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[/] [xulalx25soc/] [trunk/] [bench/] [cpp/] [sdspisim.cpp] - Rev 98
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/////////////////////////////////////////////////////////////////////////// // // // Filename: sdspisim.cpp // // Project: Wishbone Controlled SD-Card Controller over SPI port // // Purpose: This library simulates the operation of a SPI commanded SD-Card, // such as might be found on a XuLA2-LX25 board made by xess.com. // // This simulator is for testing use in a Verilator/C++ environment, where // it would be used in place of the actual hardware. // // Creator: Dan Gisselquist // Gisselquist Technology, LLC // /////////////////////////////////////////////////////////////////////////// // // Copyright (C) 2015-2016, Gisselquist Technology, LLC // // This program is free software (firmware): 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 MERCHANTIBILITY 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. (It's in the $(ROOT)/doc directory, run make with no // target there if the PDF file isn't present.) If not, see // <http://www.gnu.org/licenses/> for a copy. // // License: GPL, v3, as defined and found on www.gnu.org, // http://www.gnu.org/licenses/gpl.html // // /////////////////////////////////////////////////////////////////////////// #include <stdio.h> #include <string.h> #include <assert.h> #include <stdlib.h> #include "sdspisim.h" static const unsigned MICROSECONDS = 80, // Clocks in a microsecond MILLISECONDS = MICROSECONDS * 1000, tRESET = 4*MILLISECONDS; // Just a wild guess /* static const unsigned DEVID = 0x0115, DEVESD = 0x014, MICROSECONDS = 100, MILLISECONDS = MICROSECONDS * 1000, SECONDS = MILLISECONDS * 1000, tW = 50 * MICROSECONDS, // write config cycle time tBE = 32 * SECONDS, tDP = 10 * SECONDS, tRES = 30 * SECONDS, // Shall we artificially speed up this process? tPP = 12 * MICROSECONDS, tSE = 15 * MILLISECONDS; // or keep it at the original speed // tPP = 1200 * MICROSECONDS, // tSE = 1500 * MILLISECONDS; */ static const unsigned CCS = 1; // 0: SDSC card, 1: SDHC or SDXC card SDSPISIM::SDSPISIM(void) { m_dev = NULL; m_last_sck = 1; m_block_address = (CCS==1); m_host_supports_high_capacity = false; m_powerup_busy = -1; m_reset_state = SDSPI_POWERUP_RESET; // m_csd[ 0] = 0; // Normal SDcard, not high capacity m_csd[ 1] = 0x0f; m_csd[ 2] = 0x0f; m_csd[ 3] = 0x32; // Can be either 0x32 (25MHz) or 0x5a (50MHz) m_csd[ 4] = 0x5b; // Could also be 0x07b, if we supported more comands(?) m_csd[ 5] = 0x59; // 9-> 2^9,or 512 bytes (10->1024, 11->2048, no othrs) m_csd[ 6] = 0x00; // partial blocks allowed? m_csd[ 7] = 0x00; // C_SIZE, 2'b00, then top 6 bits m_csd[ 8] = 0; // C_SIZE, 22-bits, mid 8 bits m_csd[ 9] = 0; // C_SIZE, 22-bits, bottom 8 bits m_csd[10] = 0x7f; m_csd[11] = 0x80; m_csd[12] = 0x0a; m_csd[13] = 0x40; m_csd[14] = 0; // R/W: file format, copy, write protect, etc. m_csd[15] = cmdcrc(15, m_csd); // CID Register m_cid[ 0] = 0xba; m_cid[ 1] = 0xd0; m_cid[ 2] = 0xda; m_cid[ 3] = 0xdd; m_cid[ 4] = 0; m_cid[ 5] = 0xde; m_cid[ 6] = 0xad; m_cid[ 7] = 0xbe; m_cid[ 8] = 0xef; m_cid[ 9] = 0x20; m_cid[10] = 0x16; m_cid[11] = 0x05; m_cid[12] = 0x26; m_cid[13] = 0; m_cid[14] = 0; m_cid[15] = cmdcrc(15, m_cid); // m_write_count = 0; // m_ireg = m_oreg = 0; // m_sreg = 0x01c; // m_creg = 0x001; // Iinitial creg on delivery // m_reading_data = false; m_have_token = false; } void SDSPISIM::load(const char *fname) { m_dev = fopen(fname, "r+b"); if (m_dev) { unsigned long devln; fseek(m_dev, 0l, SEEK_END); devln = ftell(m_dev); fseek(m_dev, 0l, SEEK_SET); m_devblocks = devln>>9; printf("SDCARD: NBLOCKS = %ld\n", m_devblocks); } } int SDSPISIM::operator()(const int csn, const int sck, const int mosi) { // Keep track of a timer to determine when page program and erase // cycles complete. /* if (m_write_count > 0) { // } */ m_delay++; if (m_powerup_busy>0) m_powerup_busy--; if (csn) { m_delay = 0; m_cmdidx= 0; m_rspidx= 0; m_bitpos= 0; m_delay = 0; m_busy = false; m_last_sck = sck; m_syncd = false; m_last_miso = 1; m_dat_out = 0x0ff; // Reset everything when not selected return 0; } else if (sck == m_last_sck) { m_last_sck = sck; return m_last_miso; } else if (!m_last_sck) { // Register our input on the rising edge m_mosi = mosi; m_syncd= true; m_last_sck = sck; return m_last_miso; } if (!m_syncd) { m_last_sck = sck; return m_last_miso; } // Only change our output on the falling edge m_last_sck = sck; printf("SDSPI: (%3d) [%d,%d,%d] ", m_delay, csn, sck, m_mosi); // assert(m_delay > 20); m_bitpos++; m_dat_in = (m_dat_in<<1)|m_mosi; printf("(bitpos=%d,dat_in=%02x)\n", m_bitpos&7, m_dat_in&0x0ff); if ((m_bitpos&7)==0) { printf("SDSPI--RX BYTE %02x\n", m_dat_in&0x0ff); m_dat_out = 0xff; if (m_reading_data) { if (m_have_token) { m_block_buf[m_rxloc++] = m_dat_in; printf("SDSPI: WR[%3d] = %02x\n", m_rxloc-1, m_dat_in&0x0ff); if (m_rxloc >= 512+2) { unsigned crc, rxcrc; crc = blockcrc(512, m_block_buf); rxcrc = ((m_block_buf[512]&0x0ff)<<8) |(m_block_buf[513]&0x0ff); printf("LEN = %d\n", m_rxloc); printf("CHECKING CRC: (rx) %04x =? %04x (calc)\n", crc, rxcrc); m_reading_data = false; m_have_token = false; if (rxcrc == crc) m_dat_out = 5; else { m_dat_out = 0x0b; assert(rxcrc == crc); } } } else { if ((m_dat_in&0x0ff) == 0x0fe) { printf("SDSPI: TOKEN!!\n"); m_have_token = true; m_rxloc = 0; } else printf("SDSPI: waiting on token\n"); } } else if (m_cmdidx < 6) { printf("SDSPI: CMDIDX = %d\n", m_cmdidx); // All commands *must* start with a 01... pair of bits. if (m_cmdidx == 0) assert((m_dat_in&0xc0)==0x40); // Record the command for later processing m_cmdbuf[m_cmdidx++] = m_dat_in; } else if (m_cmdidx == 6) { // We're going to start a response from here ... m_rspidx = 0; m_blkdly = 0; m_blkidx = SDSPI_MAXBLKLEN; printf("SDSPI: CMDIDX = %d -- WE HAVE A COMMAND! [ ", m_cmdidx); for(int i=0; i<6; i++) printf("%02x ", m_cmdbuf[i] & 0xff); printf("]\n"); fflush(stdout); unsigned arg; arg = ((((((m_cmdbuf[1]<<8)|(m_cmdbuf[2]&0x0ff))<<8) |(m_cmdbuf[3]&0x0ff))<<8) |(m_cmdbuf[4]&0x0ff)); arg &= 0x0ffffffff; // Check the CRC if (!check_cmdcrc(m_cmdbuf)) { assert(0 && "BAD CRC"); m_rspbuf[0] = 0x09; m_rspdly = 1; } else if (m_altcmd_flag) { switch(m_cmdbuf[0]&0x03f) { case 41: // ACMD41 -- SD_SEND_OP_COND // and start initialization sequence assert((m_reset_state == SDSPI_RCVD_CMD8)||(m_reset_state == SDSPI_RCVD_ACMD41)||(m_reset_state == SDSPI_RESET_COMPLETE)); if((unsigned)m_powerup_busy>tRESET) m_powerup_busy = tRESET; assert((arg&0x0bfffffff) == 0); m_rspbuf[0] = (m_powerup_busy)?1:0; m_rspdly = 2; m_host_supports_high_capacity = (m_cmdbuf[1]&0x40)?1:0; m_reset_state = (m_powerup_busy)? SDSPI_RCVD_ACMD41 :SDSPI_RESET_COMPLETE; break; case 51: // ACMD51 m_block_buf[0] = 0x0fe; for(int j=0; j<8; j++) m_block_buf[j+1] = m_csd[j]; m_blklen = 8; add_block_crc(m_blklen, m_block_buf); m_blkdly = 0; m_blkidx = 0; m_dat_out = 0; break; case 13: // ACMD13 case 22: // ACMD22 case 23: // ACMD23 case 42: // ACMD42 default: // Unimplemented command! m_rspbuf[0] = 0x04; m_rspdly = 4; fprintf(stderr, "SDSPI ERR: Alt command ACMD%d not implemented!\n", m_cmdbuf[0]&0x03f); assert(0 && "Not Implemented"); } m_altcmd_flag = false; } else { m_altcmd_flag = false; memset(m_rspbuf, 0x0ff, SDSPI_RSPLEN); printf("SDSPI: Received a command 0x%02x (%d)\n", m_cmdbuf[0], m_cmdbuf[0]&0x03f); switch(m_cmdbuf[0]&0x3f) { case 0: // CMD0 -- GO_IDLE_STATE m_rspbuf[0] = 0x01; m_rspdly = 4; m_reset_state = SDSPI_CMD0_IDLE; break; case 1: // CMD1 -- SEND_OP_COND assert((arg&0x0bfffffff) == 0); m_rspbuf[0] = 0x02; m_rspdly = 4; m_host_supports_high_capacity = (m_cmdbuf[1]&0x40)?1:0; break; case 8: // CMD8 -- SEND_IF_COND assert((arg&0x0fffff000) == 0); m_rspbuf[0] = 0x00; // See p82 for this format m_rspbuf[1] = 0; m_rspbuf[2] = 0; // If we do not accept the voltage range m_rspbuf[3] = 0; // Now, check if we accept it // We only accept 2.7-3.6V in this // simulation. if ((arg&0x0f00)==0x0100) m_rspbuf[3] = 1; m_rspbuf[4] = (char)(arg&0x0ff); m_rspdly = 4; assert((m_reset_state == SDSPI_CMD0_IDLE)||(m_reset_state == SDSPI_RCVD_CMD8)); m_reset_state = SDSPI_RCVD_CMD8; break; case 9: // CMD9 -- SEND_CSD // Block read, returning start token, // 16 bytes, then 2 crc bytes assert(m_reset_state == SDSPI_IN_OPERATION); m_rspbuf[0] = 0x00; memset(m_block_buf, 0x0ff, SDSPI_MAXBLKLEN); m_block_buf[0] = 0x0fe; for(int j=0; j<16; j++) m_block_buf[j+1] = m_csd[j]; m_blklen = 16; add_block_crc(m_blklen, m_block_buf); m_blkdly = 60; m_blkidx = 0; break; case 10: // CMD10 -- SEND_CID // Block read, returning start token, // 16 bytes, then 2 crc bytes assert(m_reset_state == SDSPI_IN_OPERATION); m_rspbuf[0] = 0x00; memset(m_block_buf, 0x0ff, SDSPI_MAXBLKLEN); m_block_buf[0] = 0x0fe; for(int j=0; j<16; j++) m_block_buf[j+1] = m_cid[j]; m_blklen = 16; add_block_crc(m_blklen, m_block_buf); m_blkdly = 60; m_blkidx = 0; break; case 13: // CMD13 -- SEND_STATUS assert(m_reset_state == SDSPI_IN_OPERATION); m_rspbuf[0] = 0x00; m_rspbuf[1] = 0x00; // if (m_wp_fault) m_rspbuf[1]|=0x20; // if (m_err) m_rspbuf[1]|=0x04; m_rspdly = 4; break; case 17: // CMD17 -- READ_SINGLE_BLOCK assert(m_reset_state == SDSPI_IN_OPERATION); m_rspbuf[0] = 0x00; memset(m_block_buf, 0x0ff, SDSPI_MAXBLKLEN); if (m_dev) { printf("Reading from block %08x of %08lx\n", arg, m_devblocks); if (m_block_address) { assert(arg < m_devblocks); fseek(m_dev, arg<<9, SEEK_SET); } else { assert(arg < m_devblocks<<9); fseek(m_dev, arg, SEEK_SET); } } m_block_buf[0] = 0x0fe; m_blklen = 512; // (1<<m_csd[5]); if (m_dev) fread(&m_block_buf[1], m_blklen, 1, m_dev); else memset(&m_block_buf[1], 0, m_blklen); add_block_crc(m_blklen, m_block_buf); m_blkdly = 60; m_blkidx = 0; break; case 24: // CMD24 -- WRITE_BLOCK m_reading_data = true; m_have_token = false; m_dat_out = 0; break; case 55: // CMD55 -- APP_CMD m_rspbuf[0] = 0x00; m_rspdly = 2; m_altcmd_flag = true; break; case 58: // CMD58 -- READ_OCR, respond R7 // argument is stuff bits/dont care m_rspbuf[0] = 0x00; // See p112, Tbl 5-1 for this format m_rspbuf[1] = ((m_powerup_busy)?0x80:0) |(CCS?0x40:0); m_rspbuf[2] = 0xff;// 2.7-3.6V supported m_rspbuf[3] = 0x80; m_rspbuf[4] = 0; // No low-voltage supt m_rspdly = 4; if (m_reset_state == SDSPI_RESET_COMPLETE) m_reset_state = SDSPI_IN_OPERATION; break; case 6: // CMD6 -- SWITCH_FUNC case 12: // CMD12 -- STOP_TRANSMISSION (!impl) case 16: // CMD16 -- SET_BLOCKLEN case 18: // CMD18 -- READ_MULTIPLE_BLOCK case 25: // CMD25 -- WRITE_MULTIPLE_BLOCK case 27: // CMD27 -- PROGRAM_CSD case 32: // CMD32 -- ERASE_WR_BLK_START_ADDR case 33: // CMD33 -- ERASE_WR_BLK_END_ADDR case 38: // CMD38 -- ERASE case 56: // CMD56 -- GEN_CMD default: // Unimplemented command m_rspbuf[0] = 0x04; m_rspdly = 4; printf("SDSPI ERR: Command CMD%d not implemented!\n", m_cmdbuf[0]&0x03f); fflush(stdout); assert(0 && "Not Implemented"); } } m_cmdidx++; // If we are using blocks, add bytes for the start // token and the two CRC bytes m_blklen += 3; } else if (m_rspdly > 0) { assert((m_dat_in&0x0ff) == 0x0ff); // A delay until a response is given if (m_busy) m_dat_out = 0; m_rspdly--; } else if (m_rspidx < SDSPI_RSPLEN) { assert((m_dat_in&0x0ff) == 0x0ff); m_dat_out = m_rspbuf[m_rspidx++]; } else if (m_blkdly > 0) { assert((m_dat_in&0x0ff) == 0x0ff); m_blkdly--; } else if (m_blkidx < SDSPI_MAXBLKLEN) { assert((m_dat_in&0x0ff) == 0x0ff); m_dat_out = m_block_buf[m_blkidx++]; } // else m_dat_out = 0x0ff; // So set already above } int result = (m_dat_out&0x80)?1:0; m_dat_out <<= 1; m_delay = 0; m_last_miso = result; fflush(stdout); return result; } unsigned SDSPISIM::cmdcrc(int len, char *buf) const { unsigned int fill = 0, taps = 0x12; for(int i=0; i<len; i++) { fill ^= buf[i]; for(int j=0; j<8; j++) { if (fill&0x80) fill = (fill<<1)^taps; else fill <<= 1; } } fill &= 0x0fe; fill |= 1; return fill; } bool SDSPISIM::check_cmdcrc(char *buf) const { unsigned fill = cmdcrc(5, buf); printf("SDSPI: CRC-CHECK, should have a CRC of %02x\n", fill); return (fill == (buf[5]&0x0ff)); } unsigned SDSPISIM::blockcrc(int len, char *buf) const { unsigned int fill = 0, taps = 0x1021; bool dbg = (len == 512); for(int i=0; i<len; i++) { if (dbg) { printf("BUF[%3d] = %02x\n", i, buf[i]&0x0ff); } fill ^= ((buf[i]&0x0ff) << 8); for(int j=0; j<8; j++) { if (fill&0x8000) fill = (fill<<1)^taps; else fill <<= 1; } } fill &= 0x0ffff; if (dbg) { printf("BLOCKCRC(%d,??) = %04x\n", len, fill); } return fill; } void SDSPISIM::add_block_crc(int len, char *buf) const { unsigned fill = blockcrc(len, &buf[1]); buf[len+1] = (fill >> 8)&0x0ff; buf[len+2] = (fill )&0x0ff; }
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