVEL AVR32_EIC_LOW_LEVEL //!<
#define EIC_LEVEL_HIGH_LEVEL AVR32_EIC_HIGH_LEVEL //!<
//! @}
/*! \name Filter Options
*/
//! @{
#define EIC_FILTER_ENABLED AVR32_EIC_FILTER_ON //!<
#define EIC_FILTER_DISABLED AVR32_EIC_FILTER_OFF //!<
//! @}
/*! \name Synch Mode Options
*/
//! @{
#define EIC_SYNCH_MODE AVR32_EIC_SYNC //!<
#define EIC_ASYNCH_MODE AVR32_EIC_USE_ASYNC //!<
//! @}
//! Configuration parameters of the EIC module.
typedef struct
{
//!Line
unsigned char eic_line;
//! Mode : EDGE_LEVEL or TRIGGER_LEVEL
unsigned char eic_mode;
//! Edge : FALLING_EDGE or RISING_EDGE
unsigned char eic_edge;
//! Level : LOW_LEVEL or HIGH_LEVEL
unsigned char eic_level;
//! Filter: NOT_FILTERED or FILTERED
unsigned char eic_filter;
//! Async: SYNC mode or ASYNC
unsigned char eic_async;
} eic_options_t;
/*! \brief Init the EIC driver.
*
* \param eic Base address of the EIC module
* \param opt Configuration parameters of the EIC module (see \ref eic_options_t)
* \param nb_lines Number of lines to consider, equal to size of opt buffer
*/
extern void eic_init(volatile avr32_eic_t *eic, const eic_options_t *opt, unsigned int nb_lines);
/*! \brief Enable the EIC driver.
*
* \param eic Base address of the EIC module
* \param mask_lines Mask for current selected lines
*/
extern void eic_enable_lines(volatile avr32_eic_t *eic, unsigned int mask_lines);
/*! \brief Enable the EIC driver.
*
* \param eic Base address of the EIC module
* \param line_number Line number to enable
*/
extern void eic_enable_line(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Disable the EIC driver.
*
* \param eic Base address of the EIC module
* \param mask_lines Mask for current selected lines
*/
extern void eic_disable_lines(volatile avr32_eic_t *eic, unsigned int mask_lines);
/*! \brief Disable the EIC driver.
*
* \param eic Base address of the EIC module
* \param line_number Line number to disable
*/
extern void eic_disable_line(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Tells whether an EIC line is enabled.
*
* \param eic Base address of the EIC module
* \param line_number Line number to test
*
* \return Whether an EIC line is enabled.
*/
extern Bool eic_is_line_enabled(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \name Interrupt Control Functions
*/
//! @{
/*! \brief Enable the interrupt feature of the EIC.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param mask_lines Mask for current selected lines
*/
extern void eic_enable_interrupt_lines(volatile avr32_eic_t *eic, unsigned int mask_lines);
/*! \brief Enable the interrupt feature of the EIC.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param line_number Line number to enable
*/
extern void eic_enable_interrupt_line(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Disable the interrupt feature of the EIC.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param mask_lines Mask for current selected lines
*/
extern void eic_disable_interrupt_lines(volatile avr32_eic_t *eic, unsigned int mask_lines);
/*! \brief Disable the interrupt feature of the EIC.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param line_number Line number to disable
*/
extern void eic_disable_interrupt_line(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Tells whether an EIC interrupt line is enabled.
*
* \param eic Base address of the EIC module
* \param line_number Line number to test
*
* \return Whether an EIC interrupt line is enabled.
*/
extern Bool eic_is_interrupt_line_enabled(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Clear the interrupt flag.
* Call this function once you've handled the interrupt.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param mask_lines Mask for current selected lines
*/
extern void eic_clear_interrupt_lines(volatile avr32_eic_t *eic, unsigned int mask_lines);
/*! \brief Clear the interrupt flag.
* Call this function once you've handled the interrupt.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param line_number Line number to clear
*/
extern void eic_clear_interrupt_line(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Tells whether an EIC interrupt line is pending.
*
* \param eic Base address of the EIC module
* \param line_number Line number to test
*
* \return Whether an EIC interrupt line is pending.
*/
extern Bool eic_is_interrupt_line_pending(volatile avr32_eic_t *eic, unsigned int line_number);
/*! \brief Enable the interrupt scan feature of the EIC.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
* \param presc Prescale select for the keypad scan rate in the range [0,31].
*/
extern void eic_enable_interrupt_scan(volatile avr32_eic_t *eic, unsigned int presc);
/*! \brief Disable the interrupt scan feature of the EIC.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
*/
extern void eic_disable_interrupt_scan(volatile avr32_eic_t *eic);
/*! \brief Return scan pad number that causes interrupt.
*
* \param eic Base address of the EIC (i.e. &AVR32_EIC).
*/
extern unsigned long eic_get_interrupt_pad_scan(volatile avr32_eic_t *eic);
//! @}
#endif // _EIC_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief GPIO driver for AVR32 UC3.
*
* This file defines a useful set of functions for the GPIO.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a GPIO module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "gpio.h"
//! GPIO module instance.
#define GPIO AVR32_GPIO
/*! \name Peripheral Bus Interface
*/
//! @{
int gpio_enable_module(const gpio_map_t gpiomap, unsigned int size)
{
int status = GPIO_SUCCESS;
unsigned int i;
for (i = 0; i < size; i++)
{
status |= gpio_enable_module_pin(gpiomap->pin, gpiomap->function);
gpiomap++;
}
return status;
}
int gpio_enable_module_pin(unsigned int pin, unsigned int function)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
// Enable the correct function.
switch (function)
{
case 0: // A function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
case 1: // B function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
case 2: // C function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
case 3: // D function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pmr2c = 1 << (pin & 0x1F);
#endif
break;
#if defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
case 4: // E function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
case 5: // F function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1c = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
case 6: // G function.
gpio_port->pmr0c = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
case 7: // H function.
gpio_port->pmr0s = 1 << (pin & 0x1F);
gpio_port->pmr1s = 1 << (pin & 0x1F);
gpio_port->pmr2s = 1 << (pin & 0x1F);
break;
#endif
default:
return GPIO_INVALID_ARGUMENT;
}
// Disable GPIO control.
gpio_port->gperc = 1 << (pin & 0x1F);
return GPIO_SUCCESS;
}
void gpio_enable_gpio(const gpio_map_t gpiomap, unsigned int size)
{
unsigned int i;
for (i = 0; i < size; i++)
{
gpio_enable_gpio_pin(gpiomap->pin);
gpiomap++;
}
}
void gpio_enable_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->oderc = 1 << (pin & 0x1F);
gpio_port->gpers = 1 << (pin & 0x1F);
}
// The open-drain mode is not synthesized on the current AVR32 products.
// If one day some AVR32 products have this feature, the corresponding part
// numbers should be listed in the #if below.
// Note that other functions are available in this driver to use pins with open
// drain in GPIO mode. The advantage of the open-drain mode functions over these
// other functions is that they can be used not only in GPIO mode but also in
// module mode.
#if 0
void gpio_enable_pin_open_drain(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->odmers = 1 << (pin & 0x1F);
}
void gpio_disable_pin_open_drain(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->odmerc = 1 << (pin & 0x1F);
}
#endif
void gpio_enable_pin_pull_up(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puers = 1 << (pin & 0x1F);
#if defined(AVR32_GPIO_200_H_INCLUDED) || defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
gpio_port->pderc = 1 << (pin & 0x1F);
#endif
}
void gpio_disable_pin_pull_up(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puerc = 1 << (pin & 0x1F);
}
#if defined(AVR32_GPIO_200_H_INCLUDED) || defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
// Added support of Pull-up Resistor, Pull-down Resistor and Buskeeper Control.
/*! \brief Enables the pull-down resistor of a pin.
*
* \param pin The pin number.
*/
void gpio_enable_pin_pull_down(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puerc = 1 << (pin & 0x1F);
gpio_port->pders = 1 << (pin & 0x1F);
}
/*! \brief Disables the pull-down resistor of a pin.
*
* \param pin The pin number.
*/
void gpio_disable_pin_pull_down(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->pderc = 1 << (pin & 0x1F);
}
/*! \brief Enables the buskeeper functionality on a pin.
*
* \param pin The pin number.
*/
void gpio_enable_pin_buskeeper(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puers = 1 << (pin & 0x1F);
gpio_port->pders = 1 << (pin & 0x1F);
}
/*! \brief Disables the buskeeper functionality on a pin.
*
* \param pin The pin number.
*/
void gpio_disable_pin_buskeeper(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->puerc = 1 << (pin & 0x1F);
gpio_port->pderc = 1 << (pin & 0x1F);
}
#endif
int gpio_get_pin_value(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return (gpio_port->pvr >> (pin & 0x1F)) & 1;
}
int gpio_get_gpio_pin_output_value(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return (gpio_port->ovr >> (pin & 0x1F)) & 1;
}
int gpio_get_gpio_open_drain_pin_output_value(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return ((gpio_port->oder >> (pin & 0x1F)) & 1) ^ 1;
}
void gpio_set_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrs = 1 << (pin & 0x1F); // Value to be driven on the I/O line: 1.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_clr_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrc = 1 << (pin & 0x1F); // Value to be driven on the I/O line: 0.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_tgl_gpio_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrt = 1 << (pin & 0x1F); // Toggle the I/O line.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_set_gpio_open_drain_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->oderc = 1 << (pin & 0x1F); // The GPIO output driver is disabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_clr_gpio_open_drain_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrc = 1 << (pin & 0x1F); // Value to be driven on the I/O line: 0.
gpio_port->oders = 1 << (pin & 0x1F); // The GPIO output driver is enabled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_tgl_gpio_open_drain_pin(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ovrc = 1 << (pin & 0x1F); // Value to be driven on the I/O line if the GPIO output driver is enabled: 0.
gpio_port->odert = 1 << (pin & 0x1F); // The GPIO output driver is toggled for that pin.
gpio_port->gpers = 1 << (pin & 0x1F); // The GPIO module controls that pin.
}
void gpio_enable_pin_glitch_filter(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->gfers = 1 << (pin & 0x1F);
}
void gpio_disable_pin_glitch_filter(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->gferc = 1 << (pin & 0x1F);
}
/*! \brief Configure the edge detector of an input pin
*
* \param pin The pin number.
* \param mode The edge detection mode (\ref GPIO_PIN_CHANGE, \ref GPIO_RISING_EDGE
* or \ref GPIO_FALLING_EDGE).
*
* \return \ref GPIO_SUCCESS or \ref GPIO_INVALID_ARGUMENT.
*/
static int gpio_configure_edge_detector(unsigned int pin, unsigned int mode)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
// Configure the edge detector.
switch (mode)
{
case GPIO_PIN_CHANGE:
gpio_port->imr0c = 1 << (pin & 0x1F);
gpio_port->imr1c = 1 << (pin & 0x1F);
break;
case GPIO_RISING_EDGE:
gpio_port->imr0s = 1 << (pin & 0x1F);
gpio_port->imr1c = 1 << (pin & 0x1F);
break;
case GPIO_FALLING_EDGE:
gpio_port->imr0c = 1 << (pin & 0x1F);
gpio_port->imr1s = 1 << (pin & 0x1F);
break;
default:
return GPIO_INVALID_ARGUMENT;
}
return GPIO_SUCCESS;
}
int gpio_enable_pin_interrupt(unsigned int pin, unsigned int mode)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
// Enable the glitch filter.
gpio_port->gfers = 1 << (pin & 0x1F);
// Configure the edge detector.
if(GPIO_INVALID_ARGUMENT == gpio_configure_edge_detector(pin, mode))
return(GPIO_INVALID_ARGUMENT);
// Enable interrupt.
gpio_port->iers = 1 << (pin & 0x1F);
return GPIO_SUCCESS;
}
void gpio_disable_pin_interrupt(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ierc = 1 << (pin & 0x1F);
}
int gpio_get_pin_interrupt_flag(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
return (gpio_port->ifr >> (pin & 0x1F)) & 1;
}
void gpio_clear_pin_interrupt_flag(unsigned int pin)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
gpio_port->ifrc = 1 << (pin & 0x1F);
}
//#
//# Peripheral Event System Support.
//#
#if UC3L
int gpio_configure_pin_periph_event_mode(unsigned int pin, unsigned int mode, unsigned int use_igf)
{
volatile avr32_gpio_port_t *gpio_port = &GPIO.port[pin >> 5];
if(TRUE == use_igf)
{
// Enable the glitch filter.
gpio_port->gfers = 1 << (pin & 0x1F);
}
else
{
// Disable the glitch filter.
gpio_port->gferc = 1 << (pin & 0x1F);
}
// Configure the edge detector.
return(gpio_configure_edge_detector(pin, mode));
}
#endif
//! @}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief GPIO header for AVR32 UC3.
*
* This file contains basic GPIO driver functions.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a GPIO module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _GPIO_H_
#define _GPIO_H_
#include <avr32/io.h>
#include "compiler.h"
/*! \name Return Values of the GPIO API
*/
//! @{
#define GPIO_SUCCESS 0 //!< Function successfully completed.
#define GPIO_INVALID_ARGUMENT 1 //!< Input parameters are out of range.
//! @}
/*! \name Interrupt Trigger Modes
*/
//! @{
#define GPIO_PIN_CHANGE 0 //!< Interrupt triggered upon pin change.
#define GPIO_RISING_EDGE 1 //!< Interrupt triggered upon rising edge.
#define GPIO_FALLING_EDGE 2 //!< Interrupt triggered upon falling edge.
//! @}
//! A type definition of pins and modules connectivity.
typedef struct
{
unsigned char pin; //!< Module pin.
unsigned char function; //!< Module function.
} gpio_map_t[];
/*! \name Peripheral Bus Interface
*
* Low-speed interface with a non-deterministic number of clock cycles per
* access.
*
* This interface operates with lower clock frequencies (fPB <= fCPU), and its
* timing is not deterministic since it needs to access a shared bus which may
* be heavily loaded.
*
* \note This interface is immediately available without initialization.
*/
//! @{
/*! \brief Enables specific module modes for a set of pins.
*
* \param gpiomap The pin map.
* \param size The number of pins in \a gpiomap.
*
* \return \ref GPIO_SUCCESS or \ref GPIO_INVALID_ARGUMENT.
*/
extern int gpio_enable_module(const gpio_map_t gpiomap, unsigned int size);
/*! \brief Enables a specific module mode for a pin.
*
* \param pin The pin number.\n
* Refer to the product header file `uc3x.h' (where x is the part
* number; e.g. x = a0512) for module pins. E.g., to enable a PWM
* channel output, the pin number can be AVR32_PWM_3_PIN for PWM
* channel 3.
* \param function The pin function.\n
* Refer to the product header file `uc3x.h' (where x is the
* part number; e.g. x = a0512) for module pin functions. E.g.,
* to enable a PWM channel output, the pin function can be
* AVR32_PWM_3_FUNCTION for PWM channel 3.
*
* \return \ref GPIO_SUCCESS or \ref GPIO_INVALID_ARGUMENT.
*/
extern int gpio_enable_module_pin(unsigned int pin, unsigned int function);
/*! \brief Enables the GPIO mode of a set of pins.
*
* \param gpiomap The pin map.
* \param size The number of pins in \a gpiomap.
*/
extern void gpio_enable_gpio(const gpio_map_t gpiomap, unsigned int size);
/*! \brief Enables the GPIO mode of a pin.
*
* \param pin The pin number.\n
* Refer to the product header file `uc3x.h' (where x is the part
* number; e.g. x = a0512) for pin definitions. E.g., to enable the
* GPIO mode of PX21, AVR32_PIN_PX21 can be used. Module pins such as
* AVR32_PWM_3_PIN for PWM channel 3 can also be used to release
* module pins for GPIO.
*/
extern void gpio_enable_gpio_pin(unsigned int pin);
// The open-drain mode is not synthesized on the current AVR32 products.
// If one day some AVR32 products have this feature, the corresponding part
// numbers should be listed in the #if below.
// Note that other functions are available in this driver to use pins with open
// drain in GPIO mode. The advantage of the open-drain mode functions over these
// other functions is that they can be used not only in GPIO mode but also in
// module mode.
#if 0
/*! \brief Enables the open-drain mode of a pin.
*
* \param pin The pin number.
*/
extern void gpio_enable_pin_open_drain(unsigned int pin);
/*! \brief Disables the open-drain mode of a pin.
*
* \param pin The pin number.
*/
extern void gpio_disable_pin_open_drain(unsigned int pin);
#endif
/*! \brief Enables the pull-up resistor of a pin.
*
* \param pin The pin number.
*/
extern void gpio_enable_pin_pull_up(unsigned int pin);
/*! \brief Disables the pull-up resistor of a pin.
*
* \param pin The pin number.
*/
extern void gpio_disable_pin_pull_up(unsigned int pin);
#if defined(AVR32_GPIO_200_H_INCLUDED) || defined(AVR32_GPIO_210_H_INCLUDED) || defined(AVR32_GPIO_211_H_INCLUDED)
// Added support of Pull-up Resistor, Pull-down Resistor and Buskeeper Control.
/*! \brief Enables the pull-down resistor of a pin.
*
* \param pin The pin number.
*/
extern void gpio_enable_pin_pull_down(unsigned int pin);
/*! \brief Disables the pull-down resistor of a pin.
*
* \param pin The pin number.
*/
extern void gpio_disable_pin_pull_down(unsigned int pin);
/*! \brief Enables the buskeeper functionality on a pin.
*
* \param pin The pin number.
*/
extern void gpio_enable_pin_buskeeper(unsigned int pin);
/*! \brief Disables the buskeeper functionality on a pin.
*
* \param pin The pin number.
*/
extern void gpio_disable_pin_buskeeper(unsigned int pin);
#endif
/*! \brief Returns the value of a pin.
*
* \param pin The pin number.
*
* \return The pin value.
*/
extern int gpio_get_pin_value(unsigned int pin);
/*! \brief Returns the output value set for a GPIO pin.
*
* \param pin The pin number.
*
* \return The pin output value.
*
* \note This function must be used in conjunction with \ref gpio_set_gpio_pin,
* \ref gpio_clr_gpio_pin and \ref gpio_tgl_gpio_pin.
*/
extern int gpio_get_gpio_pin_output_value(unsigned int pin);
/*! \brief Returns the output value set for a GPIO pin using open drain.
*
* \param pin The pin number.
*
* \return The pin output value.
*
* \note This function must be used in conjunction with
* \ref gpio_set_gpio_open_drain_pin, \ref gpio_clr_gpio_open_drain_pin
* and \ref gpio_tgl_gpio_open_drain_pin.
*/
extern int gpio_get_gpio_open_drain_pin_output_value(unsigned int pin);
/*! \brief Drives a GPIO pin to 1.
*
* \param pin The pin number.
*/
extern void gpio_set_gpio_pin(unsigned int pin);
/*! \brief Drives a GPIO pin to 0.
*
* \param pin The pin number.
*/
extern void gpio_clr_gpio_pin(unsigned int pin);
/*! \brief Toggles a GPIO pin.
*
* \param pin The pin number.
*/
extern void gpio_tgl_gpio_pin(unsigned int pin);
/*! \brief Drives a GPIO pin to 1 using open drain.
*
* \param pin The pin number.
*/
extern void gpio_set_gpio_open_drain_pin(unsigned int pin);
/*! \brief Drives a GPIO pin to 0 using open drain.
*
* \param pin The pin number.
*/
extern void gpio_clr_gpio_open_drain_pin(unsigned int pin);
/*! \brief Toggles a GPIO pin using open drain.
*
* \param pin The pin number.
*/
extern void gpio_tgl_gpio_open_drain_pin(unsigned int pin);
/*! \brief Enables the glitch filter of a pin.
*
* When the glitch filter is enabled, a glitch with duration of less than 1
* clock cycle is automatically rejected, while a pulse with duration of 2 clock
* cycles or more is accepted. For pulse durations between 1 clock cycle and 2
* clock cycles, the pulse may or may not be taken into account, depending on
* the precise timing of its occurrence. Thus for a pulse to be guaranteed
* visible it must exceed 2 clock cycles, whereas for a glitch to be reliably
* filtered out, its duration must not exceed 1 clock cycle. The filter
* introduces 2 clock cycles latency.
*
* \param pin The pin number.
*/
extern void gpio_enable_pin_glitch_filter(unsigned int pin);
/*! \brief Disables the glitch filter of a pin.
*
* \param pin The pin number.
*/
extern void gpio_disable_pin_glitch_filter(unsigned int pin);
/*! \brief Enables the interrupt of a pin with the specified settings.
*
* \param pin The pin number.
* \param mode The trigger mode (\ref GPIO_PIN_CHANGE, \ref GPIO_RISING_EDGE or
* \ref GPIO_FALLING_EDGE).
*
* \return \ref GPIO_SUCCESS or \ref GPIO_INVALID_ARGUMENT.
*/
extern int gpio_enable_pin_interrupt(unsigned int pin, unsigned int mode);
/*! \brief Disables the interrupt of a pin.
*
* \param pin The pin number.
*/
extern void gpio_disable_pin_interrupt(unsigned int pin);
/*! \brief Gets the interrupt flag of a pin.
*
* \param pin The pin number.
*
* \return The pin interrupt flag.
*/
extern int gpio_get_pin_interrupt_flag(unsigned int pin);
/*! \brief Clears the interrupt flag of a pin.
*
* \param pin The pin number.
*/
extern void gpio_clear_pin_interrupt_flag(unsigned int pin);
//! @}
#if (defined AVR32_GPIO_LOCAL_ADDRESS)
/*! \name Local Bus Interface
*
* High-speed interface with only one clock cycle per access.
*
* This interface operates with high clock frequency (fCPU), and its timing is
* deterministic since it does not need to access a shared bus which may be
* heavily loaded.
*
* \warning To use this interface, the clock frequency of the peripheral bus on
* which the GPIO peripheral is connected must be set to the CPU clock
* frequency (fPB = fCPU).
*
* \note This interface has to be initialized in order to be available.
*/
//! @{
/*! \brief Enables the local bus interface for GPIO.
*
* \note This function must have been called at least once before using other
* functions in this interface.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_init(void)
{
Set_system_register(AVR32_CPUCR,
Get_system_register(AVR32_CPUCR) | AVR32_CPUCR_LOCEN_MASK);
}
/*! \brief Enables the output driver of a pin.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init must have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin.
* \ref gpio_enable_gpio_pin can be called for this purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_enable_pin_output_driver(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].oders = 1 << (pin & 0x1F);
}
/*! \brief Disables the output driver of a pin.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init must have been called beforehand.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_disable_pin_output_driver(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].oderc = 1 << (pin & 0x1F);
}
/*! \brief Returns the value of a pin.
*
* \param pin The pin number.
*
* \return The pin value.
*
* \note \ref gpio_local_init must have been called beforehand.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ int gpio_local_get_pin_value(unsigned int pin)
{
return (AVR32_GPIO_LOCAL.port[pin >> 5].pvr >> (pin & 0x1F)) & 1;
}
/*! \brief Drives a GPIO pin to 1.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init must have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin nor its output
* driver. \ref gpio_enable_gpio_pin and
* \ref gpio_local_enable_pin_output_driver can be called for this
* purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_set_gpio_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].ovrs = 1 << (pin & 0x1F);
}
/*! \brief Drives a GPIO pin to 0.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init must have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin nor its output
* driver. \ref gpio_enable_gpio_pin and
* \ref gpio_local_enable_pin_output_driver can be called for this
* purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_clr_gpio_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].ovrc = 1 << (pin & 0x1F);
}
/*! \brief Toggles a GPIO pin.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init must have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin nor its output
* driver. \ref gpio_enable_gpio_pin and
* \ref gpio_local_enable_pin_output_driver can be called for this
* purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_tgl_gpio_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].ovrt = 1 << (pin & 0x1F);
}
/*! \brief Initializes the configuration of a GPIO pin so that it can be used
* with GPIO open-drain functions.
*
* \note This function must have been called at least once before using
* \ref gpio_local_set_gpio_open_drain_pin,
* \ref gpio_local_clr_gpio_open_drain_pin or
* \ref gpio_local_tgl_gpio_open_drain_pin.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_init_gpio_open_drain_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].ovrc = 1 << (pin & 0x1F);
}
/*! \brief Drives a GPIO pin to 1 using open drain.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init and \ref gpio_local_init_gpio_open_drain_pin must
* have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin.
* \ref gpio_enable_gpio_pin can be called for this purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_set_gpio_open_drain_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].oderc = 1 << (pin & 0x1F);
}
/*! \brief Drives a GPIO pin to 0 using open drain.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init and \ref gpio_local_init_gpio_open_drain_pin must
* have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin.
* \ref gpio_enable_gpio_pin can be called for this purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_clr_gpio_open_drain_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].oders = 1 << (pin & 0x1F);
}
/*! \brief Toggles a GPIO pin using open drain.
*
* \param pin The pin number.
*
* \note \ref gpio_local_init and \ref gpio_local_init_gpio_open_drain_pin must
* have been called beforehand.
*
* \note This function does not enable the GPIO mode of the pin.
* \ref gpio_enable_gpio_pin can be called for this purpose.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_local_tgl_gpio_open_drain_pin(unsigned int pin)
{
AVR32_GPIO_LOCAL.port[pin >> 5].odert = 1 << (pin & 0x1F);
}
//! @}
#endif // AVR32_GPIO_LOCAL_ADDRESS
#if UC3L
//! @{
/*! \name Peripheral Event System support
*
* The GPIO can be programmed to output peripheral events whenever an interrupt
* condition is detected, such as pin value change, or only when a rising or
* falling edge is detected.
*
*/
/*! \brief Enables the peripheral event generation of a pin.
*
* \param pin The pin number.
*
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_enable_pin_periph_event(unsigned int pin)
{
AVR32_GPIO.port[pin >> 5].oderc = 1 << (pin & 0x1F); // The GPIO output driver is disabled for that pin.
AVR32_GPIO.port[pin >> 5].evers = 1 << (pin & 0x1F);
}
/*! \brief Disables the peripheral event generation of a pin.
*
* \param pin The pin number.
*
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ void gpio_disable_pin_periph_event(unsigned int pin)
{
AVR32_GPIO.port[pin >> 5].everc = 1 << (pin & 0x1F);
}
/*! \brief Configure the peripheral event trigger mode of a pin
*
* \param pin The pin number.
* \param mode The trigger mode (\ref GPIO_PIN_CHANGE, \ref GPIO_RISING_EDGE or
* \ref GPIO_FALLING_EDGE).
* \param use_igf use the Input Glitch Filter (TRUE) or not (FALSE).
*
* \return \ref GPIO_SUCCESS or \ref GPIO_INVALID_ARGUMENT.
*/
extern int gpio_configure_pin_periph_event_mode(unsigned int pin, unsigned int mode, unsigned int use_igf);
//! @}
#endif
#endif // _GPIO_H_

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/* This file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Exception and interrupt vectors.
*
* This file maps all events supported by an AVR32.
*
* - Compiler: GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an INTC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#if !__AVR32_UC__ && !__AVR32_AP__
#error Implementation of the AVR32 architecture not supported by the INTC driver.
#endif
#include <avr32/io.h>
//! @{
//! \verbatim
.section .exception, "ax", @progbits
// Start of Exception Vector Table.
// EVBA must be aligned with a power of two strictly greater than the EVBA-
// relative offset of the last vector.
.balign 0x200
// Export symbol.
.global _evba
.type _evba, @function
_evba:
.org 0x000
// Unrecoverable Exception.
_handle_Unrecoverable_Exception:
rjmp $
.org 0x004
// TLB Multiple Hit.
_handle_TLB_Multiple_Hit:
rjmp $
.org 0x008
// Bus Error Data Fetch.
_handle_Bus_Error_Data_Fetch:
rjmp $
.org 0x00C
// Bus Error Instruction Fetch.
_handle_Bus_Error_Instruction_Fetch:
rjmp $
.org 0x010
// NMI.
_handle_NMI:
rjmp $
.org 0x014
// Instruction Address.
_handle_Instruction_Address:
rjmp $
.org 0x018
// ITLB Protection.
_handle_ITLB_Protection:
rjmp $
.org 0x01C
// Breakpoint.
_handle_Breakpoint:
rjmp $
.org 0x020
// Illegal Opcode.
_handle_Illegal_Opcode:
rjmp $
.org 0x024
// Unimplemented Instruction.
_handle_Unimplemented_Instruction:
rjmp $
.org 0x028
// Privilege Violation.
_handle_Privilege_Violation:
rjmp $
.org 0x02C
// Floating-Point: UNUSED IN AVR32UC and AVR32AP.
_handle_Floating_Point:
rjmp $
.org 0x030
// Coprocessor Absent: UNUSED IN AVR32UC.
_handle_Coprocessor_Absent:
rjmp $
.org 0x034
// Data Address (Read).
_handle_Data_Address_Read:
rjmp $
.org 0x038
// Data Address (Write).
_handle_Data_Address_Write:
rjmp $
.org 0x03C
// DTLB Protection (Read).
_handle_DTLB_Protection_Read:
rjmp $
.org 0x040
// DTLB Protection (Write).
_handle_DTLB_Protection_Write:
rjmp $
.org 0x044
// DTLB Modified: UNUSED IN AVR32UC.
_handle_DTLB_Modified:
rjmp $
.org 0x050
// ITLB Miss.
_handle_ITLB_Miss:
rjmp $
.org 0x060
// DTLB Miss (Read).
_handle_DTLB_Miss_Read:
rjmp $
.org 0x070
// DTLB Miss (Write).
_handle_DTLB_Miss_Write:
rjmp $
.org 0x100
// Supervisor Call.
_handle_Supervisor_Call:
rjmp $
// Interrupt support.
// The interrupt controller must provide the offset address relative to EVBA.
// Important note:
// All interrupts call a C function named _get_interrupt_handler.
// This function will read group and interrupt line number to then return in
// R12 a pointer to a user-provided interrupt handler.
.balign 4
.irp priority, 0, 1, 2, 3
_int\priority:
#if __AVR32_UC__
// R8-R12, LR, PC and SR are automatically pushed onto the system stack by the
// CPU upon interrupt entry. No other register is saved by hardware.
#elif __AVR32_AP__
// PC and SR are automatically saved in respectively RAR_INTx and RSR_INTx by
// the CPU upon interrupt entry. No other register is saved by hardware.
pushm r8-r12, lr
#endif
mov r12, \priority // Pass the int_level parameter to the _get_interrupt_handler function.
call _get_interrupt_handler
cp.w r12, 0 // Get the pointer to the interrupt handler returned by the function.
#if __AVR32_UC__
movne pc, r12 // If this was not a spurious interrupt (R12 != NULL), jump to the handler.
#elif __AVR32_AP__
breq spint\priority // If this was a spurious interrupt (R12 == NULL), branch.
st.w --sp, r12 // Push the pointer to the interrupt handler onto the system stack since no register may be altered.
popm r8-r12, lr, pc // Restore registers and jump to the handler.
spint\priority:
popm r8-r12, lr
#endif
rete // If this was a spurious interrupt (R12 == NULL), return from event handler.
.endr
// Constant data area.
.balign 4
// Values to store in the interrupt priority registers for the various interrupt priority levels.
// The interrupt priority registers contain the interrupt priority level and
// the EVBA-relative interrupt vector offset.
.global ipr_val
.type ipr_val, @object
ipr_val:
.word (AVR32_INTC_INT0 << AVR32_INTC_IPR_INTLEVEL_OFFSET) | (_int0 - _evba),\
(AVR32_INTC_INT1 << AVR32_INTC_IPR_INTLEVEL_OFFSET) | (_int1 - _evba),\
(AVR32_INTC_INT2 << AVR32_INTC_IPR_INTLEVEL_OFFSET) | (_int2 - _evba),\
(AVR32_INTC_INT3 << AVR32_INTC_IPR_INTLEVEL_OFFSET) | (_int3 - _evba)
//! \endverbatim
//! @}

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief INTC driver for AVR32 UC3.
*
* AVR32 Interrupt Controller driver module.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an INTC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <avr32/io.h>
#include "compiler.h"
#include "preprocessor.h"
#include "intc.h"
// define _evba from exception.S
extern void _evba;
//! Values to store in the interrupt priority registers for the various interrupt priority levels.
extern const unsigned int ipr_val[AVR32_INTC_NUM_INT_LEVELS];
//! Creates a table of interrupt line handlers per interrupt group in order to optimize RAM space.
//! Each line handler table contains a set of pointers to interrupt handlers.
#if (defined __GNUC__)
#define DECL_INT_LINE_HANDLER_TABLE(GRP, unused) \
static volatile __int_handler _int_line_handler_table_##GRP[Max(AVR32_INTC_NUM_IRQS_PER_GRP##GRP, 1)];
#elif (defined __ICCAVR32__)
#define DECL_INT_LINE_HANDLER_TABLE(GRP, unused) \
static volatile __no_init __int_handler _int_line_handler_table_##GRP[Max(AVR32_INTC_NUM_IRQS_PER_GRP##GRP, 1)];
#endif
MREPEAT(AVR32_INTC_NUM_INT_GRPS, DECL_INT_LINE_HANDLER_TABLE, ~);
#undef DECL_INT_LINE_HANDLER_TABLE
//! Table containing for each interrupt group the number of interrupt request
//! lines and a pointer to the table of interrupt line handlers.
static const struct
{
unsigned int num_irqs;
volatile __int_handler *_int_line_handler_table;
} _int_handler_table[AVR32_INTC_NUM_INT_GRPS] =
{
#define INSERT_INT_LINE_HANDLER_TABLE(GRP, unused) \
{AVR32_INTC_NUM_IRQS_PER_GRP##GRP, _int_line_handler_table_##GRP},
MREPEAT(AVR32_INTC_NUM_INT_GRPS, INSERT_INT_LINE_HANDLER_TABLE, ~)
#undef INSERT_INT_LINE_HANDLER_TABLE
};
/*! \brief Default interrupt handler.
*
* \note Taken and adapted from Newlib.
*/
#if (defined __GNUC__)
__attribute__((__interrupt__))
#elif (defined __ICCAVR32__)
__interrupt
#endif
static void _unhandled_interrupt(void)
{
// Catch unregistered interrupts.
while (TRUE);
}
/*! \brief Gets the interrupt handler of the current event at the \a int_level
* interrupt priority level (called from exception.S).
*
* \param int_level Interrupt priority level to handle.
*
* \return Interrupt handler to execute.
*
* \note Taken and adapted from Newlib.
*/
__int_handler _get_interrupt_handler(unsigned int int_level)
{
// ICR3 is mapped first, ICR0 last.
// Code in exception.S puts int_level in R12 which is used by AVR32-GCC to
// pass a single argument to a function.
unsigned int int_grp = AVR32_INTC.icr[AVR32_INTC_INT3 - int_level];
unsigned int int_req = AVR32_INTC.irr[int_grp];
// As an interrupt may disappear while it is being fetched by the CPU
// (spurious interrupt caused by a delayed response from an MCU peripheral to
// an interrupt flag clear or interrupt disable instruction), check if there
// are remaining interrupt lines to process.
// If a spurious interrupt occurs, the status register (SR) contains an
// execution mode and interrupt level masks corresponding to a level 0
// interrupt, whatever the interrupt priority level causing the spurious
// event. This behavior has been chosen because a spurious interrupt has not
// to be a priority one and because it may not cause any trouble to other
// interrupts.
// However, these spurious interrupts place the hardware in an unstable state
// and could give problems in other/future versions of the CPU, so the
// software has to be written so that they never occur. The only safe way of
// achieving this is to always clear or disable peripheral interrupts with the
// following sequence:
// 1: Mask the interrupt in the CPU by setting GM (or IxM) in SR.
// 2: Perform the bus access to the peripheral register that clears or
// disables the interrupt.
// 3: Wait until the interrupt has actually been cleared or disabled by the
// peripheral. This is usually performed by reading from a register in the
// same peripheral (it DOES NOT have to be the same register that was
// accessed in step 2, but it MUST be in the same peripheral), what takes
// bus system latencies into account, but peripheral internal latencies
// (generally 0 cycle) also have to be considered.
// 4: Unmask the interrupt in the CPU by clearing GM (or IxM) in SR.
// Note that steps 1 and 4 are useless inside interrupt handlers as the
// corresponding interrupt level is automatically masked by IxM (unless IxM is
// explicitly cleared by the software).
//
// Get the right IRQ handler.
//
// If several interrupt lines are active in the group, the interrupt line with
// the highest number is selected. This is to be coherent with the
// prioritization of interrupt groups performed by the hardware interrupt
// controller.
//
// If no handler has been registered for the pending interrupt,
// _unhandled_interrupt will be selected thanks to the initialization of
// _int_line_handler_table_x by INTC_init_interrupts.
//
// exception.S will provide the interrupt handler with a clean interrupt stack
// frame, with nothing more pushed onto the stack. The interrupt handler must
// manage the `rete' instruction, what can be done thanks to pure assembly,
// inline assembly or the `__attribute__((__interrupt__))' C function
// attribute.
return (int_req) ? _int_handler_table[int_grp]._int_line_handler_table[32 - clz(int_req) - 1] : NULL;
}
//! Init EVBA address. This sequence might also be done in the UTILS/STARTUP/GCC/crt0.S
static __inline__ void INTC_init_evba(void)
{
Set_system_register(AVR32_EVBA, (int)&_evba );
}
void INTC_init_interrupts(void)
{
unsigned int int_grp, int_req;
INTC_init_evba();
// For all interrupt groups,
for (int_grp = 0; int_grp < AVR32_INTC_NUM_INT_GRPS; int_grp++)
{
// For all interrupt request lines of each group,
for (int_req = 0; int_req < _int_handler_table[int_grp].num_irqs; int_req++)
{
// Assign _unhandled_interrupt as default interrupt handler.
_int_handler_table[int_grp]._int_line_handler_table[int_req] = &_unhandled_interrupt;
}
// Set the interrupt group priority register to its default value.
// By default, all interrupt groups are linked to the interrupt priority
// level 0 and to the interrupt vector _int0.
AVR32_INTC.ipr[int_grp] = ipr_val[AVR32_INTC_INT0];
}
}
void INTC_register_interrupt(__int_handler handler, unsigned int irq, unsigned int int_level)
{
// Determine the group of the IRQ.
unsigned int int_grp = irq / AVR32_INTC_MAX_NUM_IRQS_PER_GRP;
// Store in _int_line_handler_table_x the pointer to the interrupt handler, so
// that _get_interrupt_handler can retrieve it when the interrupt is vectored.
_int_handler_table[int_grp]._int_line_handler_table[irq % AVR32_INTC_MAX_NUM_IRQS_PER_GRP] = handler;
// Program the corresponding IPRX register to set the interrupt priority level
// and the interrupt vector offset that will be fetched by the core interrupt
// system.
// NOTE: The _intx functions are intermediate assembly functions between the
// core interrupt system and the user interrupt handler.
AVR32_INTC.ipr[int_grp] = ipr_val[int_level & (AVR32_INTC_IPR_INTLEVEL_MASK >> AVR32_INTC_IPR_INTLEVEL_OFFSET)];
}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief INTC driver for AVR32 UC3.
*
* AVR32 Interrupt Controller driver module.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an INTC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _INTC_H_
#define _INTC_H_
#include "compiler.h"
//! Maximal number of interrupt request lines per group.
#define AVR32_INTC_MAX_NUM_IRQS_PER_GRP 32
//! Number of interrupt priority levels.
#define AVR32_INTC_NUM_INT_LEVELS (1 << AVR32_INTC_IPR_INTLEVEL_SIZE)
#ifdef __AVR32_ABI_COMPILER__ // Automatically defined when compiling for AVR32, not when assembling.
//! Pointer to interrupt handler.
#if (defined __GNUC__)
typedef void (*__int_handler)(void);
#elif (defined __ICCAVR32__)
typedef void (__interrupt *__int_handler)(void);
#endif
/*! \brief Initializes the hardware interrupt controller driver.
*
* \note Taken and adapted from Newlib.
*/
extern void INTC_init_interrupts(void);
/*! \brief Registers an interrupt handler.
*
* \param handler Interrupt handler to register.
* \param irq IRQ of the interrupt handler to register.
* \param int_level Interrupt priority level to assign to the group of this IRQ.
*
* \warning The interrupt handler must manage the `rete' instruction, what can
* be done thanks to pure assembly, inline assembly or the
* `__attribute__((__interrupt__))' C function attribute.
*
* \warning If several interrupt handlers of a same group are registered with
* different priority levels, only the latest priority level set will
* be effective.
*
* \note Taken and adapted from Newlib.
*/
extern void INTC_register_interrupt(__int_handler handler, unsigned int irq, unsigned int int_level);
#endif // __AVR32_ABI_COMPILER__
#endif // _INTC_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief PDCA driver for AVR32 UC3.
*
* This file defines a useful set of functions for the PDCA interface on AVR32
* devices.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a PDCA module.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "compiler.h"
#include "pdca.h"
volatile avr32_pdca_channel_t *pdca_get_handler(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = &AVR32_PDCA.channel[pdca_ch_number];
if (pdca_ch_number >= AVR32_PDCA_CHANNEL_LENGTH)
return (volatile avr32_pdca_channel_t *)PDCA_INVALID_ARGUMENT;
return pdca_channel;
}
int pdca_init_channel(unsigned int pdca_ch_number, const pdca_channel_options_t *opt)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_disable_interrupt_transfer_complete(pdca_ch_number); // disable channel interrupt
pdca_disable_interrupt_reload_counter_zero(pdca_ch_number); // disable channel interrupt
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
pdca_channel->mar = (unsigned long)opt->addr;
pdca_channel->tcr = opt->size;
pdca_channel->psr = opt->pid;
pdca_channel->marr = (unsigned long)opt->r_addr;
pdca_channel->tcrr = opt->r_size;
pdca_channel->mr =
#if (defined AVR32_PDCA_120_H_INCLUDED ) || (defined AVR32_PDCA_121_H_INCLUDED ) || (defined AVR32_PDCA_122_H_INCLUDED )
opt->etrig << AVR32_PDCA_ETRIG_OFFSET |
#endif // #ifdef AVR32_PDCA_120_H_INCLUDED
opt->transfer_size << AVR32_PDCA_SIZE_OFFSET;
pdca_channel->cr = AVR32_PDCA_ECLR_MASK;
pdca_channel->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
return PDCA_SUCCESS;
}
unsigned int pdca_get_channel_status(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
return (pdca_channel->sr & AVR32_PDCA_TEN_MASK) != 0;
}
void pdca_disable(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
// Disable transfer
pdca_channel->cr = AVR32_PDCA_TDIS_MASK;
}
void pdca_enable(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
// Enable transfer
pdca_channel->cr = AVR32_PDCA_TEN_MASK;
}
unsigned int pdca_get_load_size(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
return pdca_channel->tcr;
}
void pdca_load_channel(unsigned int pdca_ch_number, volatile void *addr, unsigned int size)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
pdca_channel->mar = (unsigned long)addr;
pdca_channel->tcr = size;
pdca_channel->cr = AVR32_PDCA_ECLR_MASK;
pdca_channel->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
unsigned int pdca_get_reload_size(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
return pdca_channel->tcrr;
}
void pdca_reload_channel(unsigned int pdca_ch_number, volatile void *addr, unsigned int size)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
// set up next memory address
pdca_channel->marr = (unsigned long)addr;
// set up next memory size
pdca_channel->tcrr = size;
pdca_channel->cr = AVR32_PDCA_ECLR_MASK;
pdca_channel->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void pdca_set_peripheral_select(unsigned int pdca_ch_number, unsigned int pid)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->psr = pid;
}
void pdca_set_transfer_size(unsigned int pdca_ch_number, unsigned int transfer_size)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->mr = (pdca_channel->mr & ~AVR32_PDCA_SIZE_MASK) |
transfer_size << AVR32_PDCA_SIZE_OFFSET;
}
#if (defined AVR32_PDCA_120_H_INCLUDED ) || (defined AVR32_PDCA_121_H_INCLUDED ) || (defined AVR32_PDCA_122_H_INCLUDED )
void pdca_disable_event_trigger(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->mr &= ~AVR32_PDCA_ETRIG_MASK;
}
void pdca_enable_event_trigger(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->mr |= AVR32_PDCA_ETRIG_MASK;
}
#endif // #ifdef AVR32_PDCA_120_H_INCLUDED
void pdca_disable_interrupt_transfer_error(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
pdca_channel->idr = AVR32_PDCA_TERR_MASK;
pdca_channel->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void pdca_enable_interrupt_transfer_error(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->ier = AVR32_PDCA_TERR_MASK;
}
void pdca_disable_interrupt_transfer_complete(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
pdca_channel->idr = AVR32_PDCA_TRC_MASK;
pdca_channel->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void pdca_enable_interrupt_transfer_complete(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->ier = AVR32_PDCA_TRC_MASK;
}
void pdca_disable_interrupt_reload_counter_zero(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
pdca_channel->idr = AVR32_PDCA_RCZ_MASK;
pdca_channel->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void pdca_enable_interrupt_reload_counter_zero(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
pdca_channel->ier = AVR32_PDCA_RCZ_MASK;
}
unsigned long pdca_get_transfer_status(unsigned int pdca_ch_number)
{
// get the correct channel pointer
volatile avr32_pdca_channel_t *pdca_channel = pdca_get_handler(pdca_ch_number);
return pdca_channel->isr;
}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief PDCA driver for AVR32 UC3.
*
* This file defines a useful set of functions for the PDCA interface on AVR32
* devices.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a PDCA module.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _PDCA_H_
#define _PDCA_H_
#include <avr32/io.h>
//! Size of PDCA transfer: byte.
#define PDCA_TRANSFER_SIZE_BYTE AVR32_PDCA_BYTE
//! Size of PDCA transfer: half-word.
#define PDCA_TRANSFER_SIZE_HALF_WORD AVR32_PDCA_HALF_WORD
//! Size of PDCA transfer: word.
#define PDCA_TRANSFER_SIZE_WORD AVR32_PDCA_WORD
/*! \name PDCA Driver Status Codes
*/
//! @{
#define PDCA_SUCCESS 0
#define PDCA_INVALID_ARGUMENT -1
//! @}
/*! \name PDCA Transfer Status Codes
*/
//! @{
#define PDCA_TRANSFER_ERROR AVR32_PDCA_TERR_MASK
#define PDCA_TRANSFER_COMPLETE AVR32_PDCA_TRC_MASK
#define PDCA_TRANSFER_COUNTER_RELOAD_IS_ZERO AVR32_PDCA_RCZ_MASK
//! @}
//! PDCA channel options.
typedef struct
{
//! Memory address.
volatile void *addr ;
//! Transfer counter.
unsigned int size ;
//! Next memory address.
volatile void *r_addr ;
//! Next transfer counter.
unsigned int r_size ;
//! Select peripheral ID.
unsigned int pid ;
//! Select the size of the transfer (byte, half-word or word).
unsigned int transfer_size ;
#if (defined AVR32_PDCA_120_H_INCLUDED ) || (defined AVR32_PDCA_121_H_INCLUDED ) || (defined AVR32_PDCA_122_H_INCLUDED )
// Note: the options in this preprocessor section are only available from the PDCA IP version 1.2.0 on.
//! Enable (\c 1) or disable (\c 0) the transfer upon event trigger.
unsigned char etrig ;
#endif // #ifdef AVR32_PDCA_120_H_INCLUDED
} pdca_channel_options_t;
/*! \brief Get PDCA channel handler
*
* \param pdca_ch_number PDCA channel
*
* \return channel handled or PDCA_INVALID_ARGUMENT
*/
extern volatile avr32_pdca_channel_t *pdca_get_handler(unsigned int pdca_ch_number);
/*! \brief Set the channel configuration
*
* \param pdca_ch_number PDCA channel
* \param opt channel option
*/
extern int pdca_init_channel(unsigned int pdca_ch_number, const pdca_channel_options_t *opt);
/*! \brief Get the PDCA channel transfer enable status
*
* \param pdca_ch_number PDCA channel
*
* \return \c 1 if channel transfer is enabled, else \c 0
*/
extern unsigned int pdca_get_channel_status(unsigned int pdca_ch_number);
/*! \brief Disable the PDCA for the given channel
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_disable(unsigned int pdca_ch_number);
/*! \brief Enable the PDCA for the given channel
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_enable(unsigned int pdca_ch_number);
/*! \brief Get PDCA channel load size (or remaining size if transfer started)
*
* \param pdca_ch_number PDCA channel
*
* \return size current size to transfer
*/
extern unsigned int pdca_get_load_size(unsigned int pdca_ch_number);
/*! \brief Set PDCA channel load values
*
* \param pdca_ch_number PDCA channel
* \param addr address where data to load are stored
* \param size size of the data block to load
*/
extern void pdca_load_channel(unsigned int pdca_ch_number, volatile void *addr, unsigned int size);
/*! \brief Get PDCA channel reload size
*
* \param pdca_ch_number PDCA channel
*
* \return size current reload size
*/
extern unsigned int pdca_get_reload_size(unsigned int pdca_ch_number);
/*! \brief Set PDCA channel reload values
*
* \param pdca_ch_number PDCA channel
* \param addr address where data to load are stored
* \param size size of the data block to load
*/
extern void pdca_reload_channel(unsigned int pdca_ch_number, volatile void *addr, unsigned int size);
/*! \brief Set the peripheral function to use with the PDCA channel
*
* \param pdca_ch_number PDCA channel
* \param pid the peripheral ID
*/
extern void pdca_set_peripheral_select(unsigned int pdca_ch_number, unsigned int pid);
/*! \brief Set the size of the transfer
*
* \param pdca_ch_number PDCA channel
* \param transfer_size size of the transfer (byte, half-word or word)
*/
extern void pdca_set_transfer_size(unsigned int pdca_ch_number, unsigned int transfer_size);
#if (defined AVR32_PDCA_120_H_INCLUDED ) || (defined AVR32_PDCA_121_H_INCLUDED ) || (defined AVR32_PDCA_122_H_INCLUDED )
// Note: the functions in this preprocessor section are only available from the PDCA IP version 1.2.0 on.
/*! \brief Disable the event-triggered transfer feature
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_disable_event_trigger(unsigned int pdca_ch_number);
/*! \brief Enable the event-triggered transfer feature
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_enable_event_trigger(unsigned int pdca_ch_number);
#endif // #ifdef AVR32_PDCA_120_H_INCLUDED
/*! \brief Disable PDCA transfer error interrupt
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_disable_interrupt_transfer_error(unsigned int pdca_ch_number);
/*! \brief Enable PDCA transfer error interrupt
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_enable_interrupt_transfer_error(unsigned int pdca_ch_number);
/*! \brief Disable PDCA transfer interrupt when completed (ie TCR and TCRR are both zero)
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_disable_interrupt_transfer_complete(unsigned int pdca_ch_number);
/*! \brief Enable PDCA transfer interrupt when completed (ie TCR and TCRR are both zero)
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_enable_interrupt_transfer_complete(unsigned int pdca_ch_number);
/*! \brief Disable PDCA transfer interrupt when TCRR reaches zero
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_disable_interrupt_reload_counter_zero(unsigned int pdca_ch_number);
/*! \brief Enable PDCA transfer interrupt when TCRR reaches zero
*
* \param pdca_ch_number PDCA channel
*/
extern void pdca_enable_interrupt_reload_counter_zero(unsigned int pdca_ch_number);
/*! \brief Get PDCA channel transfer status
*
* \param pdca_ch_number PDCA channel
*
* \return PDCA transfer status with the following bit-masks:\n
* - \c PDCA_TRANSFER_ERROR;\n
* - \c PDCA_TRANSFER_COMPLETE;\n
* - \c PDCA_TRANSFER_COUNTER_RELOAD_IS_ZERO.
*/
extern unsigned long pdca_get_transfer_status(unsigned int pdca_ch_number);
#endif // _PDCA_H_

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@ -0,0 +1,546 @@
/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Power Manager driver.
*
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "compiler.h"
#include "pm.h"
/*! \name PM Writable Bit-Field Registers
*/
//! @{
typedef union
{
unsigned long mcctrl;
avr32_pm_mcctrl_t MCCTRL;
} u_avr32_pm_mcctrl_t;
typedef union
{
unsigned long cksel;
avr32_pm_cksel_t CKSEL;
} u_avr32_pm_cksel_t;
typedef union
{
unsigned long pll;
avr32_pm_pll_t PLL;
} u_avr32_pm_pll_t;
typedef union
{
unsigned long oscctrl0;
avr32_pm_oscctrl0_t OSCCTRL0;
} u_avr32_pm_oscctrl0_t;
typedef union
{
unsigned long oscctrl1;
avr32_pm_oscctrl1_t OSCCTRL1;
} u_avr32_pm_oscctrl1_t;
typedef union
{
unsigned long oscctrl32;
avr32_pm_oscctrl32_t OSCCTRL32;
} u_avr32_pm_oscctrl32_t;
typedef union
{
unsigned long ier;
avr32_pm_ier_t IER;
} u_avr32_pm_ier_t;
typedef union
{
unsigned long idr;
avr32_pm_idr_t IDR;
} u_avr32_pm_idr_t;
typedef union
{
unsigned long icr;
avr32_pm_icr_t ICR;
} u_avr32_pm_icr_t;
typedef union
{
unsigned long gcctrl;
avr32_pm_gcctrl_t GCCTRL;
} u_avr32_pm_gcctrl_t;
typedef union
{
unsigned long rccr;
avr32_pm_rccr_t RCCR;
} u_avr32_pm_rccr_t;
typedef union
{
unsigned long bgcr;
avr32_pm_bgcr_t BGCR;
} u_avr32_pm_bgcr_t;
typedef union
{
unsigned long vregcr;
avr32_pm_vregcr_t VREGCR;
} u_avr32_pm_vregcr_t;
typedef union
{
unsigned long bod;
avr32_pm_bod_t BOD;
} u_avr32_pm_bod_t;
//! @}
/*! \brief Sets the mode of the oscillator 0.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
* \param mode Oscillator 0 mode (i.e. AVR32_PM_OSCCTRL0_MODE_x).
*/
static void pm_set_osc0_mode(volatile avr32_pm_t *pm, unsigned int mode)
{
// Read
u_avr32_pm_oscctrl0_t u_avr32_pm_oscctrl0 = {pm->oscctrl0};
// Modify
u_avr32_pm_oscctrl0.OSCCTRL0.mode = mode;
// Write
pm->oscctrl0 = u_avr32_pm_oscctrl0.oscctrl0;
}
void pm_enable_osc0_ext_clock(volatile avr32_pm_t *pm)
{
pm_set_osc0_mode(pm, AVR32_PM_OSCCTRL0_MODE_EXT_CLOCK);
}
void pm_enable_osc0_crystal(volatile avr32_pm_t *pm, unsigned int fosc0)
{
pm_set_osc0_mode(pm, (fosc0 < 900000) ? AVR32_PM_OSCCTRL0_MODE_CRYSTAL_G0 :
(fosc0 < 3000000) ? AVR32_PM_OSCCTRL0_MODE_CRYSTAL_G1 :
(fosc0 < 8000000) ? AVR32_PM_OSCCTRL0_MODE_CRYSTAL_G2 :
AVR32_PM_OSCCTRL0_MODE_CRYSTAL_G3);
}
void pm_enable_clk0(volatile avr32_pm_t *pm, unsigned int startup)
{
pm_enable_clk0_no_wait(pm, startup);
pm_wait_for_clk0_ready(pm);
}
void pm_disable_clk0(volatile avr32_pm_t *pm)
{
pm->mcctrl &= ~AVR32_PM_MCCTRL_OSC0EN_MASK;
}
void pm_enable_clk0_no_wait(volatile avr32_pm_t *pm, unsigned int startup)
{
// Read register
u_avr32_pm_oscctrl0_t u_avr32_pm_oscctrl0 = {pm->oscctrl0};
// Modify
u_avr32_pm_oscctrl0.OSCCTRL0.startup = startup;
// Write back
pm->oscctrl0 = u_avr32_pm_oscctrl0.oscctrl0;
pm->mcctrl |= AVR32_PM_MCCTRL_OSC0EN_MASK;
}
void pm_wait_for_clk0_ready(volatile avr32_pm_t *pm)
{
while (!(pm->poscsr & AVR32_PM_POSCSR_OSC0RDY_MASK));
}
/*! \brief Sets the mode of the oscillator 1.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
* \param mode Oscillator 1 mode (i.e. AVR32_PM_OSCCTRL1_MODE_x).
*/
static void pm_set_osc1_mode(volatile avr32_pm_t *pm, unsigned int mode)
{
// Read
u_avr32_pm_oscctrl1_t u_avr32_pm_oscctrl1 = {pm->oscctrl1};
// Modify
u_avr32_pm_oscctrl1.OSCCTRL1.mode = mode;
// Write
pm->oscctrl1 = u_avr32_pm_oscctrl1.oscctrl1;
}
void pm_enable_osc1_ext_clock(volatile avr32_pm_t *pm)
{
pm_set_osc1_mode(pm, AVR32_PM_OSCCTRL1_MODE_EXT_CLOCK);
}
void pm_enable_osc1_crystal(volatile avr32_pm_t *pm, unsigned int fosc1)
{
pm_set_osc1_mode(pm, (fosc1 < 900000) ? AVR32_PM_OSCCTRL1_MODE_CRYSTAL_G0 :
(fosc1 < 3000000) ? AVR32_PM_OSCCTRL1_MODE_CRYSTAL_G1 :
(fosc1 < 8000000) ? AVR32_PM_OSCCTRL1_MODE_CRYSTAL_G2 :
AVR32_PM_OSCCTRL1_MODE_CRYSTAL_G3);
}
void pm_enable_clk1(volatile avr32_pm_t *pm, unsigned int startup)
{
pm_enable_clk1_no_wait(pm, startup);
pm_wait_for_clk1_ready(pm);
}
void pm_disable_clk1(volatile avr32_pm_t *pm)
{
pm->mcctrl &= ~AVR32_PM_MCCTRL_OSC1EN_MASK;
}
void pm_enable_clk1_no_wait(volatile avr32_pm_t *pm, unsigned int startup)
{
// Read register
u_avr32_pm_oscctrl1_t u_avr32_pm_oscctrl1 = {pm->oscctrl1};
// Modify
u_avr32_pm_oscctrl1.OSCCTRL1.startup = startup;
// Write back
pm->oscctrl1 = u_avr32_pm_oscctrl1.oscctrl1;
pm->mcctrl |= AVR32_PM_MCCTRL_OSC1EN_MASK;
}
void pm_wait_for_clk1_ready(volatile avr32_pm_t *pm)
{
while (!(pm->poscsr & AVR32_PM_POSCSR_OSC1RDY_MASK));
}
/*! \brief Sets the mode of the 32-kHz oscillator.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
* \param mode 32-kHz oscillator mode (i.e. AVR32_PM_OSCCTRL32_MODE_x).
*/
static void pm_set_osc32_mode(volatile avr32_pm_t *pm, unsigned int mode)
{
// Read
u_avr32_pm_oscctrl32_t u_avr32_pm_oscctrl32 = {pm->oscctrl32};
// Modify
u_avr32_pm_oscctrl32.OSCCTRL32.mode = mode;
// Write
pm->oscctrl32 = u_avr32_pm_oscctrl32.oscctrl32;
}
void pm_enable_osc32_ext_clock(volatile avr32_pm_t *pm)
{
pm_set_osc32_mode(pm, AVR32_PM_OSCCTRL32_MODE_EXT_CLOCK);
}
void pm_enable_osc32_crystal(volatile avr32_pm_t *pm)
{
pm_set_osc32_mode(pm, AVR32_PM_OSCCTRL32_MODE_CRYSTAL);
}
void pm_enable_clk32(volatile avr32_pm_t *pm, unsigned int startup)
{
pm_enable_clk32_no_wait(pm, startup);
pm_wait_for_clk32_ready(pm);
}
void pm_disable_clk32(volatile avr32_pm_t *pm)
{
pm->oscctrl32 &= ~AVR32_PM_OSCCTRL32_OSC32EN_MASK;
}
void pm_enable_clk32_no_wait(volatile avr32_pm_t *pm, unsigned int startup)
{
// Read register
u_avr32_pm_oscctrl32_t u_avr32_pm_oscctrl32 = {pm->oscctrl32};
// Modify
u_avr32_pm_oscctrl32.OSCCTRL32.osc32en = 1;
u_avr32_pm_oscctrl32.OSCCTRL32.startup = startup;
// Write back
pm->oscctrl32 = u_avr32_pm_oscctrl32.oscctrl32;
}
void pm_wait_for_clk32_ready(volatile avr32_pm_t *pm)
{
while (!(pm->poscsr & AVR32_PM_POSCSR_OSC32RDY_MASK));
}
void pm_cksel(volatile avr32_pm_t *pm,
unsigned int pbadiv,
unsigned int pbasel,
unsigned int pbbdiv,
unsigned int pbbsel,
unsigned int hsbdiv,
unsigned int hsbsel)
{
u_avr32_pm_cksel_t u_avr32_pm_cksel = {0};
u_avr32_pm_cksel.CKSEL.cpusel = hsbsel;
u_avr32_pm_cksel.CKSEL.cpudiv = hsbdiv;
u_avr32_pm_cksel.CKSEL.hsbsel = hsbsel;
u_avr32_pm_cksel.CKSEL.hsbdiv = hsbdiv;
u_avr32_pm_cksel.CKSEL.pbasel = pbasel;
u_avr32_pm_cksel.CKSEL.pbadiv = pbadiv;
u_avr32_pm_cksel.CKSEL.pbbsel = pbbsel;
u_avr32_pm_cksel.CKSEL.pbbdiv = pbbdiv;
pm->cksel = u_avr32_pm_cksel.cksel;
// Wait for ckrdy bit and then clear it
while (!(pm->poscsr & AVR32_PM_POSCSR_CKRDY_MASK));
}
void pm_gc_setup(volatile avr32_pm_t *pm,
unsigned int gc,
unsigned int osc_or_pll, // Use Osc (=0) or PLL (=1)
unsigned int pll_osc, // Sel Osc0/PLL0 or Osc1/PLL1
unsigned int diven,
unsigned int div)
{
u_avr32_pm_gcctrl_t u_avr32_pm_gcctrl = {0};
u_avr32_pm_gcctrl.GCCTRL.oscsel = pll_osc;
u_avr32_pm_gcctrl.GCCTRL.pllsel = osc_or_pll;
u_avr32_pm_gcctrl.GCCTRL.diven = diven;
u_avr32_pm_gcctrl.GCCTRL.div = div;
pm->gcctrl[gc] = u_avr32_pm_gcctrl.gcctrl;
}
void pm_gc_enable(volatile avr32_pm_t *pm,
unsigned int gc)
{
pm->gcctrl[gc] |= AVR32_PM_GCCTRL_CEN_MASK;
}
void pm_gc_disable(volatile avr32_pm_t *pm,
unsigned int gc)
{
pm->gcctrl[gc] &= ~AVR32_PM_GCCTRL_CEN_MASK;
}
void pm_pll_setup(volatile avr32_pm_t *pm,
unsigned int pll,
unsigned int mul,
unsigned int div,
unsigned int osc,
unsigned int lockcount)
{
u_avr32_pm_pll_t u_avr32_pm_pll = {0};
u_avr32_pm_pll.PLL.pllosc = osc;
u_avr32_pm_pll.PLL.plldiv = div;
u_avr32_pm_pll.PLL.pllmul = mul;
u_avr32_pm_pll.PLL.pllcount = lockcount;
pm->pll[pll] = u_avr32_pm_pll.pll;
}
void pm_pll_set_option(volatile avr32_pm_t *pm,
unsigned int pll,
unsigned int pll_freq,
unsigned int pll_div2,
unsigned int pll_wbwdisable)
{
u_avr32_pm_pll_t u_avr32_pm_pll = {pm->pll[pll]};
u_avr32_pm_pll.PLL.pllopt = pll_freq | (pll_div2 << 1) | (pll_wbwdisable << 2);
pm->pll[pll] = u_avr32_pm_pll.pll;
}
unsigned int pm_pll_get_option(volatile avr32_pm_t *pm,
unsigned int pll)
{
return (pm->pll[pll] & AVR32_PM_PLLOPT_MASK) >> AVR32_PM_PLLOPT_OFFSET;
}
void pm_pll_enable(volatile avr32_pm_t *pm,
unsigned int pll)
{
pm->pll[pll] |= AVR32_PM_PLLEN_MASK;
}
void pm_pll_disable(volatile avr32_pm_t *pm,
unsigned int pll)
{
pm->pll[pll] &= ~AVR32_PM_PLLEN_MASK;
}
void pm_wait_for_pll0_locked(volatile avr32_pm_t *pm)
{
while (!(pm->poscsr & AVR32_PM_POSCSR_LOCK0_MASK));
}
void pm_wait_for_pll1_locked(volatile avr32_pm_t *pm)
{
while (!(pm->poscsr & AVR32_PM_POSCSR_LOCK1_MASK));
}
void pm_switch_to_clock(volatile avr32_pm_t *pm, unsigned long clock)
{
// Read
u_avr32_pm_mcctrl_t u_avr32_pm_mcctrl = {pm->mcctrl};
// Modify
u_avr32_pm_mcctrl.MCCTRL.mcsel = clock;
// Write back
pm->mcctrl = u_avr32_pm_mcctrl.mcctrl;
}
void pm_switch_to_osc0(volatile avr32_pm_t *pm, unsigned int fosc0, unsigned int startup)
{
pm_enable_osc0_crystal(pm, fosc0); // Enable the Osc0 in crystal mode
pm_enable_clk0(pm, startup); // Crystal startup time - This parameter is critical and depends on the characteristics of the crystal
pm_switch_to_clock(pm, AVR32_PM_MCSEL_OSC0); // Then switch main clock to Osc0
}
void pm_bod_enable_irq(volatile avr32_pm_t *pm)
{
pm->ier = AVR32_PM_IER_BODDET_MASK;
}
void pm_bod_disable_irq(volatile avr32_pm_t *pm)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
pm->idr = AVR32_PM_IDR_BODDET_MASK;
pm->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void pm_bod_clear_irq(volatile avr32_pm_t *pm)
{
pm->icr = AVR32_PM_ICR_BODDET_MASK;
}
unsigned long pm_bod_get_irq_status(volatile avr32_pm_t *pm)
{
return ((pm->isr & AVR32_PM_ISR_BODDET_MASK) != 0);
}
unsigned long pm_bod_get_irq_enable_bit(volatile avr32_pm_t *pm)
{
return ((pm->imr & AVR32_PM_IMR_BODDET_MASK) != 0);
}
unsigned long pm_bod_get_level(volatile avr32_pm_t *pm)
{
return (pm->bod & AVR32_PM_BOD_LEVEL_MASK) >> AVR32_PM_BOD_LEVEL_OFFSET;
}
unsigned long pm_read_gplp(volatile avr32_pm_t *pm, unsigned long gplp)
{
return pm->gplp[gplp];
}
void pm_write_gplp(volatile avr32_pm_t *pm, unsigned long gplp, unsigned long value)
{
pm->gplp[gplp] = value;
}
long pm_enable_module(volatile avr32_pm_t *pm, unsigned long module)
{
unsigned long domain = module>>5;
unsigned long *regptr = (unsigned long*)(&(pm->cpumask) + domain);
// Implementation-specific shortcut: the ckMASK registers are contiguous and
// memory-mapped in that order: CPUMASK, HSBMASK, PBAMASK, PBBMASK.
*regptr |= (1<<(module%32));
return PASS;
}
long pm_disable_module(volatile avr32_pm_t *pm, unsigned long module)
{
unsigned long domain = module>>5;
unsigned long *regptr = (unsigned long*)(&(pm->cpumask) + domain);
// Implementation-specific shortcut: the ckMASK registers are contiguous and
// memory-mapped in that order: CPUMASK, HSBMASK, PBAMASK, PBBMASK.
*regptr &= ~(1<<(module%32));
return PASS;
}

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@ -0,0 +1,493 @@
/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Power Manager driver.
*
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _PM_H_
#define _PM_H_
#include <avr32/io.h>
#include "compiler.h"
#include "preprocessor.h"
/*! \brief Sets the MCU in the specified sleep mode.
*
* \param mode Sleep mode:
* \arg \c AVR32_PM_SMODE_IDLE: Idle;
* \arg \c AVR32_PM_SMODE_FROZEN: Frozen;
* \arg \c AVR32_PM_SMODE_STANDBY: Standby;
* \arg \c AVR32_PM_SMODE_STOP: Stop;
* \arg \c AVR32_PM_SMODE_DEEP_STOP: DeepStop;
* \arg \c AVR32_PM_SMODE_STATIC: Static.
*/
#define SLEEP(mode) {__asm__ __volatile__ ("sleep "STRINGZ(mode));}
//! Input and output parameters when initializing PM clocks using pm_configure_clocks().
typedef struct
{
//! CPU frequency (input/output argument).
unsigned long cpu_f;
//! PBA frequency (input/output argument).
unsigned long pba_f;
//! Oscillator 0's external crystal(or external clock) frequency (board dependant) (input argument).
unsigned long osc0_f;
//! Oscillator 0's external crystal(or external clock) startup time: AVR32_PM_OSCCTRL0_STARTUP_x_RCOSC (input argument).
unsigned long osc0_startup;
} pm_freq_param_t;
#define PM_FREQ_STATUS_FAIL (-1)
#define PM_FREQ_STATUS_OK (0)
/*! \brief Gets the MCU reset cause.
*
* \param pm Base address of the Power Manager instance (i.e. &AVR32_PM).
*
* \return The MCU reset cause which can be masked with the
* \c AVR32_PM_RCAUSE_x_MASK bit-masks to isolate specific causes.
*/
#if (defined __GNUC__)
__attribute__((__always_inline__))
#endif
extern __inline__ unsigned int pm_get_reset_cause(volatile avr32_pm_t *pm)
{
return pm->rcause;
}
/*!
* \brief This function will enable the external clock mode of the oscillator 0.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_enable_osc0_ext_clock(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the crystal mode of the oscillator 0.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param fosc0 Oscillator 0 crystal frequency (Hz)
*/
extern void pm_enable_osc0_crystal(volatile avr32_pm_t *pm, unsigned int fosc0);
/*!
* \brief This function will enable the oscillator 0 to be used with a startup time.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param startup Clock 0 startup time. AVR32_PM_OSCCTRL0_STARTUP_x_RCOSC.
*/
extern void pm_enable_clk0(volatile avr32_pm_t *pm, unsigned int startup);
/*!
* \brief This function will disable the oscillator 0.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_disable_clk0(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the oscillator 0 to be used with no startup time.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param startup Clock 0 startup time, for which the function does not wait. AVR32_PM_OSCCTRL0_STARTUP_x_RCOSC.
*/
extern void pm_enable_clk0_no_wait(volatile avr32_pm_t *pm, unsigned int startup);
/*!
* \brief This function will wait until the Osc0 clock is ready.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_wait_for_clk0_ready(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the external clock mode of the oscillator 1.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_enable_osc1_ext_clock(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the crystal mode of the oscillator 1.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param fosc1 Oscillator 1 crystal frequency (Hz)
*/
extern void pm_enable_osc1_crystal(volatile avr32_pm_t *pm, unsigned int fosc1);
/*!
* \brief This function will enable the oscillator 1 to be used with a startup time.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param startup Clock 1 startup time. AVR32_PM_OSCCTRL1_STARTUP_x_RCOSC.
*/
extern void pm_enable_clk1(volatile avr32_pm_t *pm, unsigned int startup);
/*!
* \brief This function will disable the oscillator 1.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_disable_clk1(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the oscillator 1 to be used with no startup time.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param startup Clock 1 startup time, for which the function does not wait. AVR32_PM_OSCCTRL1_STARTUP_x_RCOSC.
*/
extern void pm_enable_clk1_no_wait(volatile avr32_pm_t *pm, unsigned int startup);
/*!
* \brief This function will wait until the Osc1 clock is ready.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_wait_for_clk1_ready(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the external clock mode of the 32-kHz oscillator.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_enable_osc32_ext_clock(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the crystal mode of the 32-kHz oscillator.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_enable_osc32_crystal(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the oscillator 32 to be used with a startup time.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param startup Clock 32 kHz startup time. AVR32_PM_OSCCTRL32_STARTUP_x_RCOSC.
*/
extern void pm_enable_clk32(volatile avr32_pm_t *pm, unsigned int startup);
/*!
* \brief This function will disable the oscillator 32.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_disable_clk32(volatile avr32_pm_t *pm);
/*!
* \brief This function will enable the oscillator 32 to be used with no startup time.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param startup Clock 32 kHz startup time, for which the function does not wait. AVR32_PM_OSCCTRL32_STARTUP_x_RCOSC.
*/
extern void pm_enable_clk32_no_wait(volatile avr32_pm_t *pm, unsigned int startup);
/*!
* \brief This function will wait until the osc32 clock is ready.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_wait_for_clk32_ready(volatile avr32_pm_t *pm);
/*!
* \brief This function will select all the power manager clocks.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param pbadiv Peripheral Bus A clock divisor enable
* \param pbasel Peripheral Bus A select
* \param pbbdiv Peripheral Bus B clock divisor enable
* \param pbbsel Peripheral Bus B select
* \param hsbdiv High Speed Bus clock divisor enable (CPU clock = HSB clock)
* \param hsbsel High Speed Bus select (CPU clock = HSB clock )
*/
extern void pm_cksel(volatile avr32_pm_t *pm, unsigned int pbadiv, unsigned int pbasel, unsigned int pbbdiv, unsigned int pbbsel, unsigned int hsbdiv, unsigned int hsbsel);
/*!
* \brief This function will setup a generic clock.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param gc generic clock number (0 for gc0...)
* \param osc_or_pll Use OSC (=0) or PLL (=1)
* \param pll_osc Select Osc0/PLL0 or Osc1/PLL1
* \param diven Generic clock divisor enable
* \param div Generic clock divisor
*/
extern void pm_gc_setup(volatile avr32_pm_t *pm, unsigned int gc, unsigned int osc_or_pll, unsigned int pll_osc, unsigned int diven, unsigned int div);
/*!
* \brief This function will enable a generic clock.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param gc generic clock number (0 for gc0...)
*/
extern void pm_gc_enable(volatile avr32_pm_t *pm, unsigned int gc);
/*!
* \brief This function will disable a generic clock.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param gc generic clock number (0 for gc0...)
*/
extern void pm_gc_disable(volatile avr32_pm_t *pm, unsigned int gc);
/*!
* \brief This function will setup a PLL.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param pll PLL number(0 for PLL0, 1 for PLL1)
* \param mul PLL MUL in the PLL formula
* \param div PLL DIV in the PLL formula
* \param osc OSC number (0 for osc0, 1 for osc1)
* \param lockcount PLL lockount
*/
extern void pm_pll_setup(volatile avr32_pm_t *pm, unsigned int pll, unsigned int mul, unsigned int div, unsigned int osc, unsigned int lockcount);
/*!
* \brief This function will set a PLL option.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param pll PLL number(0 for PLL0, 1 for PLL1)
* \param pll_freq Set to 1 for VCO frequency range 80-180MHz, set to 0 for VCO frequency range 160-240Mhz.
* \param pll_div2 Divide the PLL output frequency by 2 (this settings does not change the FVCO value)
* \param pll_wbwdisable 1 Disable the Wide-Bandith Mode (Wide-Bandwith mode allow a faster startup time and out-of-lock time). 0 to enable the Wide-Bandith Mode.
*/
extern void pm_pll_set_option(volatile avr32_pm_t *pm, unsigned int pll, unsigned int pll_freq, unsigned int pll_div2, unsigned int pll_wbwdisable);
/*!
* \brief This function will get a PLL option.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param pll PLL number(0 for PLL0, 1 for PLL1)
* \return Option
*/
extern unsigned int pm_pll_get_option(volatile avr32_pm_t *pm, unsigned int pll);
/*!
* \brief This function will enable a PLL.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param pll PLL number(0 for PLL0, 1 for PLL1)
*/
extern void pm_pll_enable(volatile avr32_pm_t *pm, unsigned int pll);
/*!
* \brief This function will disable a PLL.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param pll PLL number(0 for PLL0, 1 for PLL1)
*/
extern void pm_pll_disable(volatile avr32_pm_t *pm, unsigned int pll);
/*!
* \brief This function will wait for PLL0 locked
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_wait_for_pll0_locked(volatile avr32_pm_t *pm);
/*!
* \brief This function will wait for PLL1 locked
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
*/
extern void pm_wait_for_pll1_locked(volatile avr32_pm_t *pm);
/*!
* \brief This function will switch the power manager main clock.
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param clock Clock to be switched on. AVR32_PM_MCSEL_SLOW for RCOsc, AVR32_PM_MCSEL_OSC0 for Osc0, AVR32_PM_MCSEL_PLL0 for PLL0.
*/
extern void pm_switch_to_clock(volatile avr32_pm_t *pm, unsigned long clock);
/*!
* \brief Switch main clock to clock Osc0 (crystal mode)
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param fosc0 Oscillator 0 crystal frequency (Hz)
* \param startup Crystal 0 startup time. AVR32_PM_OSCCTRL0_STARTUP_x_RCOSC.
*/
extern void pm_switch_to_osc0(volatile avr32_pm_t *pm, unsigned int fosc0, unsigned int startup);
/*! \brief Enables the Brown-Out Detector interrupt.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
*/
extern void pm_bod_enable_irq(volatile avr32_pm_t *pm);
/*! \brief Disables the Brown-Out Detector interrupt.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
*/
extern void pm_bod_disable_irq(volatile avr32_pm_t *pm);
/*! \brief Clears the Brown-Out Detector interrupt flag.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
*/
extern void pm_bod_clear_irq(volatile avr32_pm_t *pm);
/*! \brief Gets the Brown-Out Detector interrupt flag.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
*
* \retval 0 No BOD interrupt.
* \retval 1 BOD interrupt pending.
*/
extern unsigned long pm_bod_get_irq_status(volatile avr32_pm_t *pm);
/*! \brief Gets the Brown-Out Detector interrupt enable status.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
*
* \retval 0 BOD interrupt disabled.
* \retval 1 BOD interrupt enabled.
*/
extern unsigned long pm_bod_get_irq_enable_bit(volatile avr32_pm_t *pm);
/*! \brief Gets the triggering threshold of the Brown-Out Detector.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM).
*
* \return Triggering threshold of the BOD. See the electrical characteristics
* in the part datasheet for actual voltage levels.
*/
extern unsigned long pm_bod_get_level(volatile avr32_pm_t *pm);
/*!
* \brief Read the content of the PM GPLP registers
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param gplp GPLP register index (0,1,... depending on the number of GPLP registers for a given part)
*
* \return The content of the chosen GPLP register.
*/
extern unsigned long pm_read_gplp(volatile avr32_pm_t *pm, unsigned long gplp);
/*!
* \brief Write into the PM GPLP registers
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param gplp GPLP register index (0,1,... depending on the number of GPLP registers for a given part)
* \param value Value to write
*/
extern void pm_write_gplp(volatile avr32_pm_t *pm, unsigned long gplp, unsigned long value);
/*! \brief Enable the clock of a module.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param module The module to clock (use one of the defines in the part-specific
* header file under "toolchain folder"/avr32/inc(lude)/avr32/; depending on the
* clock domain, look for the sections "CPU clocks", "HSB clocks", "PBx clocks")
*
* \return Status.
* \retval 0 Success.
* \retval <0 An error occured.
*/
extern long pm_enable_module(volatile avr32_pm_t *pm, unsigned long module);
/*! \brief Disable the clock of a module.
*
* \param pm Base address of the Power Manager (i.e. &AVR32_PM)
* \param module The module to shut down (use one of the defines in the part-specific
* header file under "toolchain folder"/avr32/inc(lude)/avr32/; depending on the
* clock domain, look for the sections "CPU clocks", "HSB clocks", "PBx clocks")
*
* \return Status.
* \retval 0 Success.
* \retval <0 An error occured.
*/
extern long pm_disable_module(volatile avr32_pm_t *pm, unsigned long module);
/*! \brief Automatically configure the CPU, PBA, PBB, and HSB clocks
* according to the user wishes.
*
* This function needs some parameters stored in a pm_freq_param_t structure:
* - cpu_f and pba_f are the wanted frequencies,
* - osc0_f is the oscillator 0 on-board frequency (e.g. FOSC0),
* - osc0_startup is the oscillator 0 startup time (e.g. OSC0_STARTUP).
*
* The function will then configure the clocks using the following rules:
* - It first try to find a valid PLL frequency (the highest possible value to avoid jitter) in order
* to satisfy the CPU frequency,
* - It optimizes the configuration depending the various divide stages,
* - Then, the PBA frequency is configured from the CPU freq.
* - Note that HSB and PBB are configured with the same frequency as CPU.
* - Note also that the number of wait states of the flash read accesses is automatically set-up depending
* the CPU frequency. As a consequence, the application needs the FLASHC driver to compile.
*
* The CPU, HSB and PBA frequencies programmed after configuration are stored back into cpu_f and pba_f.
*
* \param param pointer on the configuration structure.
*
* \retval PM_FREQ_STATUS_OK Mode successfully initialized.
* \retval PM_FREQ_STATUS_FAIL The configuration can not be done.
*/
extern int pm_configure_clocks(pm_freq_param_t *param);
/*! \brief Automatically configure the USB clock.
*
* USB clock is configured to 48MHz, using the PLL1 from the Oscillator0, assuming
* a 12 MHz crystal is connected to it.
*/
extern void pm_configure_usb_clock(void);
#endif // _PM_H_

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@ -0,0 +1,268 @@
/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief Power Manager clocks configuration helper.
*
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <string.h>
#include "compiler.h"
#include "pm.h"
extern void flashc_set_wait_state(unsigned int wait_state);
#if (defined AVR32_FLASHC_210_H_INCLUDED)
extern void flashc_issue_command(unsigned int command, int page_number);
#endif
#define PM_MAX_MUL ((1 << AVR32_PM_PLL0_PLLMUL_SIZE) - 1)
int pm_configure_clocks(pm_freq_param_t *param)
{
// Supported frequencies:
// Fosc0 mul div PLL div2_en cpu_f pba_f Comment
// 12 15 1 192 1 12 12
// 12 9 3 40 1 20 20 PLL out of spec
// 12 15 1 192 1 24 12
// 12 9 1 120 1 30 15
// 12 9 3 40 0 40 20 PLL out of spec
// 12 15 1 192 1 48 12
// 12 15 1 192 1 48 24
// 12 8 1 108 1 54 27
// 12 9 1 120 1 60 15
// 12 9 1 120 1 60 30
// 12 10 1 132 1 66 16.5
//
unsigned long in_cpu_f = param->cpu_f;
unsigned long in_osc0_f = param->osc0_f;
unsigned long mul, div, div2_en = 0, div2_cpu = 0, div2_pba = 0;
unsigned long pll_freq, rest;
Bool b_div2_pba, b_div2_cpu;
// Switch to external Oscillator 0
pm_switch_to_osc0(&AVR32_PM, in_osc0_f, param->osc0_startup);
// Start with CPU freq config
if (in_cpu_f == in_osc0_f)
{
param->cpu_f = in_osc0_f;
param->pba_f = in_osc0_f;
return PM_FREQ_STATUS_OK;
}
else if (in_cpu_f < in_osc0_f)
{
// TBD
}
rest = in_cpu_f % in_osc0_f;
for (div = 1; div < 32; div++)
{
if ((div * rest) % in_osc0_f == 0)
break;
}
if (div == 32)
return PM_FREQ_STATUS_FAIL;
mul = (in_cpu_f * div) / in_osc0_f;
if (mul > PM_MAX_MUL)
return PM_FREQ_STATUS_FAIL;
// export 2power from PLL div to div2_cpu
while (!(div % 2))
{
div /= 2;
div2_cpu++;
}
// Here we know the mul and div parameter of the PLL config.
// . Check out if the PLL has a valid in_cpu_f.
// . Try to have for the PLL frequency (VCO output) the highest possible value
// to reduce jitter.
while (in_osc0_f * 2 * mul / div < AVR32_PM_PLL_VCO_RANGE0_MAX_FREQ)
{
if (2 * mul > PM_MAX_MUL)
break;
mul *= 2;
div2_cpu++;
}
if (div2_cpu != 0)
{
div2_cpu--;
div2_en = 1;
}
pll_freq = in_osc0_f * mul / (div * (1 << div2_en));
// Update real CPU Frequency
param->cpu_f = pll_freq / (1 << div2_cpu);
mul--;
pm_pll_setup(&AVR32_PM
, 0 // pll
, mul // mul
, div // div
, 0 // osc
, 16 // lockcount
);
pm_pll_set_option(&AVR32_PM
, 0 // pll
// PLL clock is lower than 160MHz: need to set pllopt.
, (pll_freq < AVR32_PM_PLL_VCO_RANGE0_MIN_FREQ) ? 1 : 0 // pll_freq
, div2_en // pll_div2
, 0 // pll_wbwdisable
);
rest = pll_freq;
while (rest > AVR32_PM_PBA_MAX_FREQ ||
rest != param->pba_f)
{
div2_pba++;
rest = pll_freq / (1 << div2_pba);
if (rest < param->pba_f)
break;
}
// Update real PBA Frequency
param->pba_f = pll_freq / (1 << div2_pba);
// Enable PLL0
pm_pll_enable(&AVR32_PM, 0);
// Wait for PLL0 locked
pm_wait_for_pll0_locked(&AVR32_PM);
if (div2_cpu)
{
b_div2_cpu = TRUE;
div2_cpu--;
}
else
b_div2_cpu = FALSE;
if (div2_pba)
{
b_div2_pba = TRUE;
div2_pba--;
}
else
b_div2_pba = FALSE;
pm_cksel(&AVR32_PM
, b_div2_pba, div2_pba // PBA
, b_div2_cpu, div2_cpu // PBB
, b_div2_cpu, div2_cpu // HSB
);
if (param->cpu_f > AVR32_FLASHC_FWS_0_MAX_FREQ)
{
flashc_set_wait_state(1);
#if (defined AVR32_FLASHC_210_H_INCLUDED)
if (param->cpu_f > AVR32_FLASHC_HSEN_FWS_1_MAX_FREQ)
flashc_issue_command(AVR32_FLASHC_FCMD_CMD_HSEN, -1);
else
flashc_issue_command(AVR32_FLASHC_FCMD_CMD_HSDIS, -1);
#endif
}
else
{
flashc_set_wait_state(0);
#if (defined AVR32_FLASHC_210_H_INCLUDED)
if (param->cpu_f > AVR32_FLASHC_HSEN_FWS_0_MAX_FREQ)
flashc_issue_command(AVR32_FLASHC_FCMD_CMD_HSEN, -1);
else
flashc_issue_command(AVR32_FLASHC_FCMD_CMD_HSDIS, -1);
#endif
}
pm_switch_to_clock(&AVR32_PM, AVR32_PM_MCCTRL_MCSEL_PLL0);
return PM_FREQ_STATUS_OK;
}
void pm_configure_usb_clock(void)
{
#if UC3A3
// Setup USB GCLK.
pm_gc_setup(&AVR32_PM, AVR32_PM_GCLK_USBB, // gc
0, // osc_or_pll: use Osc (if 0) or PLL (if 1)
0, // pll_osc: select Osc0/PLL0 or Osc1/PLL1
0, // diven
0); // div
// Enable USB GCLK.
pm_gc_enable(&AVR32_PM, AVR32_PM_GCLK_USBB);
#else
// Use 12MHz from OSC0 and generate 96 MHz
pm_pll_setup(&AVR32_PM, 1, // pll.
7, // mul.
1, // div.
0, // osc.
16); // lockcount.
pm_pll_set_option(&AVR32_PM, 1, // pll.
1, // pll_freq: choose the range 80-180MHz.
1, // pll_div2.
0); // pll_wbwdisable.
// start PLL1 and wait forl lock
pm_pll_enable(&AVR32_PM, 1);
// Wait for PLL1 locked.
pm_wait_for_pll1_locked(&AVR32_PM);
pm_gc_setup(&AVR32_PM, AVR32_PM_GCLK_USBB, // gc.
1, // osc_or_pll: use Osc (if 0) or PLL (if 1).
1, // pll_osc: select Osc0/PLL0 or Osc1/PLL1.
0, // diven.
0); // div.
pm_gc_enable(&AVR32_PM, AVR32_PM_GCLK_USBB);
#endif
}

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@ -0,0 +1,566 @@
/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief High-level library abstracting features such as oscillators/pll/dfll
* configuration, clock configuration, System-sensible parameters
* configuration, buses clocks configuration, sleep mode, reset.
*
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "power_clocks_lib.h"
//! Device-specific data
#if UC3L
static long int pcl_configure_clocks_uc3l(pcl_freq_param_t *param); // FORWARD declaration
#endif
#if UC3C
static long int pcl_configure_clocks_uc3c(pcl_freq_param_t *param); // FORWARD declaration
#endif
long int pcl_configure_clocks(pcl_freq_param_t *param)
{
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
return(pm_configure_clocks(param));
#else
#ifdef AVR32_PM_410_H_INCLUDED
// Implementation for UC3C parts.
return(pcl_configure_clocks_uc3c(param));
#else
// Implementation for UC3L parts.
return(pcl_configure_clocks_uc3l(param));
#endif
#endif
}
//! Device-specific implementation
#if UC3L
// FORWARD declaration
static long int pcl_configure_synchronous_clocks( pm_clk_src_t main_clk_src,
unsigned long main_clock_freq_hz,
pcl_freq_param_t *param);
long int pcl_configure_clocks_rcsys(pcl_freq_param_t *param)
{
// Supported main clock sources: PCL_MC_RCSYS
// Supported synchronous clocks frequencies if RCSYS is the main clock source:
// 115200Hz, 57600Hz, 28800Hz, 14400Hz, 7200Hz, 3600Hz, 1800Hz, 900Hz, 450Hz.
// NOTE: by default, this implementation doesn't perform thorough checks on the
// input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
#ifdef AVR32SFW_INPUT_CHECK
// Verify that fCPU >= fPBx
if((param->cpu_f < param->pba_f) || (param->cpu_f < param->pbb_f))
return(-1);
#endif
#ifdef AVR32SFW_INPUT_CHECK
// Verify that the target frequencies are reachable.
if((param->cpu_f > SCIF_SLOWCLOCK_FREQ_HZ) || (param->pba_f > SCIF_SLOWCLOCK_FREQ_HZ)
|| (param->pbb_f > SCIF_SLOWCLOCK_FREQ_HZ))
return(-1);
#endif
return(pcl_configure_synchronous_clocks(PM_CLK_SRC_SLOW, SCIF_SLOWCLOCK_FREQ_HZ, param));
}
long int pcl_configure_clocks_rc120m(pcl_freq_param_t *param)
{
// Supported main clock sources: PCL_MC_RC120M
// Supported synchronous clocks frequencies if RC120M is the main clock source:
// 30MHz, 15MHz, 7.5MHz, 3.75MHz, 1.875MHz, 937.5kHz, 468.75kHz.
// NOTE: by default, this implementation doesn't perform thorough checks on the
// input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
#ifdef AVR32SFW_INPUT_CHECK
// Verify that fCPU >= fPBx
if((param->cpu_f < param->pba_f) || (param->cpu_f < param->pbb_f))
return(-1);
#endif
#ifdef AVR32SFW_INPUT_CHECK
// Verify that the target frequencies are reachable.
if((param->cpu_f > SCIF_RC120M_FREQ_HZ) || (param->pba_f > SCIF_RC120M_FREQ_HZ)
|| (param->pbb_f > SCIF_RC120M_FREQ_HZ))
return(-1);
#endif
// Start the 120MHz internal RCosc (RC120M) clock
scif_start_rc120M();
return(pcl_configure_synchronous_clocks(PM_CLK_SRC_RC120M, SCIF_RC120M_FREQ_HZ, param));
}
long int pcl_configure_clocks_osc0(pcl_freq_param_t *param)
{
// Supported main clock sources: PCL_MC_OSC0
// Supported synchronous clocks frequencies if OSC0 is the main clock source:
// (these obviously depend on the OSC0 frequency; we'll take 16MHz as an example)
// 16MHz, 8MHz, 4MHz, 2MHz, 1MHz, 500kHz, 250kHz, 125kHz, 62.5kHz.
// NOTE: by default, this implementation doesn't perform thorough checks on the
// input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
unsigned long main_clock_freq;
#ifdef AVR32SFW_INPUT_CHECK
// Verify that fCPU >= fPBx
if((param->cpu_f < param->pba_f) || (param->cpu_f < param->pbb_f))
return(-1);
#endif
main_clock_freq = param->osc0_f;
#ifdef AVR32SFW_INPUT_CHECK
// Verify that the target frequencies are reachable.
if((param->cpu_f > main_clock_freq) || (param->pba_f > main_clock_freq)
|| (param->pbb_f > main_clock_freq))
return(-1);
#endif
// Configure OSC0 in crystal mode, external crystal with a fcrystal Hz frequency.
scif_configure_osc_crystalmode(SCIF_OSC0, main_clock_freq);
// Enable the OSC0
scif_enable_osc(SCIF_OSC0, param->osc0_startup, true);
return(pcl_configure_synchronous_clocks(PM_CLK_SRC_OSC0, main_clock_freq, param));
}
long int pcl_configure_clocks_dfll0(pcl_freq_param_t *param)
{
// Supported main clock sources: PCL_MC_DFLL
// Supported synchronous clocks frequencies if DFLL is the main clock source:
// (these obviously depend on the DFLL target frequency; we'll take 100MHz as an example)
// 50MHz, 25MHz, 12.5MHz, 6.25MHz, 3.125MHz, 1562.5kHz, 781.25kHz, 390.625kHz.
// NOTE: by default, this implementation doesn't perform thorough checks on the
// input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
unsigned long main_clock_freq;
scif_gclk_opt_t *pgc_dfllif_ref_opt;
#ifdef AVR32SFW_INPUT_CHECK
// Verify that fCPU >= fPBx
if((param->cpu_f < param->pba_f) || (param->cpu_f < param->pbb_f))
return(-1);
#endif
main_clock_freq = param->dfll_f;
#ifdef AVR32SFW_INPUT_CHECK
// Verify that the target DFLL output frequency is in the correct range.
if((main_clock_freq > SCIF_DFLL_MAXFREQ_HZ) || (main_clock_freq < SCIF_DFLL_MINFREQ_HZ))
return(-1);
// Verify that the target frequencies are reachable.
if((param->cpu_f > main_clock_freq) || (param->pba_f > main_clock_freq)
|| (param->pbb_f > main_clock_freq))
return(-1);
#endif
pgc_dfllif_ref_opt = (scif_gclk_opt_t *)param->pextra_params;
// Implementation note: this implementation configures the DFLL in closed-loop
// mode (because it gives the best accuracy) which enables the generic clock CLK_DFLLIF_REF
// as a reference (RCSYS being used as the generic clock source, undivided).
scif_dfll0_closedloop_configure_and_start(pgc_dfllif_ref_opt, main_clock_freq, TRUE);
return(pcl_configure_synchronous_clocks(PM_CLK_SRC_DFLL0, main_clock_freq, param));
}
static long int pcl_configure_clocks_uc3l(pcl_freq_param_t *param)
{
// Supported main clock sources: PCL_MC_RCSYS, PCL_MC_OSC0, PCL_MC_DFLL0, PCL_MC_RC120M
// Supported synchronous clocks frequencies if RCSYS is the main clock source:
// 115200Hz, 57600Hz, 28800Hz, 14400Hz, 7200Hz, 3600Hz, 1800Hz, 900Hz, 450Hz.
// Supported synchronous clocks frequencies if RC120M is the main clock source:
// 30MHz, 15MHz, 7.5MHz, 3.75MHz, 1.875MHz, 937.5kHz, 468.75kHz.
// Supported synchronous clocks frequencies if OSC0 is the main clock source:
// (these obviously depend on the OSC0 frequency; we'll take 16MHz as an example)
// 16MHz, 8MHz, 4MHz, 2MHz, 1MHz, 500kHz, 250kHz, 125kHz, 62.5kHz.
// Supported synchronous clocks frequencies if DFLL is the main clock source:
// (these obviously depend on the DFLL target frequency; we'll take 100MHz as an example)
// 50MHz, 25MHz, 12.5MHz, 6.25MHz, 3.125MHz, 1562.5kHz, 781.25kHz, 390.625kHz.
// NOTE: by default, this implementation doesn't perform thorough checks on the
// input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
#ifdef AVR32SFW_INPUT_CHECK
// Verify that fCPU >= fPBx
if((param->cpu_f < param->pba_f) || (param->cpu_f < param->pbb_f))
return(-1);
#endif
if(PCL_MC_RCSYS == param->main_clk_src)
{
return(pcl_configure_clocks_rcsys(param));
}
else if(PCL_MC_RC120M == param->main_clk_src)
{
return(pcl_configure_clocks_rc120m(param));
}
else if(PCL_MC_OSC0 == param->main_clk_src)
{
return(pcl_configure_clocks_osc0(param));
}
else // PCL_MC_DFLL0 == param->main_clk_src
{
return(pcl_configure_clocks_dfll0(param));
}
}
static long int pcl_configure_synchronous_clocks(pm_clk_src_t main_clk_src, unsigned long main_clock_freq_hz, pcl_freq_param_t *param)
{
//#
//# Set the Synchronous clock division ratio for each clock domain
//#
pm_set_all_cksel(main_clock_freq_hz, param->cpu_f, param->pba_f, param->pbb_f);
//#
//# Set the Flash wait state and the speed read mode (depending on the target CPU frequency).
//#
#if UC3L
flashcdw_set_flash_waitstate_and_readmode(param->cpu_f);
#elif UC3C
flashc_set_flash_waitstate_and_readmode(param->cpu_f);
#endif
//#
//# Switch the main clock source to the selected clock.
//#
pm_set_mclk_source(main_clk_src);
return PASS;
}
#endif // UC3L device-specific implementation
//! UC3C Device-specific implementation
#if UC3C
static long int pcl_configure_clocks_uc3c(pcl_freq_param_t *param)
{
#define PM_MAX_MUL ((1 << AVR32_SCIF_PLLMUL_SIZE) - 1)
#define AVR32_PM_PBA_MAX_FREQ 66000000
#define AVR32_PM_PLL_VCO_RANGE0_MAX_FREQ 240000000
#define AVR32_PM_PLL_VCO_RANGE0_MIN_FREQ 160000000
// Implementation for UC3C parts.
// Supported frequencies:
// Fosc0 mul div PLL div2_en cpu_f pba_f Comment
// 12 15 1 192 1 12 12
// 12 9 3 40 1 20 20 PLL out of spec
// 12 15 1 192 1 24 12
// 12 9 1 120 1 30 15
// 12 9 3 40 0 40 20 PLL out of spec
// 12 15 1 192 1 48 12
// 12 15 1 192 1 48 24
// 12 8 1 108 1 54 27
// 12 9 1 120 1 60 15
// 12 9 1 120 1 60 30
// 12 10 1 132 1 66 16.5
//
unsigned long in_cpu_f = param->cpu_f;
unsigned long in_osc0_f = param->osc0_f;
unsigned long mul, div, div2_en = 0, div2_cpu = 0, div2_pba = 0;
unsigned long pll_freq, rest;
Bool b_div2_pba, b_div2_cpu;
// Configure OSC0 in crystal mode, external crystal with a FOSC0 Hz frequency.
scif_configure_osc_crystalmode(SCIF_OSC0, in_osc0_f);
// Enable the OSC0
scif_enable_osc(SCIF_OSC0, param->osc0_startup, true);
// Set the main clock source as being OSC0.
pm_set_mclk_source(PM_CLK_SRC_OSC0);
// Start with CPU freq config
if (in_cpu_f == in_osc0_f)
{
param->cpu_f = in_osc0_f;
param->pba_f = in_osc0_f;
return PASS;
}
else if (in_cpu_f < in_osc0_f)
{
// TBD
}
rest = in_cpu_f % in_osc0_f;
for (div = 1; div < 32; div++)
{
if ((div * rest) % in_osc0_f == 0)
break;
}
if (div == 32)
return FAIL;
mul = (in_cpu_f * div) / in_osc0_f;
if (mul > PM_MAX_MUL)
return FAIL;
// export 2power from PLL div to div2_cpu
while (!(div % 2))
{
div /= 2;
div2_cpu++;
}
// Here we know the mul and div parameter of the PLL config.
// . Check out if the PLL has a valid in_cpu_f.
// . Try to have for the PLL frequency (VCO output) the highest possible value
// to reduce jitter.
while (in_osc0_f * 2 * mul / div < AVR32_PM_PLL_VCO_RANGE0_MAX_FREQ)
{
if (2 * mul > PM_MAX_MUL)
break;
mul *= 2;
div2_cpu++;
}
if (div2_cpu != 0)
{
div2_cpu--;
div2_en = 1;
}
pll_freq = in_osc0_f * mul / (div * (1 << div2_en));
// Update real CPU Frequency
param->cpu_f = pll_freq / (1 << div2_cpu);
mul--;
scif_pll_opt_t opt;
opt.osc = SCIF_OSC0, // Sel Osc0 or Osc1
opt.lockcount = 16, // lockcount in main clock for the PLL wait lock
opt.div = div, // DIV=1 in the formula
opt.mul = mul, // MUL=7 in the formula
opt.pll_div2 = div2_en, // pll_div2 Divide the PLL output frequency by 2 (this settings does not change the FVCO value)
opt.pll_wbwdisable = 0, //pll_wbwdisable 1 Disable the Wide-Bandith Mode (Wide-Bandwith mode allow a faster startup time and out-of-lock time). 0 to enable the Wide-Bandith Mode.
opt.pll_freq = (pll_freq < AVR32_PM_PLL_VCO_RANGE0_MIN_FREQ) ? 1 : 0, // Set to 1 for VCO frequency range 80-180MHz, set to 0 for VCO frequency range 160-240Mhz.
scif_pll_setup(SCIF_PLL0, opt); // lockcount in main clock for the PLL wait lock
/* Enable PLL0 */
scif_pll_enable(SCIF_PLL0);
/* Wait for PLL0 locked */
scif_wait_for_pll_locked(SCIF_PLL0) ;
rest = pll_freq;
while (rest > AVR32_PM_PBA_MAX_FREQ ||
rest != param->pba_f)
{
div2_pba++;
rest = pll_freq / (1 << div2_pba);
if (rest < param->pba_f)
break;
}
// Update real PBA Frequency
param->pba_f = pll_freq / (1 << div2_pba);
if (div2_cpu)
{
b_div2_cpu = TRUE;
div2_cpu--;
}
else
b_div2_cpu = FALSE;
if (div2_pba)
{
b_div2_pba = TRUE;
div2_pba--;
}
else
b_div2_pba = FALSE;
if (b_div2_cpu == TRUE )
{
pm_set_clk_domain_div(PM_CLK_DOMAIN_0, (pm_divratio_t) div2_cpu); // CPU
pm_set_clk_domain_div(PM_CLK_DOMAIN_1, (pm_divratio_t) div2_cpu); // HSB
pm_set_clk_domain_div(PM_CLK_DOMAIN_3, (pm_divratio_t) div2_cpu); // PBB
}
if (b_div2_pba == TRUE )
{
pm_set_clk_domain_div(PM_CLK_DOMAIN_2, (pm_divratio_t) div2_pba); // PBA
pm_set_clk_domain_div(PM_CLK_DOMAIN_4, (pm_divratio_t) div2_pba); // PBC
}
// Set Flashc Wait State
flashc_set_flash_waitstate_and_readmode(param->cpu_f);
// Set the main clock source as being PLL0.
pm_set_mclk_source(PM_CLK_SRC_PLL0);
return PASS;
}
#endif // UC3C device-specific implementation
long int pcl_switch_to_osc(pcl_osc_t osc, unsigned int fcrystal, unsigned int startup)
{
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
if(PCL_OSC0 == osc)
{
// Configure OSC0 in crystal mode, external crystal with a FOSC0 Hz frequency,
// enable the OSC0, set the main clock source as being OSC0.
pm_switch_to_osc0(&AVR32_PM, fcrystal, startup);
}
else
{
return PCL_NOT_SUPPORTED;
}
#else
// Implementation for UC3C, UC3L parts.
#if AVR32_PM_VERSION_RESETVALUE < 0x400
return PCL_NOT_SUPPORTED;
#else
if(PCL_OSC0 == osc)
{
// Configure OSC0 in crystal mode, external crystal with a fcrystal Hz frequency.
scif_configure_osc_crystalmode(SCIF_OSC0, fcrystal);
// Enable the OSC0
scif_enable_osc(SCIF_OSC0, startup, true);
// Set the Flash wait state and the speed read mode (depending on the target CPU frequency).
#if UC3L
flashcdw_set_flash_waitstate_and_readmode(fcrystal);
#elif UC3C
flashc_set_flash_waitstate_and_readmode(fcrystal);
#endif
// Set the main clock source as being OSC0.
pm_set_mclk_source(PM_CLK_SRC_OSC0);
}
else
{
return PCL_NOT_SUPPORTED;
}
#endif
#endif
return PASS;
}
long int pcl_configure_usb_clock(void)
{
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
pm_configure_usb_clock();
return PASS;
#else
#ifdef AVR32_PM_410_H_INCLUDED
const scif_pll_opt_t opt = {
.osc = SCIF_OSC0, // Sel Osc0 or Osc1
.lockcount = 16, // lockcount in main clock for the PLL wait lock
.div = 1, // DIV=1 in the formula
.mul = 5, // MUL=7 in the formula
.pll_div2 = 1, // pll_div2 Divide the PLL output frequency by 2 (this settings does not change the FVCO value)
.pll_wbwdisable = 0, //pll_wbwdisable 1 Disable the Wide-Bandith Mode (Wide-Bandwith mode allow a faster startup time and out-of-lock time). 0 to enable the Wide-Bandith Mode.
.pll_freq = 1, // Set to 1 for VCO frequency range 80-180MHz, set to 0 for VCO frequency range 160-240Mhz.
};
/* Setup PLL1 on Osc0, mul=7 ,no divisor, lockcount=16, ie. 16Mhzx6 = 96MHz output */
scif_pll_setup(SCIF_PLL1, opt); // lockcount in main clock for the PLL wait lock
/* Enable PLL1 */
scif_pll_enable(SCIF_PLL1);
/* Wait for PLL1 locked */
scif_wait_for_pll_locked(SCIF_PLL1) ;
// Implementation for UC3C parts.
// Setup the generic clock for USB
scif_gc_setup(AVR32_SCIF_GCLK_USB,
SCIF_GCCTRL_PLL1,
AVR32_SCIF_GC_NO_DIV_CLOCK,
0);
// Now enable the generic clock
scif_gc_enable(AVR32_SCIF_GCLK_USB);
return PASS;
#else
return PCL_NOT_SUPPORTED;
#endif
#endif
}
#if UC3L
#else
void pcl_write_gplp(unsigned long gplp, unsigned long value)
{
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
pm_write_gplp(&AVR32_PM,gplp,value);
#else
scif_write_gplp(gplp,value);
#endif
}
unsigned long pcl_read_gplp(unsigned long gplp)
{
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
return pm_read_gplp(&AVR32_PM,gplp);
#else
return scif_read_gplp(gplp);
#endif
}
#endif

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief High-level library abstracting features such as oscillators/pll/dfll
* configuration, clock configuration, System-sensible parameters
* configuration, buses clocks configuration, sleep mode, reset.
*
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
*****************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _POWER_CLOCKS_LIB_H_
#define _POWER_CLOCKS_LIB_H_
#ifdef __cplusplus
extern "C" {
#endif
#include <avr32/io.h>
#include "compiler.h"
#ifndef AVR32_PM_VERSION_RESETVALUE
// Support for UC3A, UC3A3, UC3B parts.
#include "pm.h"
#else
//! Device-specific data
#if UC3L
#include "pm_uc3l.h"
#include "scif_uc3l.h"
#include "flashcdw.h"
#elif UC3C
#include "pm_uc3c.h"
#include "scif_uc3c.h"
#include "flashc.h"
#endif
#endif
/*! \name Clocks Management
*/
//! @{
//! The different oscillators
typedef enum
{
PCL_OSC0 = 0,
PCL_OSC1 = 1
} pcl_osc_t;
//! The different DFLLs
typedef enum
{
PCL_DFLL0 = 0,
PCL_DFLL1 = 1
} pcl_dfll_t;
//! Possible Main Clock Sources
typedef enum
{
PCL_MC_RCSYS, // Default main clock source, supported by all (aka Slow Clock)
PCL_MC_OSC0, // Supported by all
PCL_MC_OSC1, // Supported by UC3C only
PCL_MC_OSC0_PLL0, // Supported by UC3A, UC3B, UC3A3, UC3C (the main clock source is PLL0 with OSC0 as reference)
PCL_MC_OSC1_PLL0, // Supported by UC3A, UC3B, UC3A3, UC3C (the main clock source is PLL0 with OSC1 as reference)
PCL_MC_OSC0_PLL1, // Supported by UC3C (the main clock source is PLL1 with OSC0 as reference)
PCL_MC_OSC1_PLL1, // Supported by UC3C (the main clock source is PLL1 with OSC1 as reference)
PCL_MC_DFLL0, // Supported by UC3L
PCL_MC_DFLL1, // Not supported yet
PCL_MC_RC120M, // Supported by UC3L, UC3C
PCL_MC_RC8M, // Supported by UC3C
PCL_MC_CRIPOSC // Supported by UC3C
} pcl_mainclk_t;
//! Input and output parameters to configure clocks with pcl_configure_clocks().
// NOTE: regarding the frequency settings, always abide by the datasheet rules and min & max supported frequencies.
#ifndef AVR32_PM_VERSION_RESETVALUE
// Support for UC3A, UC3A3, UC3B parts.
#define pcl_freq_param_t pm_freq_param_t // See pm.h
#else
// Support for UC3C, UC3L parts.
typedef struct
{
//! Main clock source selection (input argument).
pcl_mainclk_t main_clk_src;
//! Target CPU frequency (input/output argument).
unsigned long cpu_f;
//! Target PBA frequency (input/output argument).
unsigned long pba_f;
//! Target PBB frequency (input/output argument).
unsigned long pbb_f;
//! Target PBC frequency (input/output argument).
unsigned long pbc_f;
//! Oscillator 0's external crystal(or external clock) frequency (board dependant) (input argument).
unsigned long osc0_f;
//! Oscillator 0's external crystal(or external clock) startup time: AVR32_PM_OSCCTRL0_STARTUP_x_RCOSC (input argument).
unsigned long osc0_startup;
//! DFLL target frequency (input/output argument) (NOTE: the bigger, the most stable the frequency)
unsigned long dfll_f;
//! Other parameters that might be necessary depending on the device (implementation-dependent).
// For the UC3L DFLL setup, this parameter should be pointing to a structure of
// type (scif_gclk_opt_t *).
void *pextra_params;
} pcl_freq_param_t;
#endif
//! Define "not supported" for the lib.
#define PCL_NOT_SUPPORTED (-10000)
/*! \brief Automatically configure the CPU, PBA, PBB, and HSB clocks
*
* This function needs some parameters stored in a pcl_freq_param_t structure:
* - main_clk_src is the id of the main clock source to use,
* - cpu_f and pba_f and pbb_f are the wanted frequencies,
* - osc0_f is the oscillator 0's external crystal (or external clock) on-board frequency (e.g. FOSC0),
* - osc0_startup is the oscillator 0's external crystal (or external clock) startup time (e.g. OSC0_STARTUP).
* - dfll_f is the target DFLL frequency to set-up if main_clk_src is the dfll.
*
* The CPU, HSB and PBA frequencies programmed after configuration are stored back into cpu_f and pba_f.
*
* \note: since it is dynamically computing the appropriate field values of the
* configuration registers from the parameters structure, this function is not
* optimal in terms of code size. For a code size optimal solution, it is better
* to create a new function from pcl_configure_clocks() and modify it to use
* preprocessor computation from pre-defined target frequencies.
*
* \param param pointer on the configuration structure.
*
* \retval 0 Success.
* \retval <0 The configuration cannot be performed.
*/
extern long int pcl_configure_clocks(pcl_freq_param_t *param);
/*! \brief Automatically configure the CPU, PBA, PBB, and HSB clocks using the RCSYS osc as main source clock.
*
* This function needs some parameters stored in a pcl_freq_param_t structure:
* - cpu_f and pba_f and pbb_f are the wanted frequencies
*
* Supported main clock sources: PCL_MC_RCSYS
*
* Supported synchronous clocks frequencies:
* 115200Hz, 57600Hz, 28800Hz, 14400Hz, 7200Hz, 3600Hz, 1800Hz, 900Hz, 450Hz.
*
* \note: by default, this implementation doesn't perform thorough checks on the
* input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
*
* \note: since it is dynamically computing the appropriate field values of the
* configuration registers from the parameters structure, this function is not
* optimal in terms of code size. For a code size optimal solution, it is better
* to create a new function from pcl_configure_clocks_rcsys() and modify it to use
* preprocessor computation from pre-defined target frequencies.
*
* \param param pointer on the configuration structure.
*
* \retval 0 Success.
* \retval <0 The configuration cannot be performed.
*/
extern long int pcl_configure_clocks_rcsys(pcl_freq_param_t *param);
/*! \brief Automatically configure the CPU, PBA, PBB, and HSB clocks using the RC120M osc as main source clock.
*
* This function needs some parameters stored in a pcl_freq_param_t structure:
* - cpu_f and pba_f and pbb_f are the wanted frequencies
*
* Supported main clock sources: PCL_MC_RC120M
*
* Supported synchronous clocks frequencies:
* 30MHz, 15MHz, 7.5MHz, 3.75MHz, 1.875MHz, 937.5kHz, 468.75kHz.
*
* \note: by default, this implementation doesn't perform thorough checks on the
* input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
*
* \note: since it is dynamically computing the appropriate field values of the
* configuration registers from the parameters structure, this function is not
* optimal in terms of code size. For a code size optimal solution, it is better
* to create a new function from pcl_configure_clocks_rc120m() and modify it to
* use preprocessor computation from pre-defined target frequencies.
*
* \param param pointer on the configuration structure.
*
* \retval 0 Success.
* \retval <0 The configuration cannot be performed.
*/
extern long int pcl_configure_clocks_rc120m(pcl_freq_param_t *param);
/*! \brief Automatically configure the CPU, PBA, PBB, and HSB clocks using the OSC0 osc as main source clock
*
* This function needs some parameters stored in a pcl_freq_param_t structure:
* - cpu_f and pba_f and pbb_f are the wanted frequencies,
* - osc0_f is the oscillator 0's external crystal (or external clock) on-board frequency (e.g. FOSC0),
* - osc0_startup is the oscillator 0's external crystal (or external clock) startup time (e.g. OSC0_STARTUP).
*
* Supported main clock sources: PCL_MC_OSC0
*
* Supported synchronous clocks frequencies:
* (these obviously depend on the OSC0 frequency; we'll take 16MHz as an example)
* 16MHz, 8MHz, 4MHz, 2MHz, 1MHz, 500kHz, 250kHz, 125kHz, 62.5kHz.
*
* \note: by default, this implementation doesn't perform thorough checks on the
* input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
*
* \note: since it is dynamically computing the appropriate field values of the
* configuration registers from the parameters structure, this function is not
* optimal in terms of code size. For a code size optimal solution, it is better
* to create a new function from pcl_configure_clocks_osc0() and modify it to use
* preprocessor computation from pre-defined target frequencies.
*
* \param param pointer on the configuration structure.
*
* \retval 0 Success.
* \retval <0 The configuration cannot be performed.
*/
extern long int pcl_configure_clocks_osc0(pcl_freq_param_t *param);
/*! \brief Automatically configure the CPU, PBA, PBB, and HSB clocks using the DFLL0 as main source clock
*
* This function needs some parameters stored in a pcl_freq_param_t structure:
* - cpu_f and pba_f and pbb_f are the wanted frequencies,
* - dfll_f is the target DFLL frequency to set-up
*
* \note: when the DFLL0 is to be used as main source clock for the synchronous clocks,
* the target frequency of the DFLL should be chosen to be as high as possible
* within the specification range (for stability reasons); the target cpu and pbx
* frequencies will then be reached by appropriate division ratio.
*
* Supported main clock sources: PCL_MC_DFLL0
*
* Supported synchronous clocks frequencies:
* (these obviously depend on the DFLL target frequency; we'll take 100MHz as an example)
* 50MHz, 25MHz, 12.5MHz, 6.25MHz, 3.125MHz, 1562.5kHz, 781.25kHz, 390.625kHz.
*
* \note: by default, this implementation doesn't perform thorough checks on the
* input parameters. To enable the checks, define AVR32SFW_INPUT_CHECK.
*
* \note: since it is dynamically computing the appropriate field values of the
* configuration registers from the parameters structure, this function is not
* optimal in terms of code size. For a code size optimal solution, it is better
* to create a new function from pcl_configure_clocks_dfll0() and modify it to
* use preprocessor computation from pre-defined target frequencies.
*
* \param param pointer on the configuration structure.
*
* \retval 0 Success.
* \retval <0 The configuration cannot be performed.
*/
extern long int pcl_configure_clocks_dfll0(pcl_freq_param_t *param);
/*! \brief Switch the main clock source to Osc0 configured in crystal mode
*
* \param osc The oscillator to enable and switch to.
* \param fcrystal Oscillator external crystal frequency (Hz)
* \param startup Oscillator startup time.
*
* \return Status.
* \retval 0 Success.
* \retval <0 An error occured.
*/
extern long int pcl_switch_to_osc(pcl_osc_t osc, unsigned int fcrystal, unsigned int startup);
/*! \brief Enable the clock of a module.
*
* \param module The module to clock (use one of the defines in the part-specific
* header file under "toolchain folder"/avr32/inc(lude)/avr32/; depending on the
* clock domain, look for the sections "CPU clocks", "HSB clocks", "PBx clocks"
* or look in the module section).
*
* \return Status.
* \retval 0 Success.
* \retval <0 An error occured.
*/
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
#define pcl_enable_module(module) pm_enable_module(&AVR32_PM, module)
#else
// Implementation for UC3C, UC3L parts.
#define pcl_enable_module(module) pm_enable_module(module)
#endif
/*! \brief Disable the clock of a module.
*
* \param module The module to shut down (use one of the defines in the part-specific
* header file under "toolchain folder"/avr32/inc(lude)/avr32/; depending on the
* clock domain, look for the sections "CPU clocks", "HSB clocks", "PBx clocks"
* or look in the module section).
*
* \return Status.
* \retval 0 Success.
* \retval <0 An error occured.
*/
#ifndef AVR32_PM_VERSION_RESETVALUE
// Implementation for UC3A, UC3A3, UC3B parts.
#define pcl_disable_module(module) pm_disable_module(&AVR32_PM, module)
#else
// Implementation for UC3C, UC3L parts.
#define pcl_disable_module(module) pm_disable_module(module)
#endif
/*! \brief Configure the USB Clock
*
*
* \return Status.
* \retval 0 Success.
* \retval <0 An error occured.
*/
extern long int pcl_configure_usb_clock(void);
//! @}
/*! \name Power Management
*/
//! @{
/*!
* \brief Read the content of the GPLP registers
* \param gplp GPLP register index (0,1,... depending on the number of GPLP registers for a given part)
*
* \return The content of the chosen GPLP register.
*/
extern unsigned long pcl_read_gplp(unsigned long gplp);
/*!
* \brief Write into the GPLP registers
* \param gplp GPLP register index (0,1,... depending on the number of GPLP registers for a given part)
* \param value Value to write
*/
extern void pcl_write_gplp(unsigned long gplp, unsigned long value);
//! @}
#ifdef __cplusplus
}
#endif
#endif // _POWER_CLOCKS_LIB_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief RTC driver for AVR32 UC3.
*
* AVR32 Real Time Counter driver module.
*
* - Compiler: GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an RTC and a PM module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <avr32/io.h>
#include "compiler.h"
#include "pm.h"
#include "rtc.h"
int rtc_is_busy(volatile avr32_rtc_t *rtc)
{
return (rtc->ctrl & AVR32_RTC_CTRL_BUSY_MASK) != 0;
}
int rtc_init(volatile avr32_rtc_t *rtc, unsigned char osc_type, unsigned char psel)
{
// If exit, it means that the configuration has not been set correctly
if (osc_type > (1 << AVR32_RTC_CTRL_CLK32_SIZE) - 1 ||
psel > (1 << AVR32_RTC_CTRL_PSEL_SIZE) - 1)
return 0;
// If we use the 32-kHz oscillator, we have to enable it first
if (osc_type == RTC_OSC_32KHZ)
{
// Select the 32-kHz oscillator crystal
pm_enable_osc32_crystal(&AVR32_PM);
// Enable the 32-kHz clock
pm_enable_clk32_no_wait(&AVR32_PM, AVR32_PM_OSCCTRL32_STARTUP_0_RCOSC);
}
// Wait until the rtc CTRL register is up-to-date
while (rtc_is_busy(rtc));
// Set the new RTC configuration
rtc->ctrl = osc_type << AVR32_RTC_CTRL_CLK32_OFFSET |
psel << AVR32_RTC_CTRL_PSEL_OFFSET |
AVR32_RTC_CTRL_CLKEN_MASK;
// Wait until write is done
while (rtc_is_busy(rtc));
// Set the counter value to 0
rtc_set_value(rtc, 0x00000000);
// Set the top value to 0xFFFFFFFF
rtc_set_top_value(rtc, 0xFFFFFFFF);
return 1;
}
void rtc_set_value(volatile avr32_rtc_t *rtc, unsigned long val)
{
// Wait until we can write into the VAL register
while (rtc_is_busy(rtc));
// Set the new val value
rtc->val = val;
// Wait until write is done
while (rtc_is_busy(rtc));
}
unsigned long rtc_get_value(volatile avr32_rtc_t *rtc)
{
return rtc->val;
}
void rtc_enable_wake_up(volatile avr32_rtc_t *rtc)
{
// Wait until the rtc CTRL register is up-to-date
while (rtc_is_busy(rtc));
// Enable the wake up of the RTC
rtc->ctrl |= AVR32_RTC_CTRL_WAKE_EN_MASK;
// Wait until write is done
while (rtc_is_busy(rtc));
}
void rtc_disable_wake_up(volatile avr32_rtc_t *rtc)
{
// Wait until the rtc CTRL register is up-to-date
while (rtc_is_busy(rtc));
// Disable the wake up of the RTC
rtc->ctrl &= ~AVR32_RTC_CTRL_WAKE_EN_MASK;
// Wait until write is done
while (rtc_is_busy(rtc));
}
void rtc_enable(volatile avr32_rtc_t *rtc)
{
// Wait until the rtc CTRL register is up-to-date
while (rtc_is_busy(rtc));
// Enable the RTC
rtc->ctrl |= AVR32_RTC_CTRL_EN_MASK;
// Wait until write is done
while (rtc_is_busy(rtc));
}
void rtc_disable(volatile avr32_rtc_t *rtc)
{
// Wait until the rtc CTRL register is up-to-date
while (rtc_is_busy(rtc));
// Disable the RTC
rtc->ctrl &= ~AVR32_RTC_CTRL_EN_MASK;
// Wait until write is done
while (rtc_is_busy(rtc));
}
void rtc_enable_interrupt(volatile avr32_rtc_t *rtc)
{
rtc->ier = AVR32_RTC_IER_TOPI_MASK;
}
void rtc_disable_interrupt(volatile avr32_rtc_t *rtc)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
rtc->idr = AVR32_RTC_IDR_TOPI_MASK;
rtc->imr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void rtc_clear_interrupt(volatile avr32_rtc_t *rtc)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
if (global_interrupt_enabled) Disable_global_interrupt();
rtc->icr = AVR32_RTC_ICR_TOPI_MASK;
rtc->isr;
if (global_interrupt_enabled) Enable_global_interrupt();
}
void rtc_set_top_value(volatile avr32_rtc_t *rtc, unsigned long top)
{
// Wait until we can write into the VAL register
while (rtc_is_busy(rtc));
// Set the new val value
rtc->top = top;
// Wait until write is done
while (rtc_is_busy(rtc));
}
unsigned long rtc_get_top_value(volatile avr32_rtc_t *rtc)
{
return rtc->top;
}
int rtc_interrupt_enabled(volatile avr32_rtc_t *rtc)
{
return (rtc->imr & AVR32_RTC_IMR_TOPI_MASK) != 0;
}
int rtc_is_interrupt(volatile avr32_rtc_t *rtc)
{
return (rtc->isr & AVR32_RTC_ISR_TOPI_MASK) != 0;
}

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/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief RTC driver for AVR32 UC3.
*
* AVR32 Real Time Counter driver module.
*
* - Compiler: GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an RTC and a PM module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _RTC_H_
#define _RTC_H_
#include "compiler.h"
#include <avr32/io.h>
/*! \name Oscillator Types
*/
//! @{
#define RTC_OSC_32KHZ 1
#define RTC_OSC_RC 0
//! @}
/*! \name Predefined PSEL Values
*/
//! @{
//! The PSEL value to set the RTC source clock (after the prescaler) to 1 Hz,
//! when using an external 32-kHz crystal.
#define RTC_PSEL_32KHZ_1HZ 14
//! The PSEL value to set the RTC source clock (after the prescaler) to 1.76 Hz,
//! when using the internal RC oscillator (~ 115 kHz).
#define RTC_PSEL_RC_1_76HZ 15
//! @}
/*!
* \brief This function will initialise the RTC module.
* If you use the 32 KHz oscillator, it will enable this module.
* This function also set the top value of the RTC to 0xFFFFFFFF
* and the value to 0.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \param osc_type The oscillator you want to use. If you need a better
* accuracy, use the 32 KHz oscillator (i.e. RTC_OSC_32KHZ).
* \param psel The preselector value for the corresponding oscillator (4-bits).
* To obtain this value, you can use this formula:
* psel = log(Fosc/Frtc)/log(2)-1, where Fosc is the frequency of the
* oscillator you are using (32 KHz or 115 KHz) and Frtc the frequency
* desired.
* \return 1 if the initialisation succeds otherwize it will return 0.
*/
extern int rtc_init(volatile avr32_rtc_t *rtc, unsigned char osc_type, unsigned char psel);
/*!
* \brief Enable the RTC.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_enable(volatile avr32_rtc_t *rtc);
/*!
* \brief Disable the RTC.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_disable(volatile avr32_rtc_t *rtc);
/*!
* \brief Enable the wake up feature of the RTC.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_enable_wake_up(volatile avr32_rtc_t *rtc);
/*!
* \brief Disable the wake up feature of the RTC.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_disable_wake_up(volatile avr32_rtc_t *rtc);
/*!
* \brief Enable the interrupt feature of the RTC.
* An interrupt is raised when the value of the RTC
* is equal to its top value.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_enable_interrupt(volatile avr32_rtc_t *rtc);
/*!
* \brief Disable the interrupt feature of the RTC.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_disable_interrupt(volatile avr32_rtc_t *rtc);
/*!
* \brief Clear the interrupt flag.
* Call this function once you handled the interrupt.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
*/
extern void rtc_clear_interrupt(volatile avr32_rtc_t *rtc);
/*!
* \brief Get the status of interrupts.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \return 1 if the interrupts are enabled otherwize it returns 0.
*/
extern int rtc_interrupt_enabled(volatile avr32_rtc_t *rtc);
/*!
* \brief Check if an interrupt is raised.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \return 1 if an interrupt is currently raised otherwize it returns 0.
*/
extern int rtc_is_interrupt(volatile avr32_rtc_t *rtc);
/*!
* \brief This function sets the RTC current top value.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \param top The top value you want to store.
*/
extern void rtc_set_top_value(volatile avr32_rtc_t *rtc, unsigned long top);
/*!
* \brief This function returns the RTC current top value.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \return The RTC current top value.
*/
extern unsigned long rtc_get_top_value(volatile avr32_rtc_t *rtc);
/*!
* \brief This function checks if the RTC is busy or not.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \return 1 if the RTC is busy otherwize it will return 0.
*/
extern int rtc_is_busy(volatile avr32_rtc_t *rtc);
/*!
* \brief This function sets the RTC current value.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \param val The value you want to store.
*/
extern void rtc_set_value(volatile avr32_rtc_t *rtc, unsigned long val);
/*!
* \brief This function returns the RTC current value.
* \param rtc Base address of the RTC (i.e. &AVR32_RTC).
* \return The RTC current value.
*/
extern unsigned long rtc_get_value(volatile avr32_rtc_t *rtc);
#endif // _RTC_H_

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/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief SPI driver for AVR32 UC3.
*
* This file defines a useful set of functions for the SPI interface on AVR32
* devices.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include "spi.h"
#ifdef FREERTOS_USED
#include "FreeRTOS.h"
#include "semphr.h"
#endif
/*! \name SPI Writable Bit-Field Registers
*/
//! @{
typedef union
{
unsigned long cr;
avr32_spi_cr_t CR;
} u_avr32_spi_cr_t;
typedef union
{
unsigned long mr;
avr32_spi_mr_t MR;
} u_avr32_spi_mr_t;
typedef union
{
unsigned long tdr;
avr32_spi_tdr_t TDR;
} u_avr32_spi_tdr_t;
typedef union
{
unsigned long ier;
avr32_spi_ier_t IER;
} u_avr32_spi_ier_t;
typedef union
{
unsigned long idr;
avr32_spi_idr_t IDR;
} u_avr32_spi_idr_t;
typedef union
{
unsigned long csr;
avr32_spi_csr0_t CSR;
} u_avr32_spi_csr_t;
//! @}
#ifdef FREERTOS_USED
//! The SPI mutex.
static xSemaphoreHandle xSPIMutex;
#endif
/*! \brief Calculates the baudrate divider.
*
* \param options Pointer to a structure containing initialization options for
* an SPI channel.
* \param pba_hz SPI module input clock frequency (PBA clock, Hz).
*
* \return Divider or error code.
* \retval >=0 Success.
* \retval <0 Error.
*/
static int getBaudDiv(const spi_options_t *options, unsigned int pba_hz)
{
int baudDiv = (pba_hz + options->baudrate / 2) / options->baudrate;
if (baudDiv <= 0 || baudDiv > 255) {
return -1;
}
return baudDiv;
}
void spi_reset(volatile avr32_spi_t *spi)
{
spi->cr = AVR32_SPI_CR_SWRST_MASK;
}
spi_status_t spi_initSlave(volatile avr32_spi_t *spi,
unsigned char bits,
unsigned char spi_mode)
{
if (spi_mode > 3 ||
bits < 8 || bits > 16) {
return SPI_ERROR_ARGUMENT;
}
// Reset.
spi->cr = AVR32_SPI_CR_SWRST_MASK;
// Will use CSR0 offsets; these are the same for CSR0 to CSR3.
spi->csr0 = ((spi_mode >> 1) << AVR32_SPI_CSR0_CPOL_OFFSET) |
(((spi_mode & 0x1) ^ 0x1) << AVR32_SPI_CSR0_NCPHA_OFFSET) |
((bits - 8) << AVR32_SPI_CSR0_BITS_OFFSET);
return SPI_OK;
}
spi_status_t spi_initTest(volatile avr32_spi_t *spi)
{
// Reset.
spi->cr = AVR32_SPI_CR_SWRST_MASK;
spi->mr |= AVR32_SPI_MR_MSTR_MASK | // Master Mode.
AVR32_SPI_MR_LLB_MASK; // Local Loopback.
return SPI_OK;
}
spi_status_t spi_initMaster(volatile avr32_spi_t *spi, const spi_options_t *options)
{
u_avr32_spi_mr_t u_avr32_spi_mr;
if (options->modfdis > 1) {
return SPI_ERROR_ARGUMENT;
}
// Reset.
spi->cr = AVR32_SPI_CR_SWRST_MASK;
// Master Mode.
u_avr32_spi_mr.mr = spi->mr;
u_avr32_spi_mr.MR.mstr = 1;
u_avr32_spi_mr.MR.modfdis = options->modfdis;
u_avr32_spi_mr.MR.llb = 0;
u_avr32_spi_mr.MR.pcs = (1 << AVR32_SPI_MR_PCS_SIZE) - 1;
spi->mr = u_avr32_spi_mr.mr;
return SPI_OK;
}
spi_status_t spi_selectionMode(volatile avr32_spi_t *spi,
unsigned char variable_ps,
unsigned char pcs_decode,
unsigned char delay)
{
u_avr32_spi_mr_t u_avr32_spi_mr;
if (variable_ps > 1 ||
pcs_decode > 1) {
return SPI_ERROR_ARGUMENT;
}
u_avr32_spi_mr.mr = spi->mr;
u_avr32_spi_mr.MR.ps = variable_ps;
u_avr32_spi_mr.MR.pcsdec = pcs_decode;
u_avr32_spi_mr.MR.dlybcs = delay;
spi->mr = u_avr32_spi_mr.mr;
return SPI_OK;
}
spi_status_t spi_selectChip(volatile avr32_spi_t *spi, unsigned char chip)
{
#ifdef FREERTOS_USED
while (pdFALSE == xSemaphoreTake(xSPIMutex, 20));
#endif
// Assert all lines; no peripheral is selected.
spi->mr |= AVR32_SPI_MR_PCS_MASK;
if (spi->mr & AVR32_SPI_MR_PCSDEC_MASK) {
// The signal is decoded; allow up to 15 chips.
if (chip > 14) {
return SPI_ERROR_ARGUMENT;
}
spi->mr &= ~AVR32_SPI_MR_PCS_MASK | (chip << AVR32_SPI_MR_PCS_OFFSET);
} else {
if (chip > 3) {
return SPI_ERROR_ARGUMENT;
}
spi->mr &= ~(1 << (AVR32_SPI_MR_PCS_OFFSET + chip));
}
return SPI_OK;
}
spi_status_t spi_unselectChip(volatile avr32_spi_t *spi, unsigned char chip)
{
unsigned int timeout = SPI_TIMEOUT;
while (!(spi->sr & AVR32_SPI_SR_TXEMPTY_MASK)) {
if (!timeout--) {
return SPI_ERROR_TIMEOUT;
}
}
// Assert all lines; no peripheral is selected.
spi->mr |= AVR32_SPI_MR_PCS_MASK;
// Last transfer, so deassert the current NPCS if CSAAT is set.
spi->cr = AVR32_SPI_CR_LASTXFER_MASK;
#ifdef FREERTOS_USED
xSemaphoreGive(xSPIMutex);
#endif
return SPI_OK;
}
spi_status_t spi_setupChipReg(volatile avr32_spi_t *spi,
const spi_options_t *options,
unsigned int pba_hz)
{
u_avr32_spi_csr_t u_avr32_spi_csr;
if (options->spi_mode > 3 ||
options->stay_act > 1 ||
options->bits < 8 || options->bits > 16) {
return SPI_ERROR_ARGUMENT;
}
int baudDiv = getBaudDiv(options, pba_hz);
if (baudDiv < 0) {
return SPI_ERROR_ARGUMENT;
}
// Will use CSR0 offsets; these are the same for CSR0 to CSR3.
u_avr32_spi_csr.csr = 0;
u_avr32_spi_csr.CSR.cpol = options->spi_mode >> 1;
u_avr32_spi_csr.CSR.ncpha = (options->spi_mode & 0x1) ^ 0x1;
u_avr32_spi_csr.CSR.csaat = options->stay_act;
u_avr32_spi_csr.CSR.bits = options->bits - 8;
u_avr32_spi_csr.CSR.scbr = baudDiv;
u_avr32_spi_csr.CSR.dlybs = options->spck_delay;
u_avr32_spi_csr.CSR.dlybct = options->trans_delay;
switch(options->reg) {
case 0:
spi->csr0 = u_avr32_spi_csr.csr;
break;
case 1:
spi->csr1 = u_avr32_spi_csr.csr;
break;
case 2:
spi->csr2 = u_avr32_spi_csr.csr;
break;
case 3:
spi->csr3 = u_avr32_spi_csr.csr;
break;
default:
return SPI_ERROR_ARGUMENT;
}
#ifdef FREERTOS_USED
if (!xSPIMutex)
{
// Create the SPI mutex.
vSemaphoreCreateBinary(xSPIMutex);
if (!xSPIMutex)
{
while(1);
}
}
#endif
return SPI_OK;
}
void spi_enable(volatile avr32_spi_t *spi)
{
spi->cr = AVR32_SPI_CR_SPIEN_MASK;
}
void spi_disable(volatile avr32_spi_t *spi)
{
spi->cr = AVR32_SPI_CR_SPIDIS_MASK;
}
int spi_is_enabled(volatile avr32_spi_t *spi)
{
return (spi->sr & AVR32_SPI_SR_SPIENS_MASK) != 0;
}
inline unsigned char spi_writeRegisterEmptyCheck(volatile avr32_spi_t *spi)
{
return ((spi->sr & AVR32_SPI_SR_TDRE_MASK) != 0);
}
inline spi_status_t spi_write(volatile avr32_spi_t *spi, unsigned short data)
{
unsigned int timeout = SPI_TIMEOUT;
while (!(spi->sr & AVR32_SPI_SR_TDRE_MASK)) {
if (!timeout--) {
return SPI_ERROR_TIMEOUT;
}
}
spi->tdr = data << AVR32_SPI_TDR_TD_OFFSET;
return SPI_OK;
}
spi_status_t spi_variableSlaveWrite(volatile avr32_spi_t *spi, unsigned short data,
unsigned char pcs, unsigned char lastxfer)
{
unsigned int timeout = SPI_TIMEOUT;
if (pcs > 14 || lastxfer > 1) {
return SPI_ERROR_ARGUMENT;
}
while (!(spi->sr & AVR32_SPI_SR_TDRE_MASK)) {
if (!timeout--) {
return SPI_ERROR_TIMEOUT;
}
}
spi->tdr = (data << AVR32_SPI_TDR_TD_OFFSET) |
(pcs << AVR32_SPI_TDR_PCS_OFFSET) |
(lastxfer << AVR32_SPI_TDR_LASTXFER_OFFSET);
return SPI_OK;
}
inline unsigned char spi_writeEndCheck(volatile avr32_spi_t *spi)
{
return ((spi->sr & AVR32_SPI_SR_TXEMPTY_MASK) != 0);
}
unsigned char spi_readRegisterFullCheck(volatile avr32_spi_t *spi)
{
return ((spi->sr & AVR32_SPI_SR_RDRF_MASK) != 0);
}
inline spi_status_t spi_read(volatile avr32_spi_t *spi, unsigned short *data)
{
unsigned int timeout = SPI_TIMEOUT;
while ((spi->sr & (AVR32_SPI_SR_RDRF_MASK | AVR32_SPI_SR_TXEMPTY_MASK)) !=
(AVR32_SPI_SR_RDRF_MASK | AVR32_SPI_SR_TXEMPTY_MASK)) {
if (!timeout--) {
return SPI_ERROR_TIMEOUT;
}
}
*data = spi->rdr >> AVR32_SPI_RDR_RD_OFFSET;
return SPI_OK;
}
unsigned char spi_getStatus(volatile avr32_spi_t *spi)
{
spi_status_t ret = SPI_OK;
unsigned long sr = spi->sr;
if (sr & AVR32_SPI_SR_OVRES_MASK) {
ret = SPI_ERROR_OVERRUN;
}
if (sr & AVR32_SPI_SR_MODF_MASK) {
ret += SPI_ERROR_MODE_FAULT;
}
if (ret == (SPI_ERROR_OVERRUN + SPI_ERROR_MODE_FAULT)) {
return SPI_ERROR_OVERRUN_AND_MODE_FAULT;
}
else if (ret > 0) {
return ret;
} else {
return SPI_OK;
}
}

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@ -0,0 +1,342 @@
/* This header file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief SPI driver for AVR32 UC3.
*
* This file defines a useful set of functions for the SPI interface on AVR32
* devices.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with an SPI module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#ifndef _SPI_H_
#define _SPI_H_
#include <avr32/io.h>
//! Time-out value (number of attempts).
#define SPI_TIMEOUT 10000
//! Status codes used by the SPI driver.
typedef enum
{
SPI_ERROR = -1,
SPI_OK = 0,
SPI_ERROR_TIMEOUT = 1,
SPI_ERROR_ARGUMENT,
SPI_ERROR_OVERRUN,
SPI_ERROR_MODE_FAULT,
SPI_ERROR_OVERRUN_AND_MODE_FAULT
} spi_status_t;
//! Option structure for SPI channels.
typedef struct
{
//! The SPI channel to set up.
unsigned char reg;
//! Preferred baudrate for the SPI.
unsigned int baudrate;
//! Number of bits in each character (8 to 16).
unsigned char bits;
//! Delay before first clock pulse after selecting slave (in PBA clock periods).
unsigned char spck_delay;
//! Delay between each transfer/character (in PBA clock periods).
unsigned char trans_delay;
//! Sets this chip to stay active after last transfer to it.
unsigned char stay_act;
//! Which SPI mode to use when transmitting.
unsigned char spi_mode;
//! Disables the mode fault detection.
//! With this bit cleared, the SPI master mode will disable itself if another
//! master tries to address it.
unsigned char modfdis;
} spi_options_t;
/*! \brief Resets the SPI controller.
*
* \param spi Base address of the SPI instance.
*/
extern void spi_reset(volatile avr32_spi_t *spi);
/*! \brief Initializes the SPI in slave mode.
*
* \param spi Base address of the SPI instance.
* \param bits Number of bits in each transmitted character (8 to 16).
* \param spi_mode Clock polarity and phase.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_ARGUMENT Invalid argument(s) passed.
*/
extern spi_status_t spi_initSlave(volatile avr32_spi_t *spi,
unsigned char bits,
unsigned char spi_mode);
/*! \brief Sets up the SPI in a test mode where the transmitter is connected to
* the receiver (local loopback).
*
* \param spi Base address of the SPI instance.
*
* \return Status.
* \retval SPI_OK Success.
*/
extern spi_status_t spi_initTest(volatile avr32_spi_t *spi);
/*! \brief Initializes the SPI in master mode.
*
* \param spi Base address of the SPI instance.
* \param options Pointer to a structure containing initialization options.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_ARGUMENT Invalid argument(s) passed.
*/
extern spi_status_t spi_initMaster(volatile avr32_spi_t *spi, const spi_options_t *options);
/*! \brief Sets up how and when the slave chips are selected (master mode only).
*
* \param spi Base address of the SPI instance.
* \param variable_ps Target slave is selected in transfer register for every
* character to transmit.
* \param pcs_decode The four chip select lines are decoded externally. Values
* 0 to 14 can be given to \ref spi_selectChip.
* \param delay Delay in PBA periods between chip selects.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_ARGUMENT Invalid argument(s) passed.
*/
extern spi_status_t spi_selectionMode(volatile avr32_spi_t *spi,
unsigned char variable_ps,
unsigned char pcs_decode,
unsigned char delay);
/*! \brief Selects slave chip.
*
* \param spi Base address of the SPI instance.
* \param chip Slave chip number (normal: 0 to 3, extarnally decoded signal: 0
* to 14).
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_ARGUMENT Invalid argument(s) passed.
*/
extern spi_status_t spi_selectChip(volatile avr32_spi_t *spi, unsigned char chip);
/*! \brief Unselects slave chip.
*
* \param spi Base address of the SPI instance.
* \param chip Slave chip number (normal: 0 to 3, extarnally decoded signal: 0
* to 14).
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_TIMEOUT Time-out.
*
* \note Will block program execution until time-out occurs if last transmission
* is not complete. Invoke \ref spi_writeEndCheck beforehand if needed.
*/
extern spi_status_t spi_unselectChip(volatile avr32_spi_t *spi, unsigned char chip);
/*! \brief Sets options for a specific slave chip.
*
* The baudrate field has to be written before transfer in master mode. Four
* similar registers exist, one for each slave. When using encoded slave
* addressing, reg=0 sets options for slaves 0 to 3, reg=1 for slaves 4 to 7 and
* so on.
*
* \param spi Base address of the SPI instance.
* \param options Pointer to a structure containing initialization options for
* an SPI channel.
* \param pba_hz SPI module input clock frequency (PBA clock, Hz).
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_ARGUMENT Invalid argument(s) passed.
*/
extern spi_status_t spi_setupChipReg(volatile avr32_spi_t *spi,
const spi_options_t *options,
unsigned int pba_hz);
/*! \brief Enables the SPI.
*
* \param spi Base address of the SPI instance.
*/
extern void spi_enable(volatile avr32_spi_t *spi);
/*! \brief Disables the SPI.
*
* Ensures that nothing is transferred while setting up buffers.
*
* \param spi Base address of the SPI instance.
*
* \warning This may cause data loss if used on a slave SPI.
*/
extern void spi_disable(volatile avr32_spi_t *spi);
/*! \brief Tests if the SPI is enabled.
*
* \param spi Base address of the SPI instance.
*
* \return \c 1 if the SPI is enabled, otherwise \c 0.
*/
extern int spi_is_enabled(volatile avr32_spi_t *spi);
/*! \brief Checks if there is no data in the transmit register.
*
* \param spi Base address of the SPI instance.
*
* \return Status.
* \retval 1 No data in TDR.
* \retval 0 Some data in TDR.
*/
extern unsigned char spi_writeRegisterEmptyCheck(volatile avr32_spi_t *spi);
/*! \brief Writes one data word in master fixed peripheral select mode or in
* slave mode.
*
* \param spi Base address of the SPI instance.
* \param data The data word to write.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_TIMEOUT Time-out.
*
* \note Will block program execution until time-out occurs if transmitter is
* busy and transmit buffer is full. Invoke
* \ref spi_writeRegisterEmptyCheck beforehand if needed.
*
* \note Once the data has been written to the transmit buffer, the end of
* transmission is not waited for. Invoke \ref spi_writeEndCheck if
* needed.
*/
extern spi_status_t spi_write(volatile avr32_spi_t *spi, unsigned short data);
/*! \brief Selects a slave in master variable peripheral select mode and writes
* one data word to it.
*
* \param spi Base address of the SPI instance.
* \param data The data word to write.
* \param pcs Slave selector (bit 0 -> nCS line 0, bit 1 -> nCS line 1,
* etc.).
* \param lastxfer Boolean indicating whether this is the last data word
* transfer.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_TIMEOUT Time-out.
* \retval SPI_ERROR_ARGUMENT Invalid argument(s) passed.
*
* \note Will block program execution until time-out occurs if transmitter is
* busy and transmit buffer is full. Invoke
* \ref spi_writeRegisterEmptyCheck beforehand if needed.
*
* \note Once the data has been written to the transmit buffer, the end of
* transmission is not waited for. Invoke \ref spi_writeEndCheck if
* needed.
*/
extern spi_status_t spi_variableSlaveWrite(volatile avr32_spi_t *spi,
unsigned short data,
unsigned char pcs,
unsigned char lastxfer);
/*! \brief Checks if all transmissions are complete.
*
* \param spi Base address of the SPI instance.
*
* \return Status.
* \retval 1 All transmissions complete.
* \retval 0 Transmissions not complete.
*/
extern unsigned char spi_writeEndCheck(volatile avr32_spi_t *spi);
/*! \brief Checks if there is data in the receive register.
*
* \param spi Base address of the SPI instance.
*
* \return Status.
* \retval 1 Some data in RDR.
* \retval 0 No data in RDR.
*/
extern unsigned char spi_readRegisterFullCheck(volatile avr32_spi_t *spi);
/*! \brief Reads one data word in master mode or in slave mode.
*
* \param spi Base address of the SPI instance.
* \param data Pointer to the location where to store the received data word.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_TIMEOUT Time-out.
*
* \note Will block program execution until time-out occurs if no data is
* received or last transmission is not complete. Invoke
* \ref spi_writeEndCheck or \ref spi_readRegisterFullCheck beforehand if
* needed.
*/
extern spi_status_t spi_read(volatile avr32_spi_t *spi, unsigned short *data);
/*! \brief Gets status information from the SPI.
*
* \param spi Base address of the SPI instance.
*
* \return Status.
* \retval SPI_OK Success.
* \retval SPI_ERROR_OVERRUN Overrun error.
* \retval SPI_ERROR_MODE_FAULT Mode fault (SPI addressed as slave
* while in master mode).
* \retval SPI_ERROR_OVERRUN_AND_MODE_FAULT Overrun error and mode fault.
*/
extern unsigned char spi_getStatus(volatile avr32_spi_t *spi);
#endif // _SPI_H_

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@ -0,0 +1,314 @@
/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
*
* \brief TC driver for AVR32 UC3.
*
* AVR32 Timer/Counter driver module.
*
* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
* - Supported devices: All AVR32 devices with a TC module can be used.
* - AppNote:
*
* \author Atmel Corporation: http://www.atmel.com \n
* Support and FAQ: http://support.atmel.no/
*
******************************************************************************/
/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an Atmel
* AVR product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
*/
#include <avr32/io.h>
#include "compiler.h"
#include "tc.h"
int tc_get_interrupt_settings(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
return tc->channel[channel].imr;
}
int tc_configure_interrupts(volatile avr32_tc_t *tc, unsigned int channel, const tc_interrupt_t *bitfield)
{
Bool global_interrupt_enabled = Is_global_interrupt_enabled();
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// Enable the appropriate interrupts.
tc->channel[channel].ier = bitfield->etrgs << AVR32_TC_ETRGS_OFFSET |
bitfield->ldrbs << AVR32_TC_LDRBS_OFFSET |
bitfield->ldras << AVR32_TC_LDRAS_OFFSET |
bitfield->cpcs << AVR32_TC_CPCS_OFFSET |
bitfield->cpbs << AVR32_TC_CPBS_OFFSET |
bitfield->cpas << AVR32_TC_CPAS_OFFSET |
bitfield->lovrs << AVR32_TC_LOVRS_OFFSET |
bitfield->covfs << AVR32_TC_COVFS_OFFSET;
// Disable the appropriate interrupts.
if (global_interrupt_enabled) Disable_global_interrupt();
tc->channel[channel].idr = (~bitfield->etrgs & 1) << AVR32_TC_ETRGS_OFFSET |
(~bitfield->ldrbs & 1) << AVR32_TC_LDRBS_OFFSET |
(~bitfield->ldras & 1) << AVR32_TC_LDRAS_OFFSET |
(~bitfield->cpcs & 1) << AVR32_TC_CPCS_OFFSET |
(~bitfield->cpbs & 1) << AVR32_TC_CPBS_OFFSET |
(~bitfield->cpas & 1) << AVR32_TC_CPAS_OFFSET |
(~bitfield->lovrs & 1) << AVR32_TC_LOVRS_OFFSET |
(~bitfield->covfs & 1) << AVR32_TC_COVFS_OFFSET;
tc->channel[channel].sr;
if (global_interrupt_enabled) Enable_global_interrupt();
return 0;
}
int tc_select_external_clock(volatile avr32_tc_t *tc, unsigned int channel, unsigned int ext_clk_sig_src)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS || ext_clk_sig_src >= 1 << AVR32_TC_BMR_TC0XC0S_SIZE)
return TC_INVALID_ARGUMENT;
// Clear bit-field and set the correct behavior.
tc->bmr = (tc->bmr & ~(AVR32_TC_BMR_TC0XC0S_MASK << (channel * AVR32_TC_BMR_TC0XC0S_SIZE))) |
(ext_clk_sig_src << (channel * AVR32_TC_BMR_TC0XC0S_SIZE));
return 0;
}
int tc_init_capture(volatile avr32_tc_t *tc, const tc_capture_opt_t *opt)
{
// Check for valid input.
if (opt->channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// MEASURE SIGNALS: Capture operating mode.
tc->channel[opt->channel].cmr = opt->ldrb << AVR32_TC_LDRB_OFFSET |
opt->ldra << AVR32_TC_LDRA_OFFSET |
0 << AVR32_TC_WAVE_OFFSET |
opt->cpctrg << AVR32_TC_CPCTRG_OFFSET |
opt->abetrg << AVR32_TC_ABETRG_OFFSET |
opt->etrgedg << AVR32_TC_ETRGEDG_OFFSET|
opt->ldbdis << AVR32_TC_LDBDIS_OFFSET |
opt->ldbstop << AVR32_TC_LDBSTOP_OFFSET |
opt->burst << AVR32_TC_BURST_OFFSET |
opt->clki << AVR32_TC_CLKI_OFFSET |
opt->tcclks << AVR32_TC_TCCLKS_OFFSET;
return 0;
}
int tc_init_waveform(volatile avr32_tc_t *tc, const tc_waveform_opt_t *opt)
{
// Check for valid input.
if (opt->channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// GENERATE SIGNALS: Waveform operating mode.
tc->channel[opt->channel].cmr = opt->bswtrg << AVR32_TC_BSWTRG_OFFSET |
opt->beevt << AVR32_TC_BEEVT_OFFSET |
opt->bcpc << AVR32_TC_BCPC_OFFSET |
opt->bcpb << AVR32_TC_BCPB_OFFSET |
opt->aswtrg << AVR32_TC_ASWTRG_OFFSET |
opt->aeevt << AVR32_TC_AEEVT_OFFSET |
opt->acpc << AVR32_TC_ACPC_OFFSET |
opt->acpa << AVR32_TC_ACPA_OFFSET |
1 << AVR32_TC_WAVE_OFFSET |
opt->wavsel << AVR32_TC_WAVSEL_OFFSET |
opt->enetrg << AVR32_TC_ENETRG_OFFSET |
opt->eevt << AVR32_TC_EEVT_OFFSET |
opt->eevtedg << AVR32_TC_EEVTEDG_OFFSET |
opt->cpcdis << AVR32_TC_CPCDIS_OFFSET |
opt->cpcstop << AVR32_TC_CPCSTOP_OFFSET |
opt->burst << AVR32_TC_BURST_OFFSET |
opt->clki << AVR32_TC_CLKI_OFFSET |
opt->tcclks << AVR32_TC_TCCLKS_OFFSET;
return 0;
}
int tc_start(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// Enable, reset and start the selected timer/counter channel.
tc->channel[channel].ccr = AVR32_TC_SWTRG_MASK | AVR32_TC_CLKEN_MASK;
return 0;
}
int tc_stop(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// Disable the selected timer/counter channel.
tc->channel[channel].ccr = AVR32_TC_CLKDIS_MASK;
return 0;
}
int tc_software_trigger(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// Reset the selected timer/counter channel.
tc->channel[channel].ccr = AVR32_TC_SWTRG_MASK;
return 0;
}
void tc_sync_trigger(volatile avr32_tc_t *tc)
{
// Reset all channels of the selected timer/counter.
tc->bcr = AVR32_TC_BCR_SYNC_MASK;
}
void tc_sync_start(volatile avr32_tc_t *tc)
{
unsigned int i;
// Enable the clock for each channel.
for(i=0; i<TC_NUMBER_OF_CHANNELS;i++)
tc->channel[i].ccr = AVR32_TC_CLKEN_MASK;
// Reset all channels of the selected timer/counter.
tc->bcr = AVR32_TC_BCR_SYNC_MASK;
}
int tc_read_sr(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
return tc->channel[channel].sr;
}
int tc_read_tc(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
return Rd_bitfield(tc->channel[channel].cv, AVR32_TC_CV_MASK);
}
int tc_read_ra(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
return Rd_bitfield(tc->channel[channel].ra, AVR32_TC_RA_MASK);
}
int tc_read_rb(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
return Rd_bitfield(tc->channel[channel].rb, AVR32_TC_RB_MASK);
}
int tc_read_rc(volatile avr32_tc_t *tc, unsigned int channel)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
return Rd_bitfield(tc->channel[channel].rc, AVR32_TC_RC_MASK);
}
int tc_write_ra(volatile avr32_tc_t *tc, unsigned int channel, unsigned short value)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// This function is only available in WAVEFORM mode.
if (Tst_bits(tc->channel[channel].cmr, AVR32_TC_WAVE_MASK))
Wr_bitfield(tc->channel[channel].ra, AVR32_TC_RA_MASK, value);
return value;
}
int tc_write_rb(volatile avr32_tc_t *tc, unsigned int channel, unsigned short value)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// This function is only available in WAVEFORM mode.
if (Tst_bits(tc->channel[channel].cmr, AVR32_TC_WAVE_MASK))
Wr_bitfield(tc->channel[channel].rb, AVR32_TC_RB_MASK, value);
return value;
}
int tc_write_rc(volatile avr32_tc_t *tc, unsigned int channel, unsigned short value)
{
// Check for valid input.
if (channel >= TC_NUMBER_OF_CHANNELS)
return TC_INVALID_ARGUMENT;
// This function is only available in WAVEFORM mode.
if (Tst_bits(tc->channel[channel].cmr, AVR32_TC_WAVE_MASK))
Wr_bitfield(tc->channel[channel].rc, AVR32_TC_RC_MASK, value);
return value;
}

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