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Dependencies: FATFileSystem
Dependents: AutoFlight2017_now2 AutoFlight2018_Control sbus_test_2018 Autoflight2018_sbusread ... more
SDFileSystem.cpp
- Committer:
- TUATBM
- Date:
- 2017-08-26
- Revision:
- 0:85fbe134acff
File content as of revision 0:85fbe134acff:
/* SD/MMC File System Library
* Copyright (c) 2016 Neil Thiessen
*
* 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
* 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.
*/
#include "SDFileSystem.h"
#include "diskio.h"
#include "pinmap.h"
#include "SDCRC.h"
SDFileSystem::SDFileSystem(PinName mosi, PinName miso, PinName sclk, PinName cs, const char* name, PinName cd, SwitchType cdtype, int hz)
: FATFileSystem(name),
m_Spi(mosi, miso, sclk),
m_Cs(cs, 1),
m_Cd(cd),
m_FREQ(hz)
{
//Initialize the member variables
m_CardType = CARD_NONE;
m_Crc = true;
m_LargeFrames = false;
m_WriteValidation = true;
m_Status = STA_NOINIT;
//Enable the internal pull-up resistor on MISO
pin_mode(miso, PullUp);
//Configure the SPI bus
m_Spi.format(8, 0);
//Configure the card detect pin
if (cdtype == SWITCH_POS_NO) {
m_Cd.mode(PullDown);
m_CdAssert = 1;
m_Cd.fall(this, &SDFileSystem::onCardRemoval);
} else if (cdtype == SWITCH_POS_NC) {
m_Cd.mode(PullDown);
m_CdAssert = 0;
m_Cd.rise(this, &SDFileSystem::onCardRemoval);
} else if (cdtype == SWITCH_NEG_NO) {
m_Cd.mode(PullUp);
m_CdAssert = 0;
m_Cd.rise(this, &SDFileSystem::onCardRemoval);
} else if (cdtype == SWITCH_NEG_NC) {
m_Cd.mode(PullUp);
m_CdAssert = 1;
m_Cd.fall(this, &SDFileSystem::onCardRemoval);
} else {
m_CdAssert = -1;
}
}
bool SDFileSystem::card_present()
{
//Check the card socket
checkSocket();
//Return whether or not a card is present
return !(m_Status & STA_NODISK);
}
SDFileSystem::CardType SDFileSystem::card_type()
{
//Check the card socket
checkSocket();
//Return the card type
return m_CardType;
}
bool SDFileSystem::crc()
{
//Return whether or not CRC is enabled
return m_Crc;
}
void SDFileSystem::crc(bool enabled)
{
//Check the card socket
checkSocket();
//Just update the member variable if the card isn't initialized
if (m_Status & STA_NOINIT) {
m_Crc = enabled;
return;
}
//Enable or disable CRC
if (enabled && !m_Crc) {
//Send CMD59(0x00000001) to enable CRC
m_Crc = true;
commandTransaction(CMD59, 0x00000001);
} else if (!enabled && m_Crc) {
//Send CMD59(0x00000000) to disable CRC
commandTransaction(CMD59, 0x00000000);
m_Crc = false;
}
}
bool SDFileSystem::large_frames()
{
//Return whether or not 16-bit frames are enabled
return m_LargeFrames;
}
void SDFileSystem::large_frames(bool enabled)
{
//Set whether or not 16-bit frames are enabled
m_LargeFrames = enabled;
}
bool SDFileSystem::write_validation()
{
//Return whether or not write validation is enabled
return m_WriteValidation;
}
void SDFileSystem::write_validation(bool enabled)
{
//Set whether or not write validation is enabled
m_WriteValidation = enabled;
}
int SDFileSystem::unmount()
{
//Unmount the filesystem
FATFileSystem::unmount();
//Change the status to not initialized, and the card type to unknown
m_Status |= STA_NOINIT;
m_CardType = CARD_UNKNOWN;
//Always succeeds
return 0;
}
int SDFileSystem::disk_initialize()
{
char token;
unsigned int resp;
//Make sure there's a card in the socket before proceeding
checkSocket();
if (m_Status & STA_NODISK)
return m_Status;
//Make sure we're not already initialized before proceeding
if (!(m_Status & STA_NOINIT))
return m_Status;
//Set the SPI frequency to 400kHz for initialization
m_Spi.frequency(400000);
//Send 80 dummy clocks with /CS deasserted and DI held high
m_Cs = 1;
for (int i = 0; i < 10; i++)
m_Spi.write(0xFF);
//Send CMD0(0x00000000) to reset the card
if (commandTransaction(CMD0, 0x00000000) != 0x01) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
//Send CMD59(0x00000001) to enable CRC if necessary
if (m_Crc) {
if (commandTransaction(CMD59, 0x00000001) != 0x01) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
}
//Send CMD8(0x000001AA) to see if this is an SDCv2 card
if (commandTransaction(CMD8, 0x000001AA, &resp) == 0x01) {
//This is an SDCv2 card, get the 32-bit return value and verify the voltage range/check pattern
if ((resp & 0xFFF) != 0x1AA) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
//Send CMD58(0x00000000) to read the OCR, and verify that the card supports 3.2-3.3V
if (commandTransaction(CMD58, 0x00000000, &resp) != 0x01 || !(resp & (1 << 20))) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
//Try to initialize the card using ACMD41(0x00100000)
for (int i = 0; i < 1000; i++) {
token = commandTransaction(ACMD41, 0x40100000);
if (token != 0x01) {
break;
}
}
//Check if the card initialized
if (token != 0x00) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
//Send CMD58(0x00000000) to read the OCR
if (commandTransaction(CMD58, 0x00000000, &resp) == 0x00) {
//Check the CCS bit to determine if this is a high capacity card
if (resp & (1 << 30))
m_CardType = CARD_SDHC;
else
m_CardType = CARD_SD;
//Increase the SPI frequency to full speed (up to 25MHz for SDCv2)
if (m_FREQ > 25000000)
m_Spi.frequency(25000000);
else
m_Spi.frequency(m_FREQ);
} else {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
} else {
//Didn't respond or illegal command, this is either an SDCv1 or MMC card
//Send CMD58(0x00000000) to read the OCR, and verify that the card supports 3.2-3.3V
if (commandTransaction(CMD58, 0x00000000, &resp) != 0x01 || !(resp & (1 << 20))) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
//Try to initialize the card using ACMD41(0x00100000)
for (int i = 0; i < 1000; i++) {
token = commandTransaction(ACMD41, 0x40100000);
if (token != 0x01) {
break;
}
}
//Check if the card initialized
if (token == 0x00) {
//This is an SDCv1 standard capacity card
m_CardType = CARD_SD;
//Increase the SPI frequency to full speed (up to 25MHz for SDCv1)
if (m_FREQ > 25000000)
m_Spi.frequency(25000000);
else
m_Spi.frequency(m_FREQ);
} else {
//Try to initialize the card using CMD1(0x00100000)
for (int i = 0; i < 1000; i++) {
token = commandTransaction(CMD1, 0x00100000);
if (token != 0x01) {
break;
}
}
//Check if the card initialized
if (token == 0x00) {
//This is an MMCv3 card
m_CardType = CARD_MMC;
//Increase the SPI frequency to full speed (up to 20MHz for MMCv3)
if (m_FREQ > 20000000)
m_Spi.frequency(20000000);
else
m_Spi.frequency(m_FREQ);
} else {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
}
}
//Send ACMD42(0x00000000) to disconnect the internal pull-up resistor on pin 1 if necessary
if (m_CardType != CARD_MMC) {
if (commandTransaction(ACMD42, 0x00000000) != 0x00) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
}
//Send CMD16(0x00000200) to force the block size to 512B if necessary
if (m_CardType != CARD_SDHC) {
if (commandTransaction(CMD16, 0x00000200) != 0x00) {
//Initialization failed
m_CardType = CARD_UNKNOWN;
return m_Status;
}
}
//The card is now initialized
m_Status &= ~STA_NOINIT;
//Return the disk status
return m_Status;
}
int SDFileSystem::disk_status()
{
//Check the card socket
checkSocket();
//Return the disk status
return m_Status;
}
int SDFileSystem::disk_read(uint8_t* buffer, uint32_t sector, uint32_t count)
{
//Make sure the card is initialized before proceeding
if (m_Status & STA_NOINIT)
return RES_NOTRDY;
//Read a single block, or multiple blocks
if (count > 1) {
return readBlocks((char*)buffer, sector, count) ? RES_OK : RES_ERROR;
} else {
return readBlock((char*)buffer, sector) ? RES_OK : RES_ERROR;
}
}
int SDFileSystem::disk_write(const uint8_t* buffer, uint32_t sector, uint32_t count)
{
//Make sure the card is initialized before proceeding
if (m_Status & STA_NOINIT)
return RES_NOTRDY;
//Make sure the card isn't write protected before proceeding
if (m_Status & STA_PROTECT)
return RES_WRPRT;
//Write a single block, or multiple blocks
if (count > 1) {
return writeBlocks((const char*)buffer, sector, count) ? RES_OK : RES_ERROR;
} else {
return writeBlock((const char*)buffer, sector) ? RES_OK : RES_ERROR;
}
}
int SDFileSystem::disk_sync()
{
//Select the card so we're forced to wait for the end of any internal write processes
if (select()) {
deselect();
return RES_OK;
} else {
return RES_ERROR;
}
}
uint32_t SDFileSystem::disk_sectors()
{
//Make sure the card is initialized before proceeding
if (m_Status & STA_NOINIT)
return 0;
//Try to read the CSD register up to 3 times
for (int f = 0; f < 3; f++) {
//Select the card, and wait for ready
if(!select())
break;
//Send CMD9(0x00000000) to read the CSD register
if (writeCommand(CMD9, 0x00000000) == 0x00) {
//Read the 16B CSD data block
char csd[16];
bool success = readData(csd, 16);
deselect();
if (success) {
//Calculate the sector count based on the card type
if ((csd[0] >> 6) == 0x01) {
//Calculate the sector count for a high capacity card
unsigned int size = (((csd[7] & 0x3F) << 16) | (csd[8] << 8) | csd[9]) + 1;
return size << 10;
} else {
//Calculate the sector count for a standard capacity card
unsigned int size = (((csd[6] & 0x03) << 10) | (csd[7] << 2) | ((csd[8] & 0xC0) >> 6)) + 1;
size <<= ((((csd[9] & 0x03) << 1) | ((csd[10] & 0x80) >> 7)) + 2);
size <<= (csd[5] & 0x0F);
return size >> 9;
}
}
} else {
//The command failed, get out
break;
}
}
//The read operation failed 3 times
deselect();
return 0;
}
void SDFileSystem::onCardRemoval()
{
//Check the card socket
checkSocket();
}
inline void SDFileSystem::checkSocket()
{
//Use the card detect switch (if available) to determine if the socket is occupied
if (m_CdAssert != -1) {
if (m_Status & STA_NODISK) {
if (m_Cd == m_CdAssert) {
//The socket is now occupied
m_Status &= ~STA_NODISK;
m_CardType = CARD_UNKNOWN;
}
} else {
if (m_Cd != m_CdAssert) {
//The socket is now empty
m_Status |= (STA_NODISK | STA_NOINIT);
m_CardType = CARD_NONE;
}
}
}
}
inline bool SDFileSystem::waitReady(int timeout)
{
char resp;
//Keep sending dummy clocks with DI held high until the card releases the DO line
m_Timer.start();
do {
resp = m_Spi.write(0xFF);
} while (resp == 0x00 && m_Timer.read_ms() < timeout);
m_Timer.stop();
m_Timer.reset();
//Return success/failure
return (resp > 0x00);
}
inline bool SDFileSystem::select()
{
//Assert /CS
m_Cs = 0;
//Send 8 dummy clocks with DI held high to enable DO
m_Spi.write(0xFF);
//Wait for up to 500ms for the card to become ready
if (waitReady(500)) {
return true;
} else {
//We timed out, deselect and return false
deselect();
return false;
}
}
inline void SDFileSystem::deselect()
{
//Deassert /CS
m_Cs = 1;
//Send 8 dummy clocks with DI held high to disable DO
m_Spi.write(0xFF);
}
inline char SDFileSystem::commandTransaction(char cmd, unsigned int arg, unsigned int* resp)
{
//Select the card, and wait for ready
if(!select())
return 0xFF;
//Perform the command transaction
char token = writeCommand(cmd, arg, resp);
//Deselect the card, and return the R1 response token
deselect();
return token;
}
char SDFileSystem::writeCommand(char cmd, unsigned int arg, unsigned int* resp)
{
char token;
//Try to send the command up to 3 times
for (int f = 0; f < 3; f++) {
//Send CMD55(0x00000000) prior to an application specific command
if (cmd == ACMD22 || cmd == ACMD23 || cmd == ACMD41 || cmd == ACMD42) {
token = writeCommand(CMD55, 0x00000000);
if (token > 0x01)
return token;
//Deselect and reselect the card between CMD55 and an ACMD
deselect();
if(!select())
return 0xFF;
}
//Prepare the command packet
char cmdPacket[6];
cmdPacket[0] = cmd;
cmdPacket[1] = arg >> 24;
cmdPacket[2] = arg >> 16;
cmdPacket[3] = arg >> 8;
cmdPacket[4] = arg;
if (m_Crc || cmd == CMD0 || cmd == CMD8)
cmdPacket[5] = (SDCRC::crc7(cmdPacket, 5) << 1) | 0x01;
else
cmdPacket[5] = 0x01;
//Send the command packet
for (int i = 0; i < 6; i++)
m_Spi.write(cmdPacket[i]);
//Discard the stuff byte immediately following CMD12
if (cmd == CMD12)
m_Spi.write(0xFF);
//Allow up to 8 bytes of delay for the R1 response token
for (int i = 0; i < 9; i++) {
token = m_Spi.write(0xFF);
if (!(token & 0x80))
break;
}
//Verify the R1 response token
if (token == 0xFF) {
//No data was received, get out early
break;
} else if (token & (1 << 3)) {
//There was a CRC error, try again
continue;
} else if (token > 0x01) {
//An error occured, get out early
break;
}
//Handle R2 and R3/R7 response tokens
if (cmd == CMD13 && resp != NULL) {
//Read the R2 response value
*resp = m_Spi.write(0xFF);
} else if ((cmd == CMD8 || cmd == CMD58) && resp != NULL) {
//Read the R3/R7 response value
*resp = (m_Spi.write(0xFF) << 24);
*resp |= (m_Spi.write(0xFF) << 16);
*resp |= (m_Spi.write(0xFF) << 8);
*resp |= m_Spi.write(0xFF);
}
//The command was successful
break;
}
//Return the R1 response token
return token;
}
bool SDFileSystem::readData(char* buffer, int length)
{
char token;
unsigned short crc;
//Wait for up to 500ms for a token to arrive
m_Timer.start();
do {
token = m_Spi.write(0xFF);
} while (token == 0xFF && m_Timer.read_ms() < 500);
m_Timer.stop();
m_Timer.reset();
//Check if a valid start block token was received
if (token != 0xFE)
return false;
//Check if large frames are enabled or not
if (m_LargeFrames) {
//Switch to 16-bit frames for better performance
m_Spi.format(16, 0);
//Read the data block into the buffer
unsigned short dataWord;
for (int i = 0; i < length; i += 2) {
dataWord = m_Spi.write(0xFFFF);
buffer[i] = dataWord >> 8;
buffer[i + 1] = dataWord;
}
//Read the CRC16 checksum for the data block
crc = m_Spi.write(0xFFFF);
//Switch back to 8-bit frames
m_Spi.format(8, 0);
} else {
//Read the data into the buffer
for (int i = 0; i < length; i++)
buffer[i] = m_Spi.write(0xFF);
//Read the CRC16 checksum for the data block
crc = (m_Spi.write(0xFF) << 8);
crc |= m_Spi.write(0xFF);
}
//Return the validity of the CRC16 checksum (if enabled)
return (!m_Crc || crc == SDCRC::crc16(buffer, length));
}
char SDFileSystem::writeData(const char* buffer, char token)
{
//Calculate the CRC16 checksum for the data block (if enabled)
unsigned short crc = (m_Crc) ? SDCRC::crc16(buffer, 512) : 0xFFFF;
//Wait for up to 500ms for the card to become ready
if (!waitReady(500))
return false;
//Send the start block token
m_Spi.write(token);
//Check if large frames are enabled or not
if (m_LargeFrames) {
//Switch to 16-bit frames for better performance
m_Spi.format(16, 0);
//Write the data block from the buffer
for (int i = 0; i < 512; i += 2)
m_Spi.write((buffer[i] << 8) | buffer[i + 1]);
//Send the CRC16 checksum for the data block
m_Spi.write(crc);
//Switch back to 8-bit frames
m_Spi.format(8, 0);
} else {
//Write the data block from the buffer
for (int i = 0; i < 512; i++)
m_Spi.write(buffer[i]);
//Send the CRC16 checksum for the data block
m_Spi.write(crc >> 8);
m_Spi.write(crc);
}
//Return the data response token
return (m_Spi.write(0xFF) & 0x1F);
}
inline bool SDFileSystem::readBlock(char* buffer, unsigned int lba)
{
//Try to read the block up to 3 times
for (int f = 0; f < 3; f++) {
//Select the card, and wait for ready
if(!select())
break;
//Send CMD17(block) to read a single block
if (writeCommand(CMD17, (m_CardType == CARD_SDHC) ? lba : lba << 9) == 0x00) {
//Try to read the block, and deselect the card
bool success = readData(buffer, 512);
deselect();
//Return if successful
if (success)
return true;
} else {
//The command failed, get out
break;
}
}
//The single block read failed
deselect();
return false;
}
inline bool SDFileSystem::readBlocks(char* buffer, unsigned int lba, unsigned int count)
{
//Try to read each block up to 3 times
for (int f = 0; f < 3;) {
//Select the card, and wait for ready
if(!select())
break;
//Send CMD18(block) to read multiple blocks
if (writeCommand(CMD18, (m_CardType == CARD_SDHC) ? lba : lba << 9) == 0x00) {
//Try to read all of the data blocks
do {
//Read the next block, and break on errors
if (!readData(buffer, 512)) {
f++;
break;
}
//Update the variables
lba++;
buffer += 512;
f = 0;
} while (--count);
//Send CMD12(0x00000000) to stop the transmission
if (writeCommand(CMD12, 0x00000000) != 0x00) {
//The command failed, get out
break;
}
//Deselect the card, and return if successful
deselect();
if (count == 0)
return true;
} else {
//The command failed, get out
break;
}
}
//The multiple block read failed
deselect();
return false;
}
inline bool SDFileSystem::writeBlock(const char* buffer, unsigned int lba)
{
//Try to write the block up to 3 times
for (int f = 0; f < 3; f++) {
//Select the card, and wait for ready
if(!select())
break;
//Send CMD24(block) to write a single block
if (writeCommand(CMD24, (m_CardType == CARD_SDHC) ? lba : lba << 9) == 0x00) {
//Try to write the block, and deselect the card
char token = writeData(buffer, 0xFE);
deselect();
//Check the data response token
if (token == 0x0A) {
//A CRC error occured, try again
continue;
} else if (token == 0x0C) {
//A write error occured, get out
break;
}
//Send CMD13(0x00000000) to verify that the programming was successful if enabled
if (m_WriteValidation) {
unsigned int resp;
if (commandTransaction(CMD13, 0x00000000, &resp) != 0x00 || resp != 0x00) {
//Some manner of unrecoverable write error occured during programming, get out
break;
}
}
//The data was written successfully
return true;
} else {
//The command failed, get out
break;
}
}
//The single block write failed
deselect();
return false;
}
inline bool SDFileSystem::writeBlocks(const char* buffer, unsigned int lba, unsigned int count)
{
char token;
const char* currentBuffer = buffer;
unsigned int currentLba = lba;
int currentCount = count;
//Try to write each block up to 3 times
for (int f = 0; f < 3;) {
//If this is an SD card, send ACMD23(count) to set the number of blocks to pre-erase
if (m_CardType != CARD_MMC) {
if (commandTransaction(ACMD23, currentCount) != 0x00) {
//The command failed, get out
break;
}
}
//Select the card, and wait for ready
if(!select())
break;
//Send CMD25(block) to write multiple blocks
if (writeCommand(CMD25, (m_CardType == CARD_SDHC) ? currentLba : currentLba << 9) == 0x00) {
//Try to write all of the data blocks
do {
//Write the next block and break on errors
token = writeData(currentBuffer, 0xFC);
if (token != 0x05) {
f++;
break;
}
//Update the variables
currentBuffer += 512;
f = 0;
} while (--currentCount);
//Wait for up to 500ms for the card to finish processing the last block
if (!waitReady(500))
break;
//Finalize the transmission
if (currentCount == 0) {
//Send the stop tran token, and deselect the card
m_Spi.write(0xFD);
deselect();
//Send CMD13(0x00000000) to verify that the programming was successful if enabled
if (m_WriteValidation) {
unsigned int resp;
if (commandTransaction(CMD13, 0x00000000, &resp) != 0x00 || resp != 0x00) {
//Some manner of unrecoverable write error occured during programming, get out
break;
}
}
//The data was written successfully
return true;
} else {
//Send CMD12(0x00000000) to abort the transmission
if (writeCommand(CMD12, 0x00000000) != 0x00) {
//The command failed, get out
break;
}
//Deselect the card
deselect();
//Check the error token
if (token == 0x0A) {
//Determine the number of well written blocks if possible
unsigned int writtenBlocks = 0;
if (m_CardType != CARD_MMC && select()) {
//Send ACMD22(0x00000000) to get the number of well written blocks
if (writeCommand(ACMD22, 0x00000000) == 0x00) {
//Read the data
char acmdData[4];
if (readData(acmdData, 4)) {
//Extract the number of well written blocks
writtenBlocks = acmdData[0] << 24;
writtenBlocks |= acmdData[1] << 16;
writtenBlocks |= acmdData[2] << 8;
writtenBlocks |= acmdData[3];
}
}
deselect();
}
//Roll back the variables based on the number of well written blocks
currentBuffer = buffer + (writtenBlocks << 9);
currentLba = lba + writtenBlocks;
currentCount = count - writtenBlocks;
//Try again
continue;
} else {
//A write error occured, get out
break;
}
}
} else {
//The command failed, get out
break;
}
}
//The multiple block write failed
deselect();
return false;
}