/* mini - a Free Software replacement for the Nintendo/BroadOn IOS. SD/MMC interface Copyright (C) 2008, 2009 Sven Peter # This code is licensed to you under the terms of the GNU GPL, version 2; # see file COPYING or http://www.gnu.org/licenses/old-licenses/gpl-2.0.txt */ #ifndef __SDMMC_H__ #define __SDMMC_H__ #include "bsdtypes.h" struct sdmmc_command; typedef struct sdmmc_chip_functions *sdmmc_chipset_tag_t; typedef void *sdmmc_chipset_handle_t; /* clock frequencies for sdmmc_chip_bus_clock() */ #define SDMMC_SDCLK_OFF 0 #define SDMMC_SDCLK_400KHZ 400 #define SDMMC_SDCLK_25MHZ 25000 struct sdmmc_csd { int csdver; /* CSD structure format */ int mmcver; /* MMC version (for CID format) */ int capacity; /* total number of sectors */ int sector_size; /* sector size in bytes */ int read_bl_len; /* block length for reads */ /* ... */ }; struct sdmmc_cid { int mid; /* manufacturer identification number */ int oid; /* OEM/product identification number */ char pnm[8]; /* product name (MMC v1 has the longest) */ int rev; /* product revision */ int psn; /* product serial number */ int mdt; /* manufacturing date */ }; typedef u_int32_t sdmmc_response[4]; struct sdmmc_softc; struct sdmmc_task { void (*func)(void *arg); void *arg; int onqueue; struct sdmmc_softc *sc; }; #define sdmmc_init_task(xtask, xfunc, xarg) do { \ (xtask)->func = (xfunc); \ (xtask)->arg = (xarg); \ (xtask)->onqueue = 0; \ (xtask)->sc = NULL; \ } while (0) #define sdmmc_task_pending(xtask) ((xtask)->onqueue) struct sdmmc_command { // struct sdmmc_task c_task; /* task queue entry */ u_int16_t c_opcode; /* SD or MMC command index */ u_int32_t c_arg; /* SD/MMC command argument */ sdmmc_response c_resp; /* response buffer */ void *c_data; /* buffer to send or read into */ int c_datalen; /* length of data buffer */ int c_blklen; /* block length */ int c_flags; /* see below */ #define SCF_ITSDONE 0x0001 /* command is complete */ #define SCF_CMD(flags) ((flags) & 0x00f0) #define SCF_CMD_AC 0x0000 #define SCF_CMD_ADTC 0x0010 #define SCF_CMD_BC 0x0020 #define SCF_CMD_BCR 0x0030 #define SCF_CMD_READ 0x0040 /* read command (data expected) */ #define SCF_RSP_BSY 0x0100 #define SCF_RSP_136 0x0200 #define SCF_RSP_CRC 0x0400 #define SCF_RSP_IDX 0x0800 #define SCF_RSP_PRESENT 0x1000 /* response types */ #define SCF_RSP_R0 0 /* none */ #define SCF_RSP_R1 (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_IDX) #define SCF_RSP_R1B (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_IDX|SCF_RSP_BSY) #define SCF_RSP_R2 (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_136) #define SCF_RSP_R3 (SCF_RSP_PRESENT) #define SCF_RSP_R4 (SCF_RSP_PRESENT) #define SCF_RSP_R5 (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_IDX) #define SCF_RSP_R5B (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_IDX|SCF_RSP_BSY) #define SCF_RSP_R6 (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_IDX) #define SCF_RSP_R7 (SCF_RSP_PRESENT|SCF_RSP_CRC|SCF_RSP_IDX) int c_error; /* errno value on completion */ int c_timeout; /* Host controller owned fields for data xfer in progress */ int c_resid; /* remaining I/O */ u_char *c_buf; /* remaining data */ }; /* * Decoded PC Card 16 based Card Information Structure (CIS), * per card (function 0) and per function (1 and greater). */ struct sdmmc_cis { u_int16_t manufacturer; #define SDMMC_VENDOR_INVALID 0xffff u_int16_t product; #define SDMMC_PRODUCT_INVALID 0xffff u_int8_t function; #define SDMMC_FUNCTION_INVALID 0xff u_char cis1_major; u_char cis1_minor; char cis1_info_buf[256]; char *cis1_info[4]; }; /* * Structure describing either an SD card I/O function or a SD/MMC * memory card from a "stack of cards" that responded to CMD2. For a * combo card with one I/O function and one memory card, there will be * two of these structures allocated. Each card slot has such a list * of sdmmc_function structures. */ struct sdmmc_function { /* common members */ u_int16_t rca; /* relative card address */ int flags; #define SFF_ERROR 0x0001 /* function is poo; ignore it */ #define SFF_SDHC 0x0002 /* SD High Capacity card */ /* SD card I/O function members */ int number; /* I/O function number or -1 */ struct sdmmc_cis cis; /* decoded CIS */ /* SD/MMC memory card members */ struct sdmmc_csd csd; /* decoded CSD value */ struct sdmmc_cid cid; /* decoded CID value */ sdmmc_response raw_cid; /* temp. storage for decoding */ }; #define SDMMC_LOCK(sc) lockmgr(&(sc)->sc_lock, LK_EXCLUSIVE, NULL) #define SDMMC_UNLOCK(sc) lockmgr(&(sc)->sc_lock, LK_RELEASE, NULL) #define SDMMC_ASSERT_LOCKED(sc) \ KASSERT(lockstatus(&((sc))->sc_lock) == LK_EXCLUSIVE) #ifdef CAN_HAZ_IPC #include "ipc.h" #endif #define SDMMC_DEFAULT_CLOCK 25000 #define SDMMC_DEFAULT_BLOCKLEN 512 #define SDMMC_NO_CARD 1 #define SDMMC_NEW_CARD 2 #define SDMMC_INSERTED 3 void sdmmc_attach(sdmmc_chipset_handle_t handle, const char *name, int no); void sdmmc_needs_discover(void); int sdmmc_select(void); int sdmmc_check_card(void); int sdmmc_ack_card(void); int sdmmc_read(u32 blk_start, u32 blk_count, void *data); #ifdef CAN_HAZ_IPC void sdmmc_ipc(volatile ipc_request *req); #endif /* MMC commands */ /* response type */ #define MMC_GO_IDLE_STATE 0 /* R0 */ #define MMC_SEND_OP_COND 1 /* R3 */ #define MMC_ALL_SEND_CID 2 /* R2 */ #define MMC_SET_RELATIVE_ADDR 3 /* R1 */ #define MMC_SELECT_CARD 7 /* R1 */ #define MMC_SEND_CSD 9 /* R2 */ #define MMC_STOP_TRANSMISSION 12 /* R1B */ #define MMC_SEND_STATUS 13 /* R1 */ #define MMC_SET_BLOCKLEN 16 /* R1 */ #define MMC_READ_BLOCK_SINGLE 17 /* R1 */ #define MMC_READ_BLOCK_MULTIPLE 18 /* R1 */ #define MMC_SET_BLOCK_COUNT 23 /* R1 */ #define MMC_WRITE_BLOCK_SINGLE 24 /* R1 */ #define MMC_WRITE_BLOCK_MULTIPLE 25 /* R1 */ #define MMC_APP_CMD 55 /* R1 */ /* SD commands */ /* response type */ #define SD_SEND_RELATIVE_ADDR 3 /* R6 */ #define SD_SEND_IF_COND 8 /* R7 */ /* SD application commands */ /* response type */ #define SD_APP_SET_BUS_WIDTH 6 /* R1 */ #define SD_APP_OP_COND 41 /* R3 */ /* OCR bits */ #define MMC_OCR_MEM_READY (1<<31) /* memory power-up status bit */ #define MMC_OCR_3_5V_3_6V (1<<23) #define MMC_OCR_3_4V_3_5V (1<<22) #define MMC_OCR_3_3V_3_4V (1<<21) #define MMC_OCR_3_2V_3_3V (1<<20) #define MMC_OCR_3_1V_3_2V (1<<19) #define MMC_OCR_3_0V_3_1V (1<<18) #define MMC_OCR_2_9V_3_0V (1<<17) #define MMC_OCR_2_8V_2_9V (1<<16) #define MMC_OCR_2_7V_2_8V (1<<15) #define MMC_OCR_2_6V_2_7V (1<<14) #define MMC_OCR_2_5V_2_6V (1<<13) #define MMC_OCR_2_4V_2_5V (1<<12) #define MMC_OCR_2_3V_2_4V (1<<11) #define MMC_OCR_2_2V_2_3V (1<<10) #define MMC_OCR_2_1V_2_2V (1<<9) #define MMC_OCR_2_0V_2_1V (1<<8) #define MMC_OCR_1_9V_2_0V (1<<7) #define MMC_OCR_1_8V_1_9V (1<<6) #define MMC_OCR_1_7V_1_8V (1<<5) #define MMC_OCR_1_6V_1_7V (1<<4) #define SD_OCR_SDHC_CAP (1<<30) #define SD_OCR_VOL_MASK 0xFF8000 /* bits 23:15 */ /* R1 response type bits */ #define MMC_R1_READY_FOR_DATA (1<<8) /* ready for next transfer */ #define MMC_R1_APP_CMD (1<<5) /* app. commands supported */ /* 48-bit response decoding (32 bits w/o CRC) */ #define MMC_R1(resp) ((resp)[0]) #define MMC_R3(resp) ((resp)[0]) #define SD_R6(resp) ((resp)[0]) /* RCA argument and response */ #define MMC_ARG_RCA(rca) ((rca) << 16) #define SD_R6_RCA(resp) (SD_R6((resp)) >> 16) /* bus width argument */ #define SD_ARG_BUS_WIDTH_1 0 #define SD_ARG_BUS_WIDTH_4 2 /* MMC R2 response (CSD) */ #define MMC_CSD_CSDVER(resp) MMC_RSP_BITS((resp), 126, 2) #define MMC_CSD_CSDVER_1_0 1 #define MMC_CSD_CSDVER_2_0 2 #define MMC_CSD_MMCVER(resp) MMC_RSP_BITS((resp), 122, 4) #define MMC_CSD_MMCVER_1_0 0 /* MMC 1.0 - 1.2 */ #define MMC_CSD_MMCVER_1_4 1 /* MMC 1.4 */ #define MMC_CSD_MMCVER_2_0 2 /* MMC 2.0 - 2.2 */ #define MMC_CSD_MMCVER_3_1 3 /* MMC 3.1 - 3.3 */ #define MMC_CSD_MMCVER_4_0 4 /* MMC 4 */ #define MMC_CSD_READ_BL_LEN(resp) MMC_RSP_BITS((resp), 80, 4) #define MMC_CSD_C_SIZE(resp) MMC_RSP_BITS((resp), 62, 12) #define MMC_CSD_CAPACITY(resp) ((MMC_CSD_C_SIZE((resp))+1) << \ (MMC_CSD_C_SIZE_MULT((resp))+2)) #define MMC_CSD_C_SIZE_MULT(resp) MMC_RSP_BITS((resp), 47, 3) /* MMC v1 R2 response (CID) */ #define MMC_CID_MID_V1(resp) MMC_RSP_BITS((resp), 104, 24) #define MMC_CID_PNM_V1_CPY(resp, pnm) \ do { \ (pnm)[0] = MMC_RSP_BITS((resp), 96, 8); \ (pnm)[1] = MMC_RSP_BITS((resp), 88, 8); \ (pnm)[2] = MMC_RSP_BITS((resp), 80, 8); \ (pnm)[3] = MMC_RSP_BITS((resp), 72, 8); \ (pnm)[4] = MMC_RSP_BITS((resp), 64, 8); \ (pnm)[5] = MMC_RSP_BITS((resp), 56, 8); \ (pnm)[6] = MMC_RSP_BITS((resp), 48, 8); \ (pnm)[7] = '\0'; \ } while (0) #define MMC_CID_REV_V1(resp) MMC_RSP_BITS((resp), 40, 8) #define MMC_CID_PSN_V1(resp) MMC_RSP_BITS((resp), 16, 24) #define MMC_CID_MDT_V1(resp) MMC_RSP_BITS((resp), 8, 8) /* MMC v2 R2 response (CID) */ #define MMC_CID_MID_V2(resp) MMC_RSP_BITS((resp), 120, 8) #define MMC_CID_OID_V2(resp) MMC_RSP_BITS((resp), 104, 16) #define MMC_CID_PNM_V2_CPY(resp, pnm) \ do { \ (pnm)[0] = MMC_RSP_BITS((resp), 96, 8); \ (pnm)[1] = MMC_RSP_BITS((resp), 88, 8); \ (pnm)[2] = MMC_RSP_BITS((resp), 80, 8); \ (pnm)[3] = MMC_RSP_BITS((resp), 72, 8); \ (pnm)[4] = MMC_RSP_BITS((resp), 64, 8); \ (pnm)[5] = MMC_RSP_BITS((resp), 56, 8); \ (pnm)[6] = '\0'; \ } while (0) #define MMC_CID_PSN_V2(resp) MMC_RSP_BITS((resp), 16, 32) /* SD R2 response (CSD) */ #define SD_CSD_CSDVER(resp) MMC_RSP_BITS((resp), 126, 2) #define SD_CSD_CSDVER_1_0 0 #define SD_CSD_CSDVER_2_0 1 #define SD_CSD_TAAC(resp) MMC_RSP_BITS((resp), 112, 8) #define SD_CSD_TAAC_1_5_MSEC 0x26 #define SD_CSD_NSAC(resp) MMC_RSP_BITS((resp), 104, 8) #define SD_CSD_SPEED(resp) MMC_RSP_BITS((resp), 96, 8) #define SD_CSD_SPEED_25_MHZ 0x32 #define SD_CSD_SPEED_50_MHZ 0x5a #define SD_CSD_CCC(resp) MMC_RSP_BITS((resp), 84, 12) #define SD_CSD_CCC_ALL 0x5f5 #define SD_CSD_READ_BL_LEN(resp) MMC_RSP_BITS((resp), 80, 4) #define SD_CSD_READ_BL_PARTIAL(resp) MMC_RSP_BITS((resp), 79, 1) #define SD_CSD_WRITE_BLK_MISALIGN(resp) MMC_RSP_BITS((resp), 78, 1) #define SD_CSD_READ_BLK_MISALIGN(resp) MMC_RSP_BITS((resp), 77, 1) #define SD_CSD_DSR_IMP(resp) MMC_RSP_BITS((resp), 76, 1) #define SD_CSD_C_SIZE(resp) MMC_RSP_BITS((resp), 62, 12) #define SD_CSD_CAPACITY(resp) ((SD_CSD_C_SIZE((resp))+1) << \ (SD_CSD_C_SIZE_MULT((resp))+2)) #define SD_CSD_V2_C_SIZE(resp) MMC_RSP_BITS((resp), 48, 22) #define SD_CSD_V2_CAPACITY(resp) ((SD_CSD_V2_C_SIZE((resp))+1) << 10) #define SD_CSD_V2_BL_LEN 0x9 /* 512 */ #define SD_CSD_VDD_R_CURR_MIN(resp) MMC_RSP_BITS((resp), 59, 3) #define SD_CSD_VDD_R_CURR_MAX(resp) MMC_RSP_BITS((resp), 56, 3) #define SD_CSD_VDD_W_CURR_MIN(resp) MMC_RSP_BITS((resp), 53, 3) #define SD_CSD_VDD_W_CURR_MAX(resp) MMC_RSP_BITS((resp), 50, 3) #define SD_CSD_VDD_RW_CURR_100mA 0x7 #define SD_CSD_VDD_RW_CURR_80mA 0x6 #define SD_CSD_C_SIZE_MULT(resp) MMC_RSP_BITS((resp), 47, 3) #define SD_CSD_ERASE_BLK_EN(resp) MMC_RSP_BITS((resp), 46, 1) #define SD_CSD_SECTOR_SIZE(resp) MMC_RSP_BITS((resp), 39, 7) /* +1 */ #define SD_CSD_WP_GRP_SIZE(resp) MMC_RSP_BITS((resp), 32, 7) /* +1 */ #define SD_CSD_WP_GRP_ENABLE(resp) MMC_RSP_BITS((resp), 31, 1) #define SD_CSD_R2W_FACTOR(resp) MMC_RSP_BITS((resp), 26, 3) #define SD_CSD_WRITE_BL_LEN(resp) MMC_RSP_BITS((resp), 22, 4) #define SD_CSD_RW_BL_LEN_2G 0xa #define SD_CSD_RW_BL_LEN_1G 0x9 #define SD_CSD_WRITE_BL_PARTIAL(resp) MMC_RSP_BITS((resp), 21, 1) #define SD_CSD_FILE_FORMAT_GRP(resp) MMC_RSP_BITS((resp), 15, 1) #define SD_CSD_COPY(resp) MMC_RSP_BITS((resp), 14, 1) #define SD_CSD_PERM_WRITE_PROTECT(resp) MMC_RSP_BITS((resp), 13, 1) #define SD_CSD_TMP_WRITE_PROTECT(resp) MMC_RSP_BITS((resp), 12, 1) #define SD_CSD_FILE_FORMAT(resp) MMC_RSP_BITS((resp), 10, 2) /* SD R2 response (CID) */ #define SD_CID_MID(resp) MMC_RSP_BITS((resp), 120, 8) #define SD_CID_OID(resp) MMC_RSP_BITS((resp), 104, 16) #define SD_CID_PNM_CPY(resp, pnm) \ do { \ (pnm)[0] = MMC_RSP_BITS((resp), 96, 8); \ (pnm)[1] = MMC_RSP_BITS((resp), 88, 8); \ (pnm)[2] = MMC_RSP_BITS((resp), 80, 8); \ (pnm)[3] = MMC_RSP_BITS((resp), 72, 8); \ (pnm)[4] = MMC_RSP_BITS((resp), 64, 8); \ (pnm)[5] = '\0'; \ } while (0) #define SD_CID_REV(resp) MMC_RSP_BITS((resp), 56, 8) #define SD_CID_PSN(resp) MMC_RSP_BITS((resp), 24, 32) #define SD_CID_MDT(resp) MMC_RSP_BITS((resp), 8, 12) /* Might be slow, but it should work on big and little endian systems. */ #define MMC_RSP_BITS(resp, start, len) __bitfield((resp), (start)-8, (len)) static __inline int __bitfield(u_int32_t *src, int start, int len) { u_int8_t *sp; u_int32_t dst, mask; int shift, bs, bc; if (start < 0 || len < 0 || len > 32) return 0; dst = 0; mask = len % 32 ? UINT_MAX >> (32 - (len % 32)) : UINT_MAX; shift = 0; while (len > 0) { sp = (u_int8_t *)src + start / 8; bs = start % 8; bc = 8 - bs; if (bc > len) bc = len; dst |= (*sp++ >> bs) << shift; shift += bc; start += bc; len -= bc; } dst &= mask; return (int)dst; } #endif