/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2008 by Maurus Cuelenaere * * This program is free software; 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 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "config.h" #include "jz4740.h" #include "ata.h" #include "ata_idle_notify.h" #include "ata-sd-target.h" #include "disk.h" #include "fat.h" #include "led.h" #include "hotswap.h" #include "logf.h" #include "sd.h" #include "system.h" #include "kernel.h" #include "storage.h" #include "string.h" #include "usb.h" static long last_disk_activity = -1; #ifdef CONFIG_STORAGE_MULTI static int sd_drive_nr = 0; #endif static tCardInfo card; static long sd_stack[(DEFAULT_STACK_SIZE*2 + 0x1c0)/sizeof(long)]; static const char sd_thread_name[] = "ata/sd"; static struct event_queue sd_queue; static struct mutex sd_mtx; static struct wakeup sd_wakeup; static void sd_thread(void) __attribute__((noreturn)); static int use_4bit; static int num_6; static int sd2_0; //#define SD_DMA_ENABLE #define SD_DMA_INTERRUPT 0 //#define DEBUG(x...) logf(x) #define DEBUG(x, ...) #define SD_INSERT_STATUS() __gpio_get_pin(MMC_CD_PIN) #define SD_RESET() __msc_reset() #define SD_IRQ_MASK() \ do { \ REG_MSC_IMASK = 0xffff; \ REG_MSC_IREG = 0xffff; \ } while (0) /* Error codes */ enum sd_result_t { SD_NO_RESPONSE = -1, SD_NO_ERROR = 0, SD_ERROR_OUT_OF_RANGE, SD_ERROR_ADDRESS, SD_ERROR_BLOCK_LEN, SD_ERROR_ERASE_SEQ, SD_ERROR_ERASE_PARAM, SD_ERROR_WP_VIOLATION, SD_ERROR_CARD_IS_LOCKED, SD_ERROR_LOCK_UNLOCK_FAILED, SD_ERROR_COM_CRC, SD_ERROR_ILLEGAL_COMMAND, SD_ERROR_CARD_ECC_FAILED, SD_ERROR_CC, SD_ERROR_GENERAL, SD_ERROR_UNDERRUN, SD_ERROR_OVERRUN, SD_ERROR_CID_CSD_OVERWRITE, SD_ERROR_STATE_MISMATCH, SD_ERROR_HEADER_MISMATCH, SD_ERROR_TIMEOUT, SD_ERROR_CRC, SD_ERROR_DRIVER_FAILURE, }; /* Standard MMC/SD clock speeds */ #define MMC_CLOCK_SLOW 400000 /* 400 kHz for initial setup */ #define SD_CLOCK_FAST 24000000 /* 24 MHz for SD Cards */ #define SD_CLOCK_HIGH 48000000 /* 48 MHz for SD Cards */ /* Extra commands for state control */ /* Use negative numbers to disambiguate */ #define SD_CIM_RESET -1 /* Proprietary commands, illegal/reserved according to SD Specification 2.00 */ /* class 1 */ #define SD_READ_DAT_UNTIL_STOP 11 /* adtc [31:0] dadr R1 */ /* class 3 */ #define SD_WRITE_DAT_UNTIL_STOP 20 /* adtc [31:0] data addr R1 */ /* class 4 */ #define SD_PROGRAM_CID 26 /* adtc R1 */ #define SD_PROGRAM_CSD 27 /* adtc R1 */ /* class 9 */ #define SD_GO_IRQ_STATE 40 /* bcr R5 */ /* Don't change the order of these; they are used in dispatch tables */ enum sd_rsp_t { RESPONSE_NONE = 0, RESPONSE_R1 = 1, RESPONSE_R1B = 2, RESPONSE_R2_CID = 3, RESPONSE_R2_CSD = 4, RESPONSE_R3 = 5, RESPONSE_R4 = 6, RESPONSE_R5 = 7, RESPONSE_R6 = 8, RESPONSE_R7 = 9, }; /* MMC status in R1 Type e : error bit s : status bit r : detected and set for the actual command response x : detected and set during command execution. the host must poll the card by sending status command in order to read these bits. Clear condition a : according to the card state b : always related to the previous command. Reception of a valid command will clear it (with a delay of one command) c : clear by read */ #define R1_OUT_OF_RANGE (1 << 31) /* er, c */ #define R1_ADDRESS_ERROR (1 << 30) /* erx, c */ #define R1_BLOCK_LEN_ERROR (1 << 29) /* er, c */ #define R1_ERASE_SEQ_ERROR (1 << 28) /* er, c */ #define R1_ERASE_PARAM (1 << 27) /* ex, c */ #define R1_WP_VIOLATION (1 << 26) /* erx, c */ #define R1_CARD_IS_LOCKED (1 << 25) /* sx, a */ #define R1_LOCK_UNLOCK_FAILED (1 << 24) /* erx, c */ #define R1_COM_CRC_ERROR (1 << 23) /* er, b */ #define R1_ILLEGAL_COMMAND (1 << 22) /* er, b */ #define R1_CARD_ECC_FAILED (1 << 21) /* ex, c */ #define R1_CC_ERROR (1 << 20) /* erx, c */ #define R1_ERROR (1 << 19) /* erx, c */ #define R1_UNDERRUN (1 << 18) /* ex, c */ #define R1_OVERRUN (1 << 17) /* ex, c */ #define R1_CID_CSD_OVERWRITE (1 << 16) /* erx, c, CID/CSD overwrite */ #define R1_WP_ERASE_SKIP (1 << 15) /* sx, c */ #define R1_CARD_ECC_DISABLED (1 << 14) /* sx, a */ #define R1_ERASE_RESET (1 << 13) /* sr, c */ #define R1_STATUS(x) (x & 0xFFFFE000) #define R1_CURRENT_STATE(x) ((x & 0x00001E00) >> 9) /* sx, b (4 bits) */ #define R1_READY_FOR_DATA (1 << 8) /* sx, a */ #define R1_APP_CMD (1 << 7) /* sr, c */ /* These are unpacked versions of the actual responses */ struct sd_response_r1 { unsigned char cmd; unsigned int status; }; struct sd_response_r3 { unsigned int ocr; }; #define SD_CARD_BUSY 0x80000000 /* Card Power up status bit */ struct sd_request { int index; /* Slot index - used for CS lines */ int cmd; /* Command to send */ unsigned int arg; /* Argument to send */ enum sd_rsp_t rtype; /* Response type expected */ /* Data transfer (these may be modified at the low level) */ unsigned short nob; /* Number of blocks to transfer*/ unsigned short block_len; /* Block length */ unsigned char *buffer; /* Data buffer */ unsigned int cnt; /* Data length, for PIO */ /* Results */ unsigned char response[18]; /* Buffer to store response - CRC is optional */ enum sd_result_t result; }; #define SD_OCR_ARG 0x00ff8000 /* Argument of OCR */ /*********************************************************************** * SD Events */ #define SD_EVENT_NONE 0x00 /* No events */ #define SD_EVENT_RX_DATA_DONE 0x01 /* Rx data done */ #define SD_EVENT_TX_DATA_DONE 0x02 /* Tx data done */ #define SD_EVENT_PROG_DONE 0x04 /* Programming is done */ /************************************************************************** * Utility functions **************************************************************************/ #define PARSE_U32(_buf,_index) \ (((unsigned int)_buf[_index]) << 24) | (((unsigned int)_buf[_index+1]) << 16) | \ (((unsigned int)_buf[_index+2]) << 8) | ((unsigned int)_buf[_index+3]); #define PARSE_U16(_buf,_index) \ (((unsigned short)_buf[_index]) << 8) | ((unsigned short)_buf[_index+1]); static int sd_unpack_r1(struct sd_request *request, struct sd_response_r1 *r1) { unsigned char *buf = request->response; if (request->result) return request->result; r1->cmd = buf[0]; r1->status = PARSE_U32(buf,1); DEBUG("sd_unpack_r1: cmd=%d status=%08x", r1->cmd, r1->status); if (R1_STATUS(r1->status)) { if (r1->status & R1_OUT_OF_RANGE) return SD_ERROR_OUT_OF_RANGE; if (r1->status & R1_ADDRESS_ERROR) return SD_ERROR_ADDRESS; if (r1->status & R1_BLOCK_LEN_ERROR) return SD_ERROR_BLOCK_LEN; if (r1->status & R1_ERASE_SEQ_ERROR) return SD_ERROR_ERASE_SEQ; if (r1->status & R1_ERASE_PARAM) return SD_ERROR_ERASE_PARAM; if (r1->status & R1_WP_VIOLATION) return SD_ERROR_WP_VIOLATION; //if (r1->status & R1_CARD_IS_LOCKED) return SD_ERROR_CARD_IS_LOCKED; if (r1->status & R1_LOCK_UNLOCK_FAILED) return SD_ERROR_LOCK_UNLOCK_FAILED; if (r1->status & R1_COM_CRC_ERROR) return SD_ERROR_COM_CRC; if (r1->status & R1_ILLEGAL_COMMAND) return SD_ERROR_ILLEGAL_COMMAND; if (r1->status & R1_CARD_ECC_FAILED) return SD_ERROR_CARD_ECC_FAILED; if (r1->status & R1_CC_ERROR) return SD_ERROR_CC; if (r1->status & R1_ERROR) return SD_ERROR_GENERAL; if (r1->status & R1_UNDERRUN) return SD_ERROR_UNDERRUN; if (r1->status & R1_OVERRUN) return SD_ERROR_OVERRUN; if (r1->status & R1_CID_CSD_OVERWRITE) return SD_ERROR_CID_CSD_OVERWRITE; } if (buf[0] != request->cmd) return SD_ERROR_HEADER_MISMATCH; /* This should be last - it's the least dangerous error */ return 0; } static int sd_unpack_r6(struct sd_request *request, struct sd_response_r1 *r1, unsigned long *rca) { unsigned char *buf = request->response; if (request->result) return request->result; *rca = PARSE_U16(buf,1); /* Save RCA returned by the SD Card */ *(buf+1) = 0; *(buf+2) = 0; return sd_unpack_r1(request, r1); } static int sd_unpack_r3(struct sd_request *request, struct sd_response_r3 *r3) { unsigned char *buf = request->response; if (request->result) return request->result; r3->ocr = PARSE_U32(buf,1); DEBUG("sd_unpack_r3: ocr=%08x", r3->ocr); if (buf[0] != 0x3f) return SD_ERROR_HEADER_MISMATCH; return 0; } /* Stop the MMC clock and wait while it happens */ static inline int jz_sd_stop_clock(void) { register int timeout = 1000; //DEBUG("stop MMC clock"); REG_MSC_STRPCL = MSC_STRPCL_CLOCK_CONTROL_STOP; while (timeout && (REG_MSC_STAT & MSC_STAT_CLK_EN)) { timeout--; if (timeout == 0) { DEBUG("Timeout on stop clock waiting"); return SD_ERROR_TIMEOUT; } udelay(1); } //DEBUG("clock off time is %d microsec", timeout); return SD_NO_ERROR; } /* Start the MMC clock and operation */ static inline int jz_sd_start_clock(void) { REG_MSC_STRPCL = MSC_STRPCL_CLOCK_CONTROL_START | MSC_STRPCL_START_OP; return SD_NO_ERROR; } static int jz_sd_check_status(struct sd_request *request) { (void)request; unsigned int status = REG_MSC_STAT; /* Checking for response or data timeout */ if (status & (MSC_STAT_TIME_OUT_RES | MSC_STAT_TIME_OUT_READ)) { DEBUG("SD timeout, MSC_STAT 0x%x CMD %d", status, request->cmd); return SD_ERROR_TIMEOUT; } /* Checking for CRC error */ if (status & (MSC_STAT_CRC_READ_ERROR | MSC_STAT_CRC_WRITE_ERROR | MSC_STAT_CRC_RES_ERR)) { DEBUG("SD CRC error, MSC_STAT 0x%x", status); return SD_ERROR_CRC; } /* Checking for FIFO empty */ /*if(status & MSC_STAT_DATA_FIFO_EMPTY && request->rtype != RESPONSE_NONE) { DEBUG("SD FIFO empty, MSC_STAT 0x%x", status); return SD_ERROR_UNDERRUN; }*/ return SD_NO_ERROR; } /* Obtain response to the command and store it to response buffer */ static void jz_sd_get_response(struct sd_request *request) { int i; unsigned char *buf; unsigned int data; DEBUG("fetch response for request %d, cmd %d", request->rtype, request->cmd); buf = request->response; request->result = SD_NO_ERROR; switch (request->rtype) { case RESPONSE_R1: case RESPONSE_R1B: case RESPONSE_R7: case RESPONSE_R6: case RESPONSE_R3: case RESPONSE_R4: case RESPONSE_R5: { data = REG_MSC_RES; buf[0] = (data >> 8) & 0xff; buf[1] = data & 0xff; data = REG_MSC_RES; buf[2] = (data >> 8) & 0xff; buf[3] = data & 0xff; data = REG_MSC_RES; buf[4] = data & 0xff; DEBUG("request %d, response [%02x %02x %02x %02x %02x]", request->rtype, buf[0], buf[1], buf[2], buf[3], buf[4]); break; } case RESPONSE_R2_CID: case RESPONSE_R2_CSD: { for (i = 0; i < 16; i += 2) { data = REG_MSC_RES; buf[i] = (data >> 8) & 0xff; buf[i + 1] = data & 0xff; } DEBUG("request %d, response []", request->rtype); break; } case RESPONSE_NONE: DEBUG("No response"); break; default: DEBUG("unhandled response type for request %d", request->rtype); break; } } #ifdef SD_DMA_ENABLE static void jz_sd_receive_data_dma(struct sd_request *req) { unsigned int size = req->block_len * req->nob; #if MMC_DMA_INTERRUPT unsigned char err = 0; #endif /* flush dcache */ //dma_cache_wback_inv((unsigned long) req->buffer, size); /* setup dma channel */ REG_DMAC_DSAR(DMA_SD_RX_CHANNEL) = PHYSADDR(MSC_RXFIFO); /* DMA source addr */ REG_DMAC_DTAR(DMA_SD_RX_CHANNEL) = PHYSADDR((unsigned long) req->buffer); /* DMA dest addr */ REG_DMAC_DTCR(DMA_SD_RX_CHANNEL) = (size + 3) / 4; /* DMA transfer count */ REG_DMAC_DRSR(DMA_SD_RX_CHANNEL) = DMAC_DRSR_RS_MSCIN; /* DMA request type */ #if SD_DMA_INTERRUPT REG_DMAC_DCMD(DMA_SD_RX_CHANNEL) = DMAC_DCMD_DAI | DMAC_DCMD_SWDH_32 | DMAC_DCMD_DWDH_32 | DMAC_DCMD_DS_32BIT | DMAC_DCMD_TIE; REG_DMAC_DCCSR(DMA_SD_RX_CHANNEL) = DMAC_DCCSR_EN | DMAC_DCCSR_NDES; OSSemPend(sd_dma_rx_sem, 100, &err); #else REG_DMAC_DCMD(DMA_SD_RX_CHANNEL) = DMAC_DCMD_DAI | DMAC_DCMD_SWDH_32 | DMAC_DCMD_DWDH_32 | DMAC_DCMD_DS_32BIT; REG_DMAC_DCCSR(DMA_SD_RX_CHANNEL) = DMAC_DCCSR_EN | DMAC_DCCSR_NDES; //while (REG_DMAC_DTCR(DMA_SD_RX_CHANNEL)); while( !(REG_DMAC_DCCSR(DMA_SD_RX_CHANNEL) & DMAC_DCCSR_TT) ); #endif /* clear status and disable channel */ REG_DMAC_DCCSR(DMA_SD_RX_CHANNEL) = 0; } static void jz_mmc_transmit_data_dma(struct mmc_request *req) { unsigned int size = req->block_len * req->nob; #if SD_DMA_INTERRUPT unsigned char err = 0; #endif /* flush dcache */ //dma_cache_wback_inv((unsigned long) req->buffer, size); /* setup dma channel */ REG_DMAC_DSAR(DMA_SD_TX_CHANNEL) = PHYSADDR((unsigned long) req->buffer); /* DMA source addr */ REG_DMAC_DTAR(DMA_SD_TX_CHANNEL) = PHYSADDR(MSC_TXFIFO); /* DMA dest addr */ REG_DMAC_DTCR(DMA_SD_TX_CHANNEL) = (size + 3) / 4; /* DMA transfer count */ REG_DMAC_DRSR(DMA_SD_TX_CHANNEL) = DMAC_DRSR_RS_MSCOUT; /* DMA request type */ #if SD_DMA_INTERRUPT REG_DMAC_DCMD(DMA_SD_TX_CHANNEL) = DMAC_DCMD_SAI | DMAC_DCMD_SWDH_32 | DMAC_DCMD_DWDH_32 | DMAC_DCMD_DS_32BIT | DMAC_DCMD_TIE; REG_DMAC_DCCSR(DMA_SD_TX_CHANNEL) = DMAC_DCCSR_EN | DMAC_DCCSR_NDES; OSSemPend(sd_dma_tx_sem, 100, &err); #else REG_DMAC_DCMD(DMA_SD_TX_CHANNEL) = DMAC_DCMD_SAI | DMAC_DCMD_SWDH_32 | DMAC_DCMD_DWDH_32 | DMAC_DCMD_DS_32BIT; REG_DMAC_DCCSR(DMA_SD_TX_CHANNEL) = DMAC_DCCSR_EN | DMAC_DCCSR_NDES; /* wait for dma completion */ while( !(REG_DMAC_DCCSR(DMA_SD_TX_CHANNEL) & DMAC_DCCSR_TT) ); #endif /* clear status and disable channel */ REG_DMAC_DCCSR(DMA_SD_TX_CHANNEL) = 0; } #else /* SD_DMA_ENABLE */ static int jz_sd_receive_data(struct sd_request *req) { unsigned int nob = req->nob; unsigned int wblocklen = (unsigned int) (req->block_len + 3) >> 2; /* length in word */ unsigned char *buf = req->buffer; unsigned int *wbuf = (unsigned int *) buf; unsigned int waligned = (((unsigned int) buf & 0x3) == 0); /* word aligned ? */ unsigned int stat, timeout, data, cnt; for (; nob >= 1; nob--) { timeout = 0x3FFFFFF; while (timeout) { timeout--; stat = REG_MSC_STAT; if (stat & MSC_STAT_TIME_OUT_READ) return SD_ERROR_TIMEOUT; else if (stat & MSC_STAT_CRC_READ_ERROR) return SD_ERROR_CRC; else if (!(stat & MSC_STAT_DATA_FIFO_EMPTY) || (stat & MSC_STAT_DATA_FIFO_AFULL)) /* Ready to read data */ break; udelay(1); } if (!timeout) return SD_ERROR_TIMEOUT; /* Read data from RXFIFO. It could be FULL or PARTIAL FULL */ DEBUG("Receive Data = %d", wblocklen); cnt = wblocklen; while (cnt) { data = REG_MSC_RXFIFO; if (waligned) *wbuf++ = data; else { *buf++ = (unsigned char) (data >> 0); *buf++ = (unsigned char) (data >> 8); *buf++ = (unsigned char) (data >> 16); *buf++ = (unsigned char) (data >> 24); } cnt--; while (cnt && (REG_MSC_STAT & MSC_STAT_DATA_FIFO_EMPTY)); } } return SD_NO_ERROR; } static int jz_sd_transmit_data(struct sd_request *req) { unsigned int nob = req->nob; unsigned int wblocklen = (unsigned int) (req->block_len + 3) >> 2; /* length in word */ unsigned char *buf = req->buffer; unsigned int *wbuf = (unsigned int *) buf; unsigned int waligned = (((unsigned int) buf & 0x3) == 0); /* word aligned ? */ unsigned int stat, timeout, data, cnt; for (; nob >= 1; nob--) { timeout = 0x3FFFFFF; while (timeout) { timeout--; stat = REG_MSC_STAT; if (stat & (MSC_STAT_CRC_WRITE_ERROR | MSC_STAT_CRC_WRITE_ERROR_NOSTS)) return SD_ERROR_CRC; else if (!(stat & MSC_STAT_DATA_FIFO_FULL)) /* Ready to write data */ break; udelay(1); } if (!timeout) return SD_ERROR_TIMEOUT; /* Write data to TXFIFO */ cnt = wblocklen; while (cnt) { while (REG_MSC_STAT & MSC_STAT_DATA_FIFO_FULL); if (waligned) REG_MSC_TXFIFO = *wbuf++; else { data = *buf++; data |= *buf++ << 8; data |= *buf++ << 16; data |= *buf++ << 24; REG_MSC_TXFIFO = data; } cnt--; } } return SD_NO_ERROR; } #endif static inline unsigned int jz_sd_calc_clkrt(unsigned int rate) { unsigned int clkrt; unsigned int clk_src = sd2_0 ? SD_CLOCK_HIGH : SD_CLOCK_FAST; clkrt = 0; while (rate < clk_src) { clkrt++; clk_src >>= 1; } return clkrt; } static inline void cpm_select_msc_clk(unsigned int rate) { unsigned int div = __cpm_get_pllout2() / rate; REG_CPM_MSCCDR = div - 1; } /* Set the MMC clock frequency */ static void jz_sd_set_clock(unsigned int rate) { int clkrt; jz_sd_stop_clock(); /* select clock source from CPM */ cpm_select_msc_clk(rate); REG_CPM_CPCCR |= CPM_CPCCR_CE; clkrt = jz_sd_calc_clkrt(rate); REG_MSC_CLKRT = clkrt; DEBUG("set clock to %u Hz clkrt=%d", rate, clkrt); } /******************************************************************************************************************** ** Name: int jz_sd_exec_cmd() ** Function: send command to the card, and get a response ** Input: struct sd_request *req: SD request ** Output: 0: right >0: error code ********************************************************************************************************************/ static int jz_sd_exec_cmd(struct sd_request *request) { unsigned int cmdat = 0, events = 0; int retval, timeout = 0x3fffff; /* Indicate we have no result yet */ request->result = SD_NO_RESPONSE; if (request->cmd == SD_CIM_RESET) { /* On reset, 1-bit bus width */ use_4bit = 0; /* Reset MMC/SD controller */ __msc_reset(); /* On reset, drop SD clock down */ jz_sd_set_clock(MMC_CLOCK_SLOW); /* On reset, stop SD clock */ jz_sd_stop_clock(); } if (request->cmd == SD_SET_BUS_WIDTH) { if (request->arg == 0x2) { DEBUG("Use 4-bit bus width"); use_4bit = 1; } else { DEBUG("Use 1-bit bus width"); use_4bit = 0; } } /* stop clock */ jz_sd_stop_clock(); /* mask all interrupts */ //REG_MSC_IMASK = 0xffff; /* clear status */ REG_MSC_IREG = 0xffff; /*open interrupt */ REG_MSC_IMASK = (~7); /* use 4-bit bus width when possible */ if (use_4bit) cmdat |= MSC_CMDAT_BUS_WIDTH_4BIT; /* Set command type and events */ switch (request->cmd) { /* SD core extra command */ case SD_CIM_RESET: cmdat |= MSC_CMDAT_INIT; /* Initialization sequence sent prior to command */ break; /* bc - broadcast - no response */ case SD_GO_IDLE_STATE: case SD_SET_DSR: break; /* bcr - broadcast with response */ case SD_APP_OP_COND: case SD_ALL_SEND_CID: case SD_GO_IRQ_STATE: break; /* adtc - addressed with data transfer */ case SD_READ_DAT_UNTIL_STOP: case SD_READ_SINGLE_BLOCK: case SD_READ_MULTIPLE_BLOCK: case SD_SEND_SCR: #if defined(SD_DMA_ENABLE) cmdat |= MSC_CMDAT_DATA_EN | MSC_CMDAT_READ | MSC_CMDAT_DMA_EN; #else cmdat |= MSC_CMDAT_DATA_EN | MSC_CMDAT_READ; #endif events = SD_EVENT_RX_DATA_DONE; break; case 6: if (num_6 < 2) { #if defined(SD_DMA_ENABLE) cmdat |= MSC_CMDAT_DATA_EN | MSC_CMDAT_READ | MSC_CMDAT_DMA_EN; #else cmdat |= MSC_CMDAT_DATA_EN | MSC_CMDAT_READ; #endif events = SD_EVENT_RX_DATA_DONE; } break; case SD_WRITE_DAT_UNTIL_STOP: case SD_WRITE_BLOCK: case SD_WRITE_MULTIPLE_BLOCK: case SD_PROGRAM_CID: case SD_PROGRAM_CSD: case SD_LOCK_UNLOCK: #if defined(SD_DMA_ENABLE) cmdat |= MSC_CMDAT_DATA_EN | MSC_CMDAT_WRITE | MSC_CMDAT_DMA_EN; #else cmdat |= MSC_CMDAT_DATA_EN | MSC_CMDAT_WRITE; #endif events = SD_EVENT_TX_DATA_DONE | SD_EVENT_PROG_DONE; break; case SD_STOP_TRANSMISSION: events = SD_EVENT_PROG_DONE; break; /* ac - no data transfer */ default: break; } /* Set response type */ switch (request->rtype) { case RESPONSE_NONE: break; case RESPONSE_R1B: cmdat |= MSC_CMDAT_BUSY; /* FALLTHRU */ case RESPONSE_R1: case RESPONSE_R7: cmdat |= MSC_CMDAT_RESPONSE_R1; break; case RESPONSE_R2_CID: case RESPONSE_R2_CSD: cmdat |= MSC_CMDAT_RESPONSE_R2; break; case RESPONSE_R3: cmdat |= MSC_CMDAT_RESPONSE_R3; break; case RESPONSE_R4: cmdat |= MSC_CMDAT_RESPONSE_R4; break; case RESPONSE_R5: cmdat |= MSC_CMDAT_RESPONSE_R5; break; case RESPONSE_R6: cmdat |= MSC_CMDAT_RESPONSE_R6; break; default: break; } /* Set command index */ if (request->cmd == SD_CIM_RESET) REG_MSC_CMD = SD_GO_IDLE_STATE; else REG_MSC_CMD = request->cmd; /* Set argument */ REG_MSC_ARG = request->arg; /* Set block length and nob */ if (request->cmd == SD_SEND_SCR) { /* get SCR from DataFIFO */ REG_MSC_BLKLEN = 8; REG_MSC_NOB = 1; } else { REG_MSC_BLKLEN = request->block_len; REG_MSC_NOB = request->nob; } /* Set command */ REG_MSC_CMDAT = cmdat; DEBUG("Send cmd %d cmdat: %x arg: %x resp %d", request->cmd, cmdat, request->arg, request->rtype); /* Start SD clock and send command to card */ jz_sd_start_clock(); /* Wait for command completion */ //__intc_unmask_irq(IRQ_MSC); //wakeup_wait(&sd_wakeup, 100); while (timeout-- && !(REG_MSC_STAT & MSC_STAT_END_CMD_RES)); if (timeout == 0) return SD_ERROR_TIMEOUT; REG_MSC_IREG = MSC_IREG_END_CMD_RES; /* clear flag */ /* Check for status */ retval = jz_sd_check_status(request); if (retval) return retval; /* Complete command with no response */ if (request->rtype == RESPONSE_NONE) return SD_NO_ERROR; /* Get response */ jz_sd_get_response(request); /* Start data operation */ if (events & (SD_EVENT_RX_DATA_DONE | SD_EVENT_TX_DATA_DONE)) { if (events & SD_EVENT_RX_DATA_DONE) { if (request->cmd == SD_SEND_SCR) { /* SD card returns SCR register as data. SD core expect it in the response buffer, after normal response. */ request->buffer = (unsigned char *) ((unsigned int) request->response + 5); } #ifdef SD_DMA_ENABLE jz_sd_receive_data_dma(request); #else jz_sd_receive_data(request); #endif } if (events & SD_EVENT_TX_DATA_DONE) { #ifdef SD_DMA_ENABLE jz_sd_transmit_data_dma(request); #else jz_sd_transmit_data(request); #endif } //__intc_unmask_irq(IRQ_MSC); //wakeup_wait(&sd_wakeup, 100); /* Wait for Data Done */ while (!(REG_MSC_IREG & MSC_IREG_DATA_TRAN_DONE)); REG_MSC_IREG = MSC_IREG_DATA_TRAN_DONE; /* clear status */ } /* Wait for Prog Done event */ if (events & SD_EVENT_PROG_DONE) { //__intc_unmask_irq(IRQ_MSC); //wakeup_wait(&sd_wakeup, 100); while (!(REG_MSC_IREG & MSC_IREG_PRG_DONE)); REG_MSC_IREG = MSC_IREG_PRG_DONE; /* clear status */ } /* Command completed */ return SD_NO_ERROR; /* return successfully */ } /******************************************************************************************************************* ** Name: int sd_chkcard() ** Function: check whether card is insert entirely ** Input: NULL ** Output: 1: insert entirely 0: not insert entirely ********************************************************************************************************************/ static int jz_sd_chkcard(void) { return (SD_INSERT_STATUS() == 0 ? 1 : 0); } #if SD_DMA_INTERRUPT static void jz_sd_tx_handler(unsigned int arg) { if (__dmac_channel_address_error_detected(arg)) { DEBUG("%s: DMAC address error.", __FUNCTION__); __dmac_channel_clear_address_error(arg); } if (__dmac_channel_transmit_end_detected(arg)) { __dmac_channel_clear_transmit_end(arg); OSSemPost(sd_dma_tx_sem); } } static void jz_sd_rx_handler(unsigned int arg) { if (__dmac_channel_address_error_detected(arg)) { DEBUG("%s: DMAC address error.", __FUNCTION__); __dmac_channel_clear_address_error(arg); } if (__dmac_channel_transmit_end_detected(arg)) { __dmac_channel_clear_transmit_end(arg); OSSemPost(sd_dma_rx_sem); } } #endif /* MSC interrupt handler */ void MSC(void) { //wakeup_signal(&sd_wakeup); logf("MSC interrupt"); } static void sd_gpio_setup_irq(bool inserted) { if(inserted) __gpio_as_irq_rise_edge(MMC_CD_PIN); else __gpio_as_irq_fall_edge(MMC_CD_PIN); } /******************************************************************************************************************* ** Name: void sd_hardware_init() ** Function: initialize the hardware condiction that access sd card ** Input: NULL ** Output: NULL ********************************************************************************************************************/ static void jz_sd_hardware_init(void) { __cpm_start_msc(); /* enable mmc clock */ sd_init_gpio(); /* init GPIO */ sd_gpio_setup_irq(jz_sd_chkcard()); #ifdef SD_POWER_ON SD_POWER_ON(); /* turn on power of card */ #endif SD_RESET(); /* reset mmc/sd controller */ SD_IRQ_MASK(); /* mask all IRQs */ jz_sd_stop_clock(); /* stop SD clock */ #ifdef SD_DMA_ENABLE // __cpm_start_dmac(); // __dmac_enable_module(); // REG_DMAC_DMACR = DMAC_DMACR_DME; #if SD_DMA_INTERRUPT sd_dma_rx_sem = OSSemCreate(0); sd_dma_tx_sem = OSSemCreate(0); request_irq(IRQ_DMA_0 + RX_DMA_CHANNEL, jz_sd_rx_handler, RX_DMA_CHANNEL); request_irq(IRQ_DMA_0 + TX_DMA_CHANNEL, jz_sd_tx_handler, TX_DMA_CHANNEL); #endif #endif } static int sd_send_cmd(struct sd_request *request, int cmd, unsigned int arg, unsigned short nob, unsigned short block_len, enum sd_rsp_t rtype, unsigned char* buffer) { request->cmd = cmd; request->arg = arg; request->rtype = rtype; request->nob = nob; request->block_len = block_len; request->buffer = buffer; request->cnt = nob * block_len; return jz_sd_exec_cmd(request); } static void sd_simple_cmd(struct sd_request *request, int cmd, unsigned int arg, enum sd_rsp_t rtype) { sd_send_cmd(request, cmd, arg, 0, 0, rtype, NULL); } #define SD_INIT_DOING 0 #define SD_INIT_PASSED 1 #define SD_INIT_FAILED 2 static int sd_init_card_state(struct sd_request *request) { struct sd_response_r1 r1; struct sd_response_r3 r3; int retval, i, ocr = 0x40300000, limit_41 = 0; switch (request->cmd) { case SD_GO_IDLE_STATE: /* No response to parse */ sd_simple_cmd(request, SD_SEND_IF_COND, 0x1AA, RESPONSE_R1); break; case SD_SEND_IF_COND: retval = sd_unpack_r1(request, &r1); sd_simple_cmd(request, SD_APP_CMD, 0, RESPONSE_R1); break; case SD_APP_CMD: retval = sd_unpack_r1(request, &r1); if (retval & (limit_41 < 100)) { DEBUG("sd_init_card_state: unable to SD_APP_CMD error=%d", retval); limit_41++; sd_simple_cmd(request, SD_APP_OP_COND, ocr, RESPONSE_R3); } else if (limit_41 < 100) { limit_41++; sd_simple_cmd(request, SD_APP_OP_COND, ocr, RESPONSE_R3); } else /* reset the card to idle*/ sd_simple_cmd(request, SD_GO_IDLE_STATE, 0, RESPONSE_NONE); break; case SD_APP_OP_COND: retval = sd_unpack_r3(request, &r3); if (retval) break; DEBUG("sd_init_card_state: read ocr value = 0x%08x", r3.ocr); card.ocr = r3.ocr; if(!(r3.ocr & SD_CARD_BUSY || ocr == 0)) { sleep(HZ / 100); sd_simple_cmd(request, SD_APP_CMD, 0, RESPONSE_R1); } else { /* Set the data bus width to 4 bits */ use_4bit = 1; sd_simple_cmd(request, SD_ALL_SEND_CID, 0, RESPONSE_R2_CID); } break; case SD_ALL_SEND_CID: for(i=0; i<4; i++) card.cid[i] = ((request->response[1+i*4]<<24) | (request->response[2+i*4]<<16) | (request->response[3+i*4]<< 8) | request->response[4+i*4]); logf("CID: %08lx%08lx%08lx%08lx", card.cid[0], card.cid[1], card.cid[2], card.cid[3]); sd_simple_cmd(request, SD_SEND_RELATIVE_ADDR, 0, RESPONSE_R6); break; case SD_SEND_RELATIVE_ADDR: retval = sd_unpack_r6(request, &r1, &card.rca); card.rca = card.rca << 16; DEBUG("sd_init_card_state: Get RCA from SD: 0x%04lx Status: %x", card.rca, r1.status); if (retval) { DEBUG("sd_init_card_state: unable to SET_RELATIVE_ADDR error=%d", retval); return SD_INIT_FAILED; } sd_simple_cmd(request, SD_SEND_CSD, card.rca, RESPONSE_R2_CSD); break; case SD_SEND_CSD: for(i=0; i<4; i++) card.csd[i] = ((request->response[1+i*4]<<24) | (request->response[2+i*4]<<16) | (request->response[3+i*4]<< 8) | request->response[4+i*4]); sd_parse_csd(&card); sd2_0 = (card_extract_bits(card.csd, 127, 2) == 1); logf("CSD: %08lx%08lx%08lx%08lx", card.csd[0], card.csd[1], card.csd[2], card.csd[3]); DEBUG("SD card is ready"); jz_sd_set_clock(SD_CLOCK_FAST); return SD_INIT_PASSED; default: DEBUG("sd_init_card_state: error! Illegal last cmd %d", request->cmd); return SD_INIT_FAILED; } return SD_INIT_DOING; } static int sd_switch(struct sd_request *request, int mode, int group, unsigned char value, unsigned char * resp) { unsigned int arg; mode = !!mode; value &= 0xF; arg = (mode << 31 | 0x00FFFFFF); arg &= ~(0xF << (group * 4)); arg |= value << (group * 4); sd_send_cmd(request, 6, arg, 1, 64, RESPONSE_R1, resp); return 0; } /* * Fetches and decodes switch information */ static int sd_read_switch(struct sd_request *request) { unsigned int status[64 / 4]; memset((unsigned char *)status, 0, 64); sd_switch(request, 0, 0, 1, (unsigned char*) status); if (((unsigned char *)status)[13] & 0x02) return 0; else return 1; } /* * Test if the card supports high-speed mode and, if so, switch to it. */ static int sd_switch_hs(struct sd_request *request) { unsigned int status[64 / 4]; sd_switch(request, 1, 0, 1, (unsigned char*) status); return 0; } static int sd_select_card(void) { struct sd_request request; struct sd_response_r1 r1; int retval; sd_simple_cmd(&request, SD_SELECT_CARD, card.rca, RESPONSE_R1B); retval = sd_unpack_r1(&request, &r1); if (retval) return retval; if (sd2_0) { retval = sd_read_switch(&request); if (!retval) { sd_switch_hs(&request); jz_sd_set_clock(SD_CLOCK_HIGH); } } num_6 = 3; sd_simple_cmd(&request, SD_APP_CMD, card.rca, RESPONSE_R1); retval = sd_unpack_r1(&request, &r1); if (retval) return retval; sd_simple_cmd(&request, SD_SET_BUS_WIDTH, 2, RESPONSE_R1); retval = sd_unpack_r1(&request, &r1); if (retval) return retval; card.initialized = 1; return 0; } static int sd_init_device(void) { int retval; struct sd_request init_req; mutex_lock(&sd_mtx); /* Initialise card data as blank */ memset(&card, 0, sizeof(tCardInfo)); sd2_0 = 0; num_6 = 0; use_4bit = 0; /* reset mmc/sd controller */ jz_sd_hardware_init(); sd_simple_cmd(&init_req, SD_CIM_RESET, 0, RESPONSE_NONE); sd_simple_cmd(&init_req, SD_GO_IDLE_STATE, 0, RESPONSE_NONE); sleep(HZ/2); /* Give the card/controller some rest */ while((retval = sd_init_card_state(&init_req)) == SD_INIT_DOING); retval = (retval == SD_INIT_PASSED ? sd_select_card() : -1); mutex_unlock(&sd_mtx); return retval; } int sd_init(void) { static bool inited = false; if(!inited) { wakeup_init(&sd_wakeup); mutex_init(&sd_mtx); queue_init(&sd_queue, true); create_thread(sd_thread, sd_stack, sizeof(sd_stack), 0, sd_thread_name IF_PRIO(, PRIORITY_USER_INTERFACE) IF_COP(, CPU)); inited = true; } return sd_init_device(); } static inline bool card_detect_target(void) { return (jz_sd_chkcard() == 1); } tCardInfo* card_get_info_target(int card_no) { (void)card_no; return &card; } int sd_read_sectors(IF_MV2(int drive,) unsigned long start, int count, void* buf) { #ifdef HAVE_MULTIVOLUME (void)drive; #endif mutex_lock(&sd_mtx); led(true); struct sd_request request; struct sd_response_r1 r1; int retval = -1; if (!card_detect_target() || count == 0 || start > card.numblocks) goto err; if(card.initialized == 0 && !sd_init_device()) goto err; sd_simple_cmd(&request, SD_SEND_STATUS, card.rca, RESPONSE_R1); retval = sd_unpack_r1(&request, &r1); if (retval && (retval != SD_ERROR_STATE_MISMATCH)) goto err; sd_simple_cmd(&request, SD_SET_BLOCKLEN, SD_BLOCK_SIZE, RESPONSE_R1); if ((retval = sd_unpack_r1(&request, &r1))) goto err; if (sd2_0) { sd_send_cmd(&request, SD_READ_MULTIPLE_BLOCK, start, count, SD_BLOCK_SIZE, RESPONSE_R1, buf); if ((retval = sd_unpack_r1(&request, &r1))) goto err; } else { sd_send_cmd(&request, SD_READ_MULTIPLE_BLOCK, start * SD_BLOCK_SIZE, count, SD_BLOCK_SIZE, RESPONSE_R1, buf); if ((retval = sd_unpack_r1(&request, &r1))) goto err; } last_disk_activity = current_tick; sd_simple_cmd(&request, SD_STOP_TRANSMISSION, 0, RESPONSE_R1B); if ((retval = sd_unpack_r1(&request, &r1))) goto err; err: led(false); mutex_unlock(&sd_mtx); return retval; } int sd_write_sectors(IF_MV2(int drive,) unsigned long start, int count, const void* buf) { #ifdef HAVE_MULTIVOLUME (void)drive; #endif mutex_lock(&sd_mtx); led(true); struct sd_request request; struct sd_response_r1 r1; int retval = -1; if (!card_detect_target() || count == 0 || start > card.numblocks) goto err; if(card.initialized == 0 && !sd_init_device()) goto err; sd_simple_cmd(&request, SD_SEND_STATUS, card.rca, RESPONSE_R1); retval = sd_unpack_r1(&request, &r1); if (retval && (retval != SD_ERROR_STATE_MISMATCH)) goto err; sd_simple_cmd(&request, SD_SET_BLOCKLEN, SD_BLOCK_SIZE, RESPONSE_R1); if ((retval = sd_unpack_r1(&request, &r1))) goto err; if (sd2_0) { sd_send_cmd(&request, SD_WRITE_MULTIPLE_BLOCK, start, count, SD_BLOCK_SIZE, RESPONSE_R1, (void*)buf); if ((retval = sd_unpack_r1(&request, &r1))) goto err; } else { sd_send_cmd(&request, SD_WRITE_MULTIPLE_BLOCK, start * SD_BLOCK_SIZE, count, SD_BLOCK_SIZE, RESPONSE_R1, (void*)buf); if ((retval = sd_unpack_r1(&request, &r1))) goto err; } last_disk_activity = current_tick; sd_simple_cmd(&request, SD_STOP_TRANSMISSION, 0, RESPONSE_R1B); if ((retval = sd_unpack_r1(&request, &r1))) goto err; err: led(false); mutex_unlock(&sd_mtx); return retval; } long sd_last_disk_activity(void) { return last_disk_activity; } int sd_spinup_time(void) { return 0; } void sd_enable(bool on) { (void)on; } void sd_sleepnow(void) { } bool sd_disk_is_active(void) { return sd_mtx.locked; } int sd_soft_reset(void) { return 0; } #ifdef HAVE_HOTSWAP bool sd_removable(IF_MV_NONVOID(int drive)) { #ifdef HAVE_MULTIVOLUME (void)drive; #endif return true; } void card_enable_monitoring_target(bool on) { if(on) sd_gpio_setup_irq(card_detect_target()); else __gpio_mask_irq(MMC_CD_PIN); } static int sd_oneshot_callback(struct timeout *tmo) { (void)tmo; int state = card_detect_target(); /* This is called only if the state was stable for 300ms - check state * and post appropriate event. */ if (state) queue_broadcast(SYS_HOTSWAP_INSERTED, 0); else queue_broadcast(SYS_HOTSWAP_EXTRACTED, 0); sd_gpio_setup_irq(state); return 0; } /* called on insertion/removal interrupt */ void MMC_CD_IRQ(void) { static struct timeout sd_oneshot; timeout_register(&sd_oneshot, sd_oneshot_callback, (3*HZ/10), 0); } #endif bool sd_present(IF_MV_NONVOID(int drive)) { #ifdef HAVE_MULTIDRIVE (void)drive; #endif return card_detect_target(); } #ifdef CONFIG_STORAGE_MULTI int sd_num_drives(int first_drive) { sd_drive_nr = first_drive; return 1; } #endif static void sd_thread(void) { struct queue_event ev; bool idle_notified = false; while (1) { queue_wait_w_tmo(&sd_queue, &ev, HZ); switch (ev.id) { #ifdef HAVE_HOTSWAP case SYS_HOTSWAP_INSERTED: case SYS_HOTSWAP_EXTRACTED: fat_lock(); /* lock-out FAT activity first - prevent deadlocking via disk_mount that would cause a reverse-order attempt with another thread */ mutex_lock(&sd_mtx); /* lock-out card activity - direct calls into driver that bypass the fat cache */ /* We now have exclusive control of fat cache and ata */ disk_unmount(sd_drive_nr); /* release "by force", ensure file descriptors aren't leaked and any busy ones are invalid if mounting */ /* Force card init for new card, re-init for re-inserted one or * clear if the last attempt to init failed with an error. */ card.initialized = 0; if(ev.id == SYS_HOTSWAP_INSERTED) disk_mount(sd_drive_nr); queue_broadcast(SYS_FS_CHANGED, 0); /* Access is now safe */ mutex_unlock(&sd_mtx); fat_unlock(); break; #endif case SYS_TIMEOUT: if (TIME_BEFORE(current_tick, last_disk_activity+(3*HZ))) idle_notified = false; else { if (!idle_notified) { call_storage_idle_notifys(false); idle_notified = true; } } break; case SYS_USB_CONNECTED: usb_acknowledge(SYS_USB_CONNECTED_ACK); /* Wait until the USB cable is extracted again */ usb_wait_for_disconnect(&sd_queue); break; case SYS_USB_DISCONNECTED: usb_acknowledge(SYS_USB_DISCONNECTED_ACK); break; } } }