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/* sdcard.c */ #include "spi.h" #include "types.h" #include "uart.h" #include "timer.h" #include "event.h" #include "log.h" #define spi_write_array(x) spi_write_bytes(x, sizeof(x)/sizeof(x[0])) #define SDCARD_COMMAND_TIMEOUT 0xffff char dummy_block[] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff}; char reset_command[] = {0x40, 0, 0, 0, 0, 0x95}; /* Voltage = 2.7-3.6V, check pattern = 0xaa, CRC matters for CMD8 */ char sdcard_cmd8[] = {0x48, 0, 0, 0x01, 0xaa, 0x87}; char sdcard_cmd55[] = {0x77, 0, 0, 0, 0, 0xff}; char sdcard_acmd41[] = {0x69, 0, 0, 0, 0, 0xff}; char sdcard_acmd41_hcs[] = {0x69, 0x40, 0, 0, 0, 0xff}; char sdcard_cmd58[] = {0x7a, 0, 0, 0, 0, 0xff}; /* 512 bytes block length */ char sdcard_cmd16[] = {0x50, 0, 0, 2, 0, 0xff}; /* Read CSD */ char sdcard_cmd9[] = {0x49, 0, 0, 0, 0, 0xff}; static bool high_capacity; #ifdef SDCARD_BOUNDARY_128K /* 128K */ #define SDCARD_BOUNDARY_MASK 0xff #define SDCARD_BOUNDARY_SIZE 0x100 #else /* 32K */ #define SDCARD_BOUNDARY_MASK 0x3f #define SDCARD_BOUNDARY_SIZE 0x40 #endif unsigned int sdcard_sector; unsigned int sdcard_offset; unsigned int sdcard_size; /* defined as number of sectors */ #define SDCARD_IDLE 0 #define SDCARD_WRITE_GAP 1 #define SDCARD_WRITING_BLOCK 2 #define SDCARD_STOPPING 3 #define SDCARD_ERROR 4 unsigned int sdcard_active; static bool sdcard_command(char *command, unsigned int command_length, char *response, unsigned int response_length, bool wait_busy); bool sdcard_write(unsigned int address, char *buffer, unsigned int length); bool sdcard_read_csd(char *buffer); void sdcard_prepare(void); /* SD card (SPI mode initialisation) power on CMD0+ CMD8 if (no response from CMD8) { // legacy (MMC) card CMD58 (optional, read OCR) - no or bad response = don't use card while (ACMD41(arg 0x00) & in_idle_state_mask) ; done } else { // SD card if (response from CMD8 was present but invalid (check pattern not matched)) retry CMD8; CMD58 (optional, read OCR) while (ACMD41(arg HCS=1) & in_idle_state_mask) ; CMD58 (Get CCS) if (CCS) done - high capacity SD card else done - standard SD card } */ bool init_sdcard(void) { char response[16]; unsigned int i; unsigned int read_bl_len, c_size_mult, c_size; unsigned int block_len, mult, blocknr; putstr("Initialising SPI\r\n"); init_spi(); high_capacity = FALSE; putstr("Sending 80 clocks\r\n"); spi_transaction_start(); spi_write_array(dummy_block); spi_transaction_stop(); putstr("Sending reset command\r\n"); if (!sdcard_command(reset_command, sizeof(reset_command), response, 1, FALSE)) return FALSE; putstr("Reset command successful. Checking response.\r\n"); puthex(response[0]); putstr("\r\n"); if (response[0] != 0x01) return FALSE; putstr("Sending CMD8\r\n"); if (!sdcard_command(sdcard_cmd8, sizeof(sdcard_cmd8), response, 5, FALSE)) { putstr("No response. Legacy device.\r\n"); /* Legacy device */ do { if (!sdcard_command(sdcard_cmd55, sizeof(sdcard_cmd55), response, 1, FALSE)) return FALSE; if (response[0] != 0x01) return FALSE; if (!sdcard_command(sdcard_acmd41, sizeof(sdcard_acmd41), response, 1, FALSE)) return FALSE; } while (response[0] & 1); putstr("ACMD41 gave us the right response.\r\n"); } else { putstr("We got a response. Not a legacy device.\r\n"); /* Not legacy device */ for (i = 1; i < 4; i++) { if (response[i] != sdcard_cmd8[i]) { /* We should really retry here. Meh. */ return FALSE; } } putstr("Response OK. Safe to continue.\r\n"); do { if (!sdcard_command(sdcard_cmd55, sizeof(sdcard_cmd55), response, 1, FALSE)) return FALSE; if (response[0] != 0x01) return FALSE; if (!sdcard_command(sdcard_acmd41_hcs, sizeof(sdcard_acmd41_hcs), response, 1, FALSE)) return FALSE; } while (response[0] & 1); putstr("ACMD41 gave us the right response.\r\n"); if (!sdcard_command(sdcard_cmd58, sizeof(sdcard_cmd58), response, 5, FALSE)) return FALSE; putstr("OCR register retrieved.\r\n"); if ((response[1] & 0x80) == 0) return FALSE; putstr("Chip isn't still powering up.\r\n"); if (response[1] & 0x40) { putstr("We have a high capacity device.\r\n"); high_capacity = TRUE; } else { putstr("We have a low capacity device.\r\n"); high_capacity = FALSE; } } spi_speedup(); /* Set block length to 512 */ if (!sdcard_command(sdcard_cmd16, sizeof(sdcard_cmd16), response, 1, FALSE)) return FALSE; putstr("Determining card size.\r\n"); if (!sdcard_read_csd(response)) return FALSE; putstr("Read CSD\r\n"); switch ((response[0] & 0xc0) >> 6) { case 0: /* CSD Version 1.0 */ read_bl_len = response[5] & 0x0f; c_size_mult = ((response[9] & 0x03) << 1) | (response[10] >> 7); c_size = ((response[6] & 0x03) << 10) | (response[7] << 2) | (response[8] >> 6); block_len = 1<<read_bl_len; mult = 1<<(c_size_mult+2); blocknr = (c_size+1) * mult; sdcard_size = blocknr * block_len / 512; break; case 1: /* CSD Version 2.0 */ c_size = ((response[7] & 0x3f) << 16) | (response[8] << 8) | response[9]; sdcard_size = (c_size+1) * 1024; break; default: /* Unrecognised CSD version */ putstr("Unrecognised CSD version\r\n"); return FALSE; } putstr("SD initialisation sequence complete.\r\n"); putstr("size = "); putint(sdcard_size / 2); putstr("KB\r\n"); putstr("Initialising logging system.\r\n"); sdcard_prepare(); return TRUE; } static bool sdcard_command_innards(char *command, unsigned int command_length, char *response, unsigned int response_length, bool wait_busy) { char byte; unsigned int i; spi_write_bytes(command, command_length); i = 0; do { byte = spi_read_byte(); i++; } while (((byte & 0x80) != 0) && (i < SDCARD_COMMAND_TIMEOUT)); if (byte & 0x80) return FALSE; if (response_length > 0) response[0] = byte; /* We need to store the response, plus read one extra byte for luck. */ /* XXX not an extra byte for luck any more */ for (i = 1; i < response_length; i++) { byte = spi_read_byte(); response[i] = byte; } if (wait_busy) { do { byte = spi_read_byte(); } while (byte == 0); spi_write_byte(0xff); } return TRUE; } static bool sdcard_check_data_response(void) { char byte; unsigned int i; i = 0; do { byte = spi_read_byte(); i++; } while (((byte & 0x11) != 0x01) && (i < SDCARD_COMMAND_TIMEOUT)); if ((byte & 0x11) != 0x01) return FALSE; if ((byte & 0x0f) != 0x05) /* Data accepted */ return FALSE; /* Read one more byte for luck */ byte = spi_read_byte(); return TRUE; } static bool sdcard_command(char *command, unsigned int command_length, char *response, unsigned int response_length, bool wait_busy) { bool result; spi_transaction_start(); result = sdcard_command_innards(command, command_length, response, response_length, wait_busy); spi_transaction_stop(); return result; } static bool sdcard_read_block(char *buffer, unsigned int length) { unsigned int i; unsigned int crc_hi; unsigned int crc_lo; unsigned int crc; while (1) { char byte = spi_read_byte(); if (byte == 0xff) continue; if (byte == 0xfe) break; if ((byte & 0xf0) == 0) if (byte != 0) return FALSE; } /* We need to store the response, plus read one extra byte for luck. */ for (i = 0; i < length; i++) { buffer[i] = spi_read_byte(); } crc_hi = spi_read_byte(); crc_lo = spi_read_byte(); crc = (crc_hi << 8) + crc_lo; /* XXX check CRC and return FALSE if doesn't match */ return TRUE; } bool sdcard_read(unsigned int address, char *buffer, unsigned int length) { bool valid; char response; char cmd[6]; if (!high_capacity) address = address * 512; cmd[0] = 0x51; /* CMD17 */ cmd[1] = (address >> 24) & 0xff; cmd[2] = (address >> 16) & 0xff; cmd[3] = (address >> 8) & 0xff; cmd[4] = (address >> 0) & 0xff; cmd[5] = 0xff; /* dummy CRC */ spi_transaction_start(); if (!sdcard_command_innards(cmd, sizeof(cmd), &response, 1, FALSE)) { spi_transaction_stop(); return FALSE; } if (response != 0) { spi_transaction_stop(); return FALSE; } valid = sdcard_read_block(buffer, length); spi_transaction_stop(); return valid; } bool sdcard_read_csd(char *buffer) { bool valid; char response; spi_transaction_start(); if (!sdcard_command_innards(sdcard_cmd9, sizeof(sdcard_cmd9), &response, 1, FALSE)) { spi_transaction_stop(); return FALSE; } if (response != 0) { spi_transaction_stop(); return FALSE; } valid = sdcard_read_block(buffer, 16); spi_transaction_stop(); return valid; } bool sdcard_send_write_cmd(unsigned int address) { char response; char cmd[6]; if (!high_capacity) address = address * 512; cmd[0] = 0x59; /* CMD25 */ cmd[1] = (address >> 24) & 0xff; cmd[2] = (address >> 16) & 0xff; cmd[3] = (address >> 8) & 0xff; cmd[4] = (address >> 0) & 0xff; cmd[5] = 0xff; /* dummy CRC */ spi_transaction_start(); if (!sdcard_command_innards(cmd, sizeof(cmd), &response, 1, FALSE)) { spi_transaction_stop(); return FALSE; } if (response != 0) { spi_transaction_stop(); return FALSE; } return TRUE; } static void sdcard_send_data_token(void) { spi_write_byte(0xfc); } static void sdcard_send_stop_token(void) { spi_write_byte(0xfd); } #define READ_UINT(b, i) ((b)[(i)] + ((b)[(i)+1] << 8) + \ ((b)[(i)+2] << 16) + ((b)[(i)+3] << 24)) #define WRITE_UINT(b, i, d) \ do { \ (b)[(i)] = (d) & 0xff; \ (b)[(i)+1] = ((d) >> 8) & 0xff; \ (b)[(i)+2] = ((d) >> 16) & 0xff; \ (b)[(i)+3] = ((d) >> 24) & 0xff; \ } while (0) /* We assume that the magic is to be found within this area. If not, * we will need to read a bigger area. If the typical record size grows * to more than a sector, for example, then we will need to read in multiple * sectors where this function is called. */ bool sdcard_scan_magic(char *buffer, unsigned int size, unsigned int generation) { unsigned int i; for (i = 0; i < size - 8; i++) { if ((buffer[i] == (LOG_MAGIC & 0xff)) && (buffer[i+1] == ((LOG_MAGIC >> 8) & 0xff)) && (buffer[i+2] == ((LOG_MAGIC >> 16) & 0xff)) && (buffer[i+3] == ((LOG_MAGIC >> 24) & 0xff)) && (buffer[i+4] == ((generation >> 0) & 0xff)) && (buffer[i+5] == ((generation >> 8) & 0xff)) && (buffer[i+6] == ((generation >> 16) & 0xff)) && (buffer[i+7] == ((generation >> 24) & 0xff))) return TRUE; } return FALSE; } void sdcard_prepare(void) { unsigned int magic; unsigned int start_sector; unsigned int count; if (!sdcard_read(0, log_buffer, 512)) return; magic = READ_UINT(log_buffer, 0); if (magic != LOG_MAGIC) { unsigned int i; for (i = 0; i < 512; i++) log_buffer[i] = 0; WRITE_UINT(log_buffer, 0, LOG_MAGIC); start_sector = SDCARD_BOUNDARY_SIZE; log_generation = 0; putstr("Did not find header. Formatting.\r\n"); } else { start_sector = READ_UINT(log_buffer, 4); log_generation = READ_UINT(log_buffer, 8); count = 0; putstr("Found header.\r\n"); putstr("Last started at sector "); putint(start_sector); putstr(" with generation "); putint(log_generation); putstr("\r\n"); while (1) { if (!sdcard_read(start_sector, log_buffer+512, 512)) return; /* This needs to change if record length exceeds 512 */ if (sdcard_scan_magic(log_buffer+512, 512, log_generation)) { start_sector += SDCARD_BOUNDARY_SIZE; if (start_sector >= sdcard_size) start_sector = SDCARD_BOUNDARY_SIZE; } else { break; } if (count++ > (sdcard_size / SDCARD_BOUNDARY_SIZE)) { start_sector = SDCARD_BOUNDARY_SIZE; break; } } log_generation++; } WRITE_UINT(log_buffer, 4, start_sector); WRITE_UINT(log_buffer, 8, log_generation); putstr("Starting at sector "); putint(start_sector); putstr(" with generation "); putint(log_generation); putstr("\r\n"); if (!sdcard_write(0, log_buffer, 512)) return; sdcard_sector = start_sector; sdcard_offset = 0; log_enabled = TRUE; } static bool sdcard_busy(void) { return (spi_read_byte() != 0xff); } static void sdcard_send_dummy_crc(void) { spi_write_byte(0xff); spi_write_byte(0xff); } void sdcard_poll(void) { if (!log_enabled) return; if (LOG_BUFFER_EMPTY) return; log_mark_busy(); if (sdcard_active == SDCARD_IDLE) { spi_transaction_start(); if (sdcard_busy()) { spi_transaction_stop(); log_mark_idle(); return; } putch('C'); if (sdcard_send_write_cmd(sdcard_sector)) sdcard_active = SDCARD_WRITE_GAP; else { spi_transaction_stop(); sdcard_active = SDCARD_ERROR; } } if (sdcard_active == SDCARD_WRITE_GAP) { if (sdcard_busy()) { log_mark_idle(); return; } sdcard_send_data_token(); sdcard_active = SDCARD_WRITING_BLOCK; } if (sdcard_active == SDCARD_WRITING_BLOCK) { unsigned int bytes_to_end_of_sector; unsigned int i; i = LOG_BUFFER_BYTES; bytes_to_end_of_sector = 512 - sdcard_offset; if (i > bytes_to_end_of_sector) i = bytes_to_end_of_sector; if (i > 32) i = 32; sdcard_offset += i; while (i--) { spi_write_byte(log_get_byte()); } if (sdcard_offset >= 512) { sdcard_offset = 0; sdcard_sector++; sdcard_send_dummy_crc(); putch('.'); if (!sdcard_check_data_response()) { /* Set state to STOPPING instead? */ /* How do we test this? */ spi_transaction_stop(); sdcard_active = SDCARD_ERROR; log_mark_idle(); return; } sdcard_active = SDCARD_WRITE_GAP; if ((sdcard_sector & SDCARD_BOUNDARY_MASK) == 0) { putch('S'); sdcard_active = SDCARD_STOPPING; } } } if (sdcard_active == SDCARD_STOPPING) { if (sdcard_busy()) { log_mark_idle(); return; } sdcard_send_stop_token(); spi_transaction_stop(); sdcard_active = SDCARD_IDLE; } log_mark_idle(); } bool sdcard_write(unsigned int address, char *buffer, unsigned int length) { unsigned int i; spi_transaction_start(); if (!sdcard_send_write_cmd(address)) { spi_transaction_stop(); return FALSE; } sdcard_send_data_token(); for (i = 0; i < length; i++) { spi_write_byte(buffer[i]); } sdcard_send_dummy_crc(); if (!sdcard_check_data_response()) { spi_transaction_stop(); return FALSE; } while (sdcard_busy()) ; sdcard_send_stop_token(); while (sdcard_busy()) ; spi_transaction_stop(); return TRUE; }