This is the original SDFileSystem but after performing an "update all"
Fork of SDFileSystem by
SDFileSystem.cpp
- Committer:
- neilt6
- Date:
- 2014-07-30
- Revision:
- 4:49b29888eca7
- Parent:
- 3:7cf3d1835ef5
- Child:
- 5:6befff2300d0
File content as of revision 4:49b29888eca7:
/* SD/MMC File System Library * Copyright (c) 2014 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 "CRC7.h" #include "CRC16.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_CD_ASSERT((int)cdtype) { //Initialize the member variables m_SpiFreq = hz; m_Status = STA_NOINIT; m_CardType = CARD_NONE; //Configure the SPI bus m_SPI.format(8, 0); //Configure the card detect pin m_CD.mode(PullUp); if (cdtype == SWITCH_NO) m_CD.rise(this, &SDFileSystem::checkSocket); else m_CD.fall(this, &SDFileSystem::checkSocket); } SDFileSystem::CardType SDFileSystem::card_type() { //Check the card socket checkSocket(); //If a card is present but not initialized, initialize it if (!(m_Status & STA_NODISK) && (m_Status & STA_NOINIT)) disk_initialize(); //Return the card type return m_CardType; } int SDFileSystem::disk_initialize() { char 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 100kHz for initialization m_SPI.frequency(100000); //Send 80 dummy clocks with /CS and DI held high m_CS = 1; for (int i = 0; i < 10; i++) m_SPI.write(0xFF); //Write CMD0(0), and check for a valid response resp = writeCommand(CMD0, 0); if (resp != 0x01) { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } //Write CMD8(0x000001AA) to see if this is an SDCv2 card resp = writeCommand(CMD8, 0x000001AA); if (resp == 0x01) { //This is an SDCv2 card, get the 32-bit return value and verify the voltage range/check pattern if ((readReturn() & 0xFFF) != 0x1AA) { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } //Send CMD58(0) to read the OCR, and verify that the card supports 3.2-3.3V resp = writeCommand(CMD58, 0); if (resp != 0x01 || !(readReturn() & (1 << 20))) { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } //Send ACMD41(0x40100000) repeatedly for up to 1 second to initialize the card for (int i = 0; i < 1000; i++) { resp = writeCommand(ACMD41, 0x40100000); if (resp != 0x01) break; wait_ms(1); } //Check if the card initialized if (resp != 0x00) { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } //Send CMD58(0) to read the OCR resp = writeCommand(CMD58, 0); if (resp == 0x00) { //Check the CCS bit to determine if this is a high capacity card if (readReturn() & 0x40000000) m_CardType = CARD_SDHC; else m_CardType = CARD_SD; } 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(0) to read the OCR, and verify that the card supports 3.2-3.3V resp = writeCommand(CMD58, 0); if (resp != 0x01 || !(readReturn() & (1 << 20))) { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } //Try to initialize the card using ACMD41(0x00100000) for 1 second for (int i = 0; i < 1000; i++) { resp = writeCommand(ACMD41, 0x00100000); if (resp != 0x01) break; wait_ms(1); } //Check if the card initialized if (resp == 0x00) { //This is an SDCv1 standard capacity card m_CardType = CARD_SD; } else { //Try to initialize the card using CMD1(0x00100000) for 1 second for (int i = 0; i < 1000; i++) { resp = writeCommand(CMD1, 0x00100000); if (resp != 0x01) break; wait_ms(1); } //Check if the card initialized if (resp == 0x00) { //This is an MMCv3 card m_CardType = CARD_MMC; } else { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } } } //Send CMD59(0x00000001) to re-enable CRC resp = writeCommand(CMD59, 0x00000001); if (resp != 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) { resp = writeCommand(CMD16, 0x00000200); if (resp != 0x00) { //Initialization failed m_CardType = CARD_UNKNOWN; return m_Status; } } //The card is now initialized m_Status &= ~STA_NOINIT; //Increase the SPI frequency to full speed (limited to 20MHz for MMC, or 25MHz for SDC) if (m_CardType == CARD_MMC && m_SpiFreq > 20000000) m_SPI.frequency(20000000); else if (m_SpiFreq > 25000000) m_SPI.frequency(25000000); else m_SPI.frequency(m_SpiFreq); //Return the device status return m_Status; } int SDFileSystem::disk_status() { //Check if there's a card in the socket checkSocket(); //Return the device status return m_Status; } int SDFileSystem::disk_read(uint8_t* buffer, uint64_t sector) { //Make sure the device is initialized before proceeding if (m_Status & STA_NOINIT) return RES_NOTRDY; //Convert from LBA to a byte address for standard capacity cards if (m_CardType != CARD_SDHC) sector *= 512; //Try to read the block up to 3 times for (int i = 0; i < 3; i++) { //Send CMD17(sector) to read a single block char resp = writeCommand(CMD17, sector); if (resp == 0x00) { //Try to read the sector, and return if successful if (readData((char*)buffer, 512)) return RES_OK; } else { //The command failed return RES_ERROR; } } //The read operation failed 3 times (CRC most likely) return RES_ERROR; } int SDFileSystem::disk_write(const uint8_t* buffer, uint64_t sector) { //Make sure the device is initialized before proceeding if (m_Status & STA_NOINIT) return RES_NOTRDY; //Make sure the device isn't write protected before proceeding if (m_Status & STA_PROTECT) return RES_WRPRT; //Convert from LBA to a byte address for older cards if (m_CardType != CARD_SDHC) sector *= 512; //Try to write the block up to 3 times for (int i = 0; i < 3; i++) { //Send CMD24(sector) to write a single block if (writeCommand(CMD24, sector) == 0x00) { //Wait for up to 500ms for the card to become ready if (!waitReady(500)) { //We timed out, deselect and loop again deselect(); continue; } //Send the write data token m_SPI.write(0xFE); //Write the data block from the buffer for (int b = 0; b < 512; b++) m_SPI.write(buffer[b]); //Calculate the CRC16 checksum for the data block and send it unsigned short crc = CRC16((char*)buffer, 512); m_SPI.write(crc >> 8); m_SPI.write(crc); //Receive the data response, and deselect the card char resp = m_SPI.write(0xFF) & 0x1F; deselect(); //Check the response if (resp == 0x05) return RES_OK; else if (resp == 0x0D) return RES_ERROR; } else { //The command failed return RES_ERROR; } } //The operation either timed out 3 times, failed the CRC check 3 times, or experienced a write error return RES_ERROR; } int SDFileSystem::disk_sync() { //Select the card so we're forced to wait for the end of any internal write processes bool ret = select(); deselect(); //Return success/failure return (ret) ? RES_OK : RES_ERROR; } uint64_t SDFileSystem::disk_sectors() { //Make sure the device is initialized before proceeding if (m_Status & STA_NOINIT) return 0; //Try to read the CSD register up to 3 times for (int i = 0; i < 3; i++) { //Send CMD9(0) to read the CSD register if (writeCommand(CMD9, 0) == 0x00) { //Receive the 16B CSD data char csd[16]; if (readData(csd, 16)) { //Calculate the sector count based on the card type if ((csd[0] >> 6) == 0x01) { //Calculate the sector count a high capacity card uint64_t sectors = (((csd[7] & 0x3F) << 16) | (csd[8] << 8) | csd[9]) + 1; return sectors << 10; } else { //Calculate the sector count standard capacity card uint64_t sectors = (((csd[6] & 0x03) << 10) | (csd[7] << 2) | ((csd[8] & 0xC0) >> 6)) + 1; sectors <<= ((((csd[9] & 0x03) << 1) | ((csd[10] & 0x80) >> 7)) + 2); sectors <<= (csd[5] & 0x0F); return sectors >> 9; } } } else { //The command failed return 0; } } //The read operation failed 3 times (CRC most likely) return 0; } void SDFileSystem::checkSocket() { //Check if a card is in the socket if (m_CD == m_CD_ASSERT) { //The socket is occupied, clear the STA_NODISK flag m_Status &= ~STA_NODISK; } else { //The socket is empty m_Status |= (STA_NODISK | STA_NOINIT); m_CardType = CARD_NONE; } } inline bool SDFileSystem::waitReady(int timeout) { //Wait for the specified timeout for the card to become ready for (int i = 0; i < timeout; i++) { if (m_SPI.write(0xFF) == 0xFF) return true; wait_ms(1); } //We timed out return false; } inline bool SDFileSystem::select() { //Pull /CS low m_CS = 0; //Send a dummy clock to enable DO m_SPI.write(0xFF); //Wait for up to 500ms for the card to become ready if (waitReady(500)) return true; //We timed out, deselect and return false deselect(); return false; } inline void SDFileSystem::deselect() { //Pull /CS high m_CS = 1; //Send a dummy byte to release DO m_SPI.write(0xFF); } char SDFileSystem::writeCommand(char cmd, unsigned int arg) { char resp; //Try to send the command up to 3 times for (int i = 0; i < 3; i++) { //Send CMD55 prior to an ACMD if (cmd == ACMD41) { resp = writeCommand(CMD55, 0); if (resp > 0x01) return resp; } //Select the card, and wait for ready 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; cmdPacket[5] = (CRC7(cmdPacket, 5) << 1) | 0x01; //Send the command packet for (int b = 0; b < 6; b++) m_SPI.write(cmdPacket[b]); //Allow up to 10 bytes of delay for the command response for (int b = 0; b < 10; b++) { resp = m_SPI.write(0xFF); if (!(resp & 0x80)) break; } //Deselect the card on errors, or if the transaction is finished if (resp > 0x01 || !(cmd == CMD8 || cmd == CMD9 || cmd == CMD17 || cmd == CMD24 || cmd == CMD55 || cmd == CMD58)) deselect(); //Return the response unless there were CRC errors if (resp == 0xFF || !(resp & (1 << 3))) return resp; } //The command failed 3 times due to CRC errors return 0xFF; } unsigned int SDFileSystem::readReturn() { unsigned int ret; //Read the 32-bit response value ret = (m_SPI.write(0xFF) << 24); ret |= (m_SPI.write(0xFF) << 16); ret |= (m_SPI.write(0xFF) << 8); ret |= m_SPI.write(0xFF); //Deselect the card deselect(); //Return the response value return ret; } bool SDFileSystem::readData(char* buffer, int length) { char token; //Wait for up to 200ms for the DataStart token to arrive for (int i = 0; i < 200; i++) { token = m_SPI.write(0xFF); if (token != 0xFF) break; wait_ms(1); } //Make sure the token is valid if (token != 0xFE) return false; //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, and deselect the card unsigned short crc = (m_SPI.write(0xFF) << 8); crc |= m_SPI.write(0xFF); deselect(); //Indicate whether the CRC16 checksum was valid or not if (crc == CRC16(buffer, length)) return true; else return false; }