Firmware2/Marlin/src/HAL/HAL_DUE/HAL_spi_Due.cpp

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2017-07-19 01:29:06 +02:00
/**
* Marlin 3D Printer Firmware
* Copyright (C) 2016 MarlinFirmware [https://github.com/MarlinFirmware/Marlin]
*
* Based on Sprinter and grbl.
* Copyright (C) 2011 Camiel Gubbels / Erik van der Zalm
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
*/
/**
* Software SPI functions originally from Arduino Sd2Card Library
* Copyright (C) 2009 by William Greiman
*/
/**
* Description: HAL for Arduino Due and compatible (SAM3X8E)
*
* For ARDUINO_ARCH_SAM
*/
#ifdef ARDUINO_ARCH_SAM
// --------------------------------------------------------------------------
// Includes
// --------------------------------------------------------------------------
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#include "../../inc/MarlinConfig.h"
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// --------------------------------------------------------------------------
// Public Variables
// --------------------------------------------------------------------------
// --------------------------------------------------------------------------
// Public functions
// --------------------------------------------------------------------------
#if ENABLED(SOFTWARE_SPI)
// --------------------------------------------------------------------------
// software SPI
// --------------------------------------------------------------------------
// bitbanging transfer
// run at ~100KHz (necessary for init)
static uint8_t spiTransfer(uint8_t b) { // using Mode 0
for (int bits = 0; bits < 8; bits++) {
if (b & 0x80) {
WRITE(MOSI_PIN, HIGH);
}
else {
WRITE(MOSI_PIN, LOW);
}
b <<= 1;
WRITE(SCK_PIN, HIGH);
delayMicroseconds(5U);
if (READ(MISO_PIN)) {
b |= 1;
}
WRITE(SCK_PIN, LOW);
delayMicroseconds(5U);
}
return b;
}
void spiBegin() {
SET_OUTPUT(SS_PIN);
WRITE(SS_PIN, HIGH);
SET_OUTPUT(SCK_PIN);
SET_INPUT(MISO_PIN);
SET_OUTPUT(MOSI_PIN);
}
void spiInit(uint8_t spiRate) {
UNUSED(spiRate);
WRITE(SS_PIN, HIGH);
WRITE(MOSI_PIN, HIGH);
WRITE(SCK_PIN, LOW);
}
uint8_t spiRec() {
WRITE(SS_PIN, LOW);
uint8_t b = spiTransfer(0xff);
WRITE(SS_PIN, HIGH);
return b;
}
void spiRead(uint8_t*buf, uint16_t nbyte) {
if (nbyte == 0) return;
WRITE(SS_PIN, LOW);
for (int i = 0; i < nbyte; i++) {
buf[i] = spiTransfer(0xff);
}
WRITE(SS_PIN, HIGH);
}
void spiSend(uint8_t b) {
WRITE(SS_PIN, LOW);
uint8_t response = spiTransfer(b);
UNUSED(response);
WRITE(SS_PIN, HIGH);
}
static void spiSend(const uint8_t* buf, size_t n) {
uint8_t response;
if (n == 0) return;
WRITE(SS_PIN, LOW);
for (uint16_t i = 0; i < n; i++) {
response = spiTransfer(buf[i]);
}
UNUSED(response);
WRITE(SS_PIN, HIGH);
}
void spiSendBlock(uint8_t token, const uint8_t* buf) {
uint8_t response;
WRITE(SS_PIN, LOW);
response = spiTransfer(token);
for (uint16_t i = 0; i < 512; i++) {
response = spiTransfer(buf[i]);
}
UNUSED(response);
WRITE(SS_PIN, HIGH);
}
#else
// --------------------------------------------------------------------------
// hardware SPI
// --------------------------------------------------------------------------
// 8.4 MHz, 4 MHz, 2 MHz, 1 MHz, 0.5 MHz, 0.329 MHz, 0.329 MHz
int spiDueDividors[] = { 10, 21, 42, 84, 168, 255, 255 };
bool spiInitMaded = false;
void spiBegin() {
if(spiInitMaded == false) {
// Configure SPI pins
PIO_Configure(
g_APinDescription[SCK_PIN].pPort,
g_APinDescription[SCK_PIN].ulPinType,
g_APinDescription[SCK_PIN].ulPin,
g_APinDescription[SCK_PIN].ulPinConfiguration);
PIO_Configure(
g_APinDescription[MOSI_PIN].pPort,
g_APinDescription[MOSI_PIN].ulPinType,
g_APinDescription[MOSI_PIN].ulPin,
g_APinDescription[MOSI_PIN].ulPinConfiguration);
PIO_Configure(
g_APinDescription[MISO_PIN].pPort,
g_APinDescription[MISO_PIN].ulPinType,
g_APinDescription[MISO_PIN].ulPin,
g_APinDescription[MISO_PIN].ulPinConfiguration);
// set master mode, peripheral select, fault detection
SPI_Configure(SPI0, ID_SPI0, SPI_MR_MSTR | SPI_MR_MODFDIS | SPI_MR_PS);
SPI_Enable(SPI0);
#if MB(ALLIGATOR)
SET_OUTPUT(DAC0_SYNC);
#if EXTRUDERS > 1
SET_OUTPUT(DAC1_SYNC);
WRITE(DAC1_SYNC, HIGH);
#endif
SET_OUTPUT(SPI_EEPROM1_CS);
SET_OUTPUT(SPI_EEPROM2_CS);
SET_OUTPUT(SPI_FLASH_CS);
WRITE(DAC0_SYNC, HIGH);
WRITE(SPI_EEPROM1_CS, HIGH );
WRITE(SPI_EEPROM2_CS, HIGH );
WRITE(SPI_FLASH_CS, HIGH );
WRITE(SS_PIN, HIGH );
#endif // MB(ALLIGATOR)
PIO_Configure(
g_APinDescription[SPI_PIN].pPort,
g_APinDescription[SPI_PIN].ulPinType,
g_APinDescription[SPI_PIN].ulPin,
g_APinDescription[SPI_PIN].ulPinConfiguration);
spiInit(1);
spiInitMaded = true;
}
}
void spiInit(uint8_t spiRate) {
if(spiInitMaded == false) {
if(spiRate > 6) spiRate = 1;
#if MB(ALLIGATOR)
// Set SPI mode 1, clock, select not active after transfer, with delay between transfers
SPI_ConfigureNPCS(SPI0, SPI_CHAN_DAC,
SPI_CSR_CSAAT | SPI_CSR_SCBR(spiDueDividors[spiRate]) |
SPI_CSR_DLYBCT(1));
// Set SPI mode 0, clock, select not active after transfer, with delay between transfers
SPI_ConfigureNPCS(SPI0, SPI_CHAN_EEPROM1, SPI_CSR_NCPHA |
SPI_CSR_CSAAT | SPI_CSR_SCBR(spiDueDividors[spiRate]) |
SPI_CSR_DLYBCT(1));
#endif//MB(ALLIGATOR)
// Set SPI mode 0, clock, select not active after transfer, with delay between transfers
SPI_ConfigureNPCS(SPI0, SPI_CHAN, SPI_CSR_NCPHA |
SPI_CSR_CSAAT | SPI_CSR_SCBR(spiDueDividors[spiRate]) |
SPI_CSR_DLYBCT(1));
SPI_Enable(SPI0);
spiInitMaded = true;
}
}
// Write single byte to SPI
void spiSend(byte b) {
// write byte with address and end transmission flag
SPI0->SPI_TDR = (uint32_t)b | SPI_PCS(SPI_CHAN) | SPI_TDR_LASTXFER;
// wait for transmit register empty
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
// wait for receive register
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
// clear status
SPI0->SPI_RDR;
//delayMicroseconds(1U);
}
void spiSend(const uint8_t* buf, size_t n) {
if (n == 0) return;
for (size_t i = 0; i < n - 1; i++) {
SPI0->SPI_TDR = (uint32_t)buf[i] | SPI_PCS(SPI_CHAN);
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
SPI0->SPI_RDR;
//delayMicroseconds(1U);
}
spiSend(buf[n - 1]);
}
void spiSend(uint32_t chan, byte b) {
uint8_t dummy_read = 0;
// wait for transmit register empty
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
// write byte with address and end transmission flag
SPI0->SPI_TDR = (uint32_t)b | SPI_PCS(chan) | SPI_TDR_LASTXFER;
// wait for receive register
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
// clear status
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 1)
dummy_read = SPI0->SPI_RDR;
UNUSED(dummy_read);
}
void spiSend(uint32_t chan, const uint8_t* buf, size_t n) {
uint8_t dummy_read = 0;
if (n == 0) return;
for (int i = 0; i < (int)n - 1; i++) {
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
SPI0->SPI_TDR = (uint32_t)buf[i] | SPI_PCS(chan);
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 1)
dummy_read = SPI0->SPI_RDR;
UNUSED(dummy_read);
}
spiSend(chan, buf[n - 1]);
}
// Read single byte from SPI
uint8_t spiRec() {
// write dummy byte with address and end transmission flag
SPI0->SPI_TDR = 0x000000FF | SPI_PCS(SPI_CHAN) | SPI_TDR_LASTXFER;
// wait for transmit register empty
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
// wait for receive register
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
// get byte from receive register
//delayMicroseconds(1U);
return SPI0->SPI_RDR;
}
uint8_t spiRec(uint32_t chan) {
uint8_t spirec_tmp;
// wait for transmit register empty
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 1)
spirec_tmp = SPI0->SPI_RDR;
UNUSED(spirec_tmp);
// write dummy byte with address and end transmission flag
SPI0->SPI_TDR = 0x000000FF | SPI_PCS(chan) | SPI_TDR_LASTXFER;
// wait for receive register
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
// get byte from receive register
return SPI0->SPI_RDR;
}
// Read from SPI into buffer
void spiRead(uint8_t*buf, uint16_t nbyte) {
if (nbyte-- == 0) return;
for (int i = 0; i < nbyte; i++) {
//while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
SPI0->SPI_TDR = 0x000000FF | SPI_PCS(SPI_CHAN);
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
buf[i] = SPI0->SPI_RDR;
//delayMicroseconds(1U);
}
buf[nbyte] = spiRec();
}
// Write from buffer to SPI
void spiSendBlock(uint8_t token, const uint8_t* buf) {
SPI0->SPI_TDR = (uint32_t)token | SPI_PCS(SPI_CHAN);
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
//while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
//SPI0->SPI_RDR;
for (int i = 0; i < 511; i++) {
SPI0->SPI_TDR = (uint32_t)buf[i] | SPI_PCS(SPI_CHAN);
while ((SPI0->SPI_SR & SPI_SR_TDRE) == 0);
while ((SPI0->SPI_SR & SPI_SR_RDRF) == 0);
SPI0->SPI_RDR;
//delayMicroseconds(1U);
}
spiSend(buf[511]);
}
#endif // ENABLED(SOFTWARE_SPI)
#endif // ARDUINO_ARCH_SAM