karelv
Using the USBFileSystem class to provide SD-card with USBMSD and FATFileSystem support at same time.
Dependents: SD_USB_FS_HelloWorld
See also helloworld program at http://mbed.org/users/karelv/code/SD_USB_FS_HelloWorld/
Created based on:
- comment from Erik Olieman. forum
- USBMSD_SD library for the spi-access to SD-card. (no dependency but spi-access code is copied) USBMSD_SD
- USBFileSystem libary USBFileSystem
Information
My win7 pc always disconnect/connect the drive and at disconnect it also closes the explorer which show the content of that drive. It does the same with the editor that has the file opened.
Quote:
(by Erik Olieman)
You are correct that that is what happens, got the same on windows 8. The problem is that windows (and probably every other OS) is quite heavy on caching of USB drives. So it reads the data ones, and after that it only writes and assumes its commands have been performed. For example if you have a drive with a bunch of files, and I enable write protection on the library, you can still happily delete the file and windows will tell you it is gone. You can make new files and windows will tell you they are created. Despite nothing actually being done. So the only way to force a refresh is disconnecting/reconnecting. Well not entirely true, I found out if you are writing custom programs you can disable this caching behavior after alot of digging. But in principle it is always on, and you have to reconnect the device. An alternative file browser might have other behavior, but dunno.
So the TL;DR: It is OS behavior that the program can't do anything about. Initially I intended to just use write protection to block the computer from writing, which is why it is still the default, but it doesn't actually work like you want it to work for 99% of the use cases. So reconnecting it is.
USBSDFileSystem.cpp
- Committer:
- karelv
- Date:
- 2013-08-27
- Revision:
- 1:88089dd56f0e
- Parent:
- 0:c3d2e89ca30d
File content as of revision 1:88089dd56f0e:
/* a copy of the SDFileSystem library...
* but adapted for class 'USBSDFileSystem'!
*/
/* Introduction
* ------------
* SD and MMC cards support a number of interfaces, but common to them all
* is one based on SPI. This is the one I'm implmenting because it means
* it is much more portable even though not so performant, and we already
* have the mbed SPI Interface!
*
* The main reference I'm using is Chapter 7, "SPI Mode" of:
* http://www.sdcard.org/developers/tech/sdcard/pls/Simplified_Physical_Layer_Spec.pdf
*
* SPI Startup
* -----------
* The SD card powers up in SD mode. The SPI interface mode is selected by
* asserting CS low and sending the reset command (CMD0). The card will
* respond with a (R1) response.
*
* CMD8 is optionally sent to determine the voltage range supported, and
* indirectly determine whether it is a version 1.x SD/non-SD card or
* version 2.x. I'll just ignore this for now.
*
* ACMD41 is repeatedly issued to initialise the card, until "in idle"
* (bit 0) of the R1 response goes to '0', indicating it is initialised.
*
* You should also indicate whether the host supports High Capicity cards,
* and check whether the card is high capacity - i'll also ignore this
*
* SPI Protocol
* ------------
* The SD SPI protocol is based on transactions made up of 8-bit words, with
* the host starting every bus transaction by asserting the CS signal low. The
* card always responds to commands, data blocks and errors.
*
* The protocol supports a CRC, but by default it is off (except for the
* first reset CMD0, where the CRC can just be pre-calculated, and CMD8)
* I'll leave the CRC off I think!
*
* Standard capacity cards have variable data block sizes, whereas High
* Capacity cards fix the size of data block to 512 bytes. I'll therefore
* just always use the Standard Capacity cards with a block size of 512 bytes.
* This is set with CMD16.
*
* You can read and write single blocks (CMD17, CMD25) or multiple blocks
* (CMD18, CMD25). For simplicity, I'll just use single block accesses. When
* the card gets a read command, it responds with a response token, and then
* a data token or an error.
*
* SPI Command Format
* ------------------
* Commands are 6-bytes long, containing the command, 32-bit argument, and CRC.
*
* +---------------+------------+------------+-----------+----------+--------------+
* | 01 | cmd[5:0] | arg[31:24] | arg[23:16] | arg[15:8] | arg[7:0] | crc[6:0] | 1 |
* +---------------+------------+------------+-----------+----------+--------------+
*
* As I'm not using CRC, I can fix that byte to what is needed for CMD0 (0x95)
*
* All Application Specific commands shall be preceded with APP_CMD (CMD55).
*
* SPI Response Format
* -------------------
* The main response format (R1) is a status byte (normally zero). Key flags:
* idle - 1 if the card is in an idle state/initialising
* cmd - 1 if an illegal command code was detected
*
* +-------------------------------------------------+
* R1 | 0 | arg | addr | seq | crc | cmd | erase | idle |
* +-------------------------------------------------+
*
* R1b is the same, except it is followed by a busy signal (zeros) until
* the first non-zero byte when it is ready again.
*
* Data Response Token
* -------------------
* Every data block written to the card is acknowledged by a byte
* response token
*
* +----------------------+
* | xxx | 0 | status | 1 |
* +----------------------+
* 010 - OK!
* 101 - CRC Error
* 110 - Write Error
*
* Single Block Read and Write
* ---------------------------
*
* Block transfers have a byte header, followed by the data, followed
* by a 16-bit CRC. In our case, the data will always be 512 bytes.
*
* +------+---------+---------+- - - -+---------+-----------+----------+
* | 0xFE | data[0] | data[1] | | data[n] | crc[15:8] | crc[7:0] |
* +------+---------+---------+- - - -+---------+-----------+----------+
*/
#include "USBSDFileSystem.h"
#include "mbed_debug.h"
#define SD_COMMAND_TIMEOUT 5000
#define SD_DBG 0
USBSDFileSystem::USBSDFileSystem(const char *name, PinName mosi, PinName miso, PinName sclk, PinName cs) :
USBFileSystem(name), _spi(mosi, miso, sclk), _cs(cs)
{
_cs = 1;
//no init
_status = 0x01;
// wait (1);
connect();
}
#define R1_IDLE_STATE (1 << 0)
#define R1_ERASE_RESET (1 << 1)
#define R1_ILLEGAL_COMMAND (1 << 2)
#define R1_COM_CRC_ERROR (1 << 3)
#define R1_ERASE_SEQUENCE_ERROR (1 << 4)
#define R1_ADDRESS_ERROR (1 << 5)
#define R1_PARAMETER_ERROR (1 << 6)
// Types
// - v1.x Standard Capacity
// - v2.x Standard Capacity
// - v2.x High Capacity
// - Not recognised as an SD Card
#define SDCARD_FAIL 0
#define SDCARD_V1 1
#define SDCARD_V2 2
#define SDCARD_V2HC 3
int USBSDFileSystem::initialise_card() {
// Set to 100kHz for initialisation, and clock card with cs = 1
_spi.frequency(100000);
_cs = 1;
for (int i = 0; i < 16; i++) {
_spi.write(0xFF);
}
// send CMD0, should return with all zeros except IDLE STATE set (bit 0)
if (_cmd(0, 0) != R1_IDLE_STATE) {
debug("No disk, or could not put SD card in to SPI idle state\n");
return SDCARD_FAIL;
}
// send CMD8 to determine whther it is ver 2.x
int r = _cmd8();
if (r == R1_IDLE_STATE) {
return initialise_card_v2();
} else if (r == (R1_IDLE_STATE | R1_ILLEGAL_COMMAND)) {
return initialise_card_v1();
} else {
debug("Not in idle state after sending CMD8 (not an SD card?)\n");
return SDCARD_FAIL;
}
}
int USBSDFileSystem::initialise_card_v1() {
for (int i = 0; i < SD_COMMAND_TIMEOUT; i++) {
_cmd(55, 0);
if (_cmd(41, 0) == 0) {
cdv = 512;
debug_if(SD_DBG, "\n\rInit: SEDCARD_V1\n\r");
return SDCARD_V1;
}
}
debug("Timeout waiting for v1.x card\n");
return SDCARD_FAIL;
}
int USBSDFileSystem::initialise_card_v2() {
for (int i = 0; i < SD_COMMAND_TIMEOUT; i++) {
wait_ms(50);
_cmd58();
_cmd(55, 0);
if (_cmd(41, 0x40000000) == 0) {
_cmd58();
debug_if(SD_DBG, "\n\rInit: SDCARD_V2\n\r");
cdv = 1;
return SDCARD_V2;
}
}
debug("Timeout waiting for v2.x card\n");
return SDCARD_FAIL;
}
int USBSDFileSystem::disk_initialize() {
int i = initialise_card();
debug_if(SD_DBG, "init card = %d\n", i);
_sectors = _sd_sectors();
// Set block length to 512 (CMD16)
if (_cmd(16, 512) != 0) {
debug("Set 512-byte block timed out\n");
return 1;
}
// _spi.frequency(1000000); // Set to 1MHz for data transfer
_spi.frequency(5000000); // Set to 5MHz for data transfer
// OK
_status = 0x00;
return 0;
}
int USBSDFileSystem::_disk_write(const uint8_t *buffer, uint64_t block_number) {
// set write address for single block (CMD24)
if (_cmd(24, block_number * cdv) != 0) {
return 1;
}
// send the data block
_write(buffer, 512);
return 0;
}
int USBSDFileSystem::disk_read(uint8_t *buffer, uint64_t block_number) {
// set read address for single block (CMD17)
if (_cmd(17, block_number * cdv) != 0) {
return 1;
}
// receive the data
_read(buffer, 512);
return 0;
}
int USBSDFileSystem::_disk_status() { return _status; }
int USBSDFileSystem::disk_sync() { return 0; }
uint64_t USBSDFileSystem::disk_sectors() { return _sectors; }
// PRIVATE FUNCTIONS
int USBSDFileSystem::_cmd(int cmd, int arg) {
_cs = 0;
// send a command
_spi.write(0x40 | cmd);
_spi.write(arg >> 24);
_spi.write(arg >> 16);
_spi.write(arg >> 8);
_spi.write(arg >> 0);
_spi.write(0x95);
// wait for the repsonse (response[7] == 0)
for (int i = 0; i < SD_COMMAND_TIMEOUT; i++) {
int response = _spi.write(0xFF);
if (!(response & 0x80)) {
_cs = 1;
_spi.write(0xFF);
return response;
}
}
_cs = 1;
_spi.write(0xFF);
return -1; // timeout
}
int USBSDFileSystem::_cmdx(int cmd, int arg) {
_cs = 0;
// send a command
_spi.write(0x40 | cmd);
_spi.write(arg >> 24);
_spi.write(arg >> 16);
_spi.write(arg >> 8);
_spi.write(arg >> 0);
_spi.write(0x95);
// wait for the repsonse (response[7] == 0)
for (int i = 0; i < SD_COMMAND_TIMEOUT; i++) {
int response = _spi.write(0xFF);
if (!(response & 0x80)) {
return response;
}
}
_cs = 1;
_spi.write(0xFF);
return -1; // timeout
}
int USBSDFileSystem::_cmd58() {
_cs = 0;
int arg = 0;
// send a command
_spi.write(0x40 | 58);
_spi.write(arg >> 24);
_spi.write(arg >> 16);
_spi.write(arg >> 8);
_spi.write(arg >> 0);
_spi.write(0x95);
// wait for the repsonse (response[7] == 0)
for (int i = 0; i < SD_COMMAND_TIMEOUT; i++) {
int response = _spi.write(0xFF);
if (!(response & 0x80)) {
int ocr = _spi.write(0xFF) << 24;
ocr |= _spi.write(0xFF) << 16;
ocr |= _spi.write(0xFF) << 8;
ocr |= _spi.write(0xFF) << 0;
_cs = 1;
_spi.write(0xFF);
return response;
}
}
_cs = 1;
_spi.write(0xFF);
return -1; // timeout
}
int USBSDFileSystem::_cmd8() {
_cs = 0;
// send a command
_spi.write(0x40 | 8); // CMD8
_spi.write(0x00); // reserved
_spi.write(0x00); // reserved
_spi.write(0x01); // 3.3v
_spi.write(0xAA); // check pattern
_spi.write(0x87); // crc
// wait for the repsonse (response[7] == 0)
for (int i = 0; i < SD_COMMAND_TIMEOUT * 1000; i++) {
char response[5];
response[0] = _spi.write(0xFF);
if (!(response[0] & 0x80)) {
for (int j = 1; j < 5; j++) {
response[i] = _spi.write(0xFF);
}
_cs = 1;
_spi.write(0xFF);
return response[0];
}
}
_cs = 1;
_spi.write(0xFF);
return -1; // timeout
}
int USBSDFileSystem::_read(uint8_t *buffer, uint32_t length) {
_cs = 0;
// read until start byte (0xFF)
while (_spi.write(0xFF) != 0xFE);
// read data
for (int i = 0; i < length; i++) {
buffer[i] = _spi.write(0xFF);
}
_spi.write(0xFF); // checksum
_spi.write(0xFF);
_cs = 1;
_spi.write(0xFF);
return 0;
}
int USBSDFileSystem::_write(const uint8_t*buffer, uint32_t length) {
_cs = 0;
// indicate start of block
_spi.write(0xFE);
// write the data
for (int i = 0; i < length; i++) {
_spi.write(buffer[i]);
}
// write the checksum
_spi.write(0xFF);
_spi.write(0xFF);
// check the response token
if ((_spi.write(0xFF) & 0x1F) != 0x05) {
_cs = 1;
_spi.write(0xFF);
return 1;
}
// wait for write to finish
while (_spi.write(0xFF) == 0);
_cs = 1;
_spi.write(0xFF);
return 0;
}
static uint32_t ext_bits(unsigned char *data, int msb, int lsb) {
uint32_t bits = 0;
uint32_t size = 1 + msb - lsb;
for (int i = 0; i < size; i++) {
uint32_t position = lsb + i;
uint32_t byte = 15 - (position >> 3);
uint32_t bit = position & 0x7;
uint32_t value = (data[byte] >> bit) & 1;
bits |= value << i;
}
return bits;
}
uint64_t USBSDFileSystem::_sd_sectors() {
uint32_t c_size, c_size_mult, read_bl_len;
uint32_t block_len, mult, blocknr, capacity;
uint32_t hc_c_size;
uint64_t blocks;
// CMD9, Response R2 (R1 byte + 16-byte block read)
if (_cmdx(9, 0) != 0) {
debug("Didn't get a response from the disk\n");
return 0;
}
uint8_t csd[16];
if (_read(csd, 16) != 0) {
debug("Couldn't read csd response from disk\n");
return 0;
}
// csd_structure : csd[127:126]
// c_size : csd[73:62]
// c_size_mult : csd[49:47]
// read_bl_len : csd[83:80] - the *maximum* read block length
int csd_structure = ext_bits(csd, 127, 126);
switch (csd_structure) {
case 0:
cdv = 512;
c_size = ext_bits(csd, 73, 62);
c_size_mult = ext_bits(csd, 49, 47);
read_bl_len = ext_bits(csd, 83, 80);
block_len = 1 << read_bl_len;
mult = 1 << (c_size_mult + 2);
blocknr = (c_size + 1) * mult;
capacity = blocknr * block_len;
blocks = capacity / 512;
debug_if(SD_DBG, "\n\rSDCard\n\rc_size: %d \n\rcapacity: %ld \n\rsectors: %lld\n\r", c_size, capacity, blocks);
break;
case 1:
cdv = 1;
hc_c_size = ext_bits(csd, 63, 48);
blocks = (hc_c_size+1)*1024;
debug_if(SD_DBG, "\n\rSDHC Card \n\rhc_c_size: %d\n\rcapacity: %lld \n\rsectors: %lld\n\r", hc_c_size, blocks*512, blocks);
break;
default:
debug("CSD struct unsupported\r\n");
return 0;
};
return blocks;
}