/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2021 Aidan MacDonald * * 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 "system.h" #include "panic.h" #include "msc-x1000.h" #include "gpio-x1000.h" #include "irq-x1000.h" #include "clk-x1000.h" #include "x1000/msc.h" #include "x1000/cpm.h" #include #include /* #define LOGF_ENABLE */ #include "logf.h" /* TODO - this needs some auditing to better handle errors * * There should be a clearer code path involving errors. Especially we should * ensure that removing the card always resets the driver to a sane state. */ static const msc_config msc_configs[] = { #ifdef FIIO_M3K #define MSC_CLOCK_SOURCE X1000_CLK_SCLK_A #define msc0_cd_interrupt GPIOB06 { .msc_nr = 0, .msc_type = MSC_TYPE_SD, .bus_width = 4, .label = "microSD", .cd_gpio = GPIO_MSC0_CD, .cd_active_level = 0, }, #else # error "Please add X1000 MSC config" #endif {.msc_nr = -1}, }; static const msc_config* msc_lookup_config(int msc) { for(int i = 0; i < MSC_COUNT; ++i) if(msc_configs[i].msc_nr == msc) return &msc_configs[i]; return NULL; } static msc_drv msc_drivers[MSC_COUNT]; /* --------------------------------------------------------------------------- * Initialization */ static void msc_gate_clock(int msc, bool gate) { int bit; if(msc == 0) bit = BM_CPM_CLKGR_MSC0; else bit = BM_CPM_CLKGR_MSC1; if(gate) REG_CPM_CLKGR |= bit; else REG_CPM_CLKGR &= ~bit; } static void msc_init_one(msc_drv* d, int msc) { /* Lookup config */ d->drive_nr = -1; d->config = msc_lookup_config(msc); if(!d->config) { d->msc_nr = -1; return; } /* Initialize driver state */ d->msc_nr = msc; d->driver_flags = 0; d->clk_status = 0; d->cmdat_def = jz_orf(MSC_CMDAT, RTRG_V(GE32), TTRG_V(LE32)); d->req = NULL; d->iflag_done = 0; d->card_present = 1; d->req_running = 0; mutex_init(&d->lock); semaphore_init(&d->cmd_done, 1, 0); /* Ensure correct clock source */ jz_writef(CPM_MSC0CDR, CE(1), CLKDIV(0), CLKSRC(MSC_CLOCK_SOURCE == X1000_CLK_MPLL ? 1 : 0)); while(jz_readf(CPM_MSC0CDR, BUSY)); jz_writef(CPM_MSC0CDR, CE(0)); /* Initialize the hardware */ msc_gate_clock(msc, false); msc_full_reset(d); system_enable_irq(msc == 0 ? IRQ_MSC0 : IRQ_MSC1); /* Setup the card detect IRQ */ if(d->config->cd_gpio != GPIO_NONE) { if(gpio_get_level(d->config->cd_gpio) != d->config->cd_active_level) d->card_present = 0; gpio_set_function(d->config->cd_gpio, GPIOF_IRQ_EDGE(1)); gpio_flip_edge_irq(d->config->cd_gpio); gpio_enable_irq(d->config->cd_gpio); } } void msc_init(void) { /* Only do this once -- each storage subsystem calls us in its init */ static bool done = false; if(done) return; done = true; /* Set up each MSC driver according to msc_configs */ for(int i = 0; i < MSC_COUNT; ++i) msc_init_one(&msc_drivers[i], i); } msc_drv* msc_get(int type, int index) { for(int i = 0, m = 0; i < MSC_COUNT; ++i) { if(msc_drivers[i].config == NULL) continue; if(type == MSC_TYPE_ANY || msc_drivers[i].config->msc_type == type) if(index == m++) return &msc_drivers[i]; } return NULL; } msc_drv* msc_get_by_drive(int drive_nr) { for(int i = 0; i < MSC_COUNT; ++i) if(msc_drivers[i].drive_nr == drive_nr) return &msc_drivers[i]; return NULL; } void msc_lock(msc_drv* d) { mutex_lock(&d->lock); } void msc_unlock(msc_drv* d) { mutex_unlock(&d->lock); } void msc_full_reset(msc_drv* d) { msc_lock(d); msc_set_clock_mode(d, MSC_CLK_AUTOMATIC); msc_set_speed(d, MSC_SPEED_INIT); msc_set_width(d, 1); msc_ctl_reset(d); d->driver_flags = 0; memset(&d->cardinfo, 0, sizeof(tCardInfo)); msc_unlock(d); } bool msc_card_detect(msc_drv* d) { if(d->config->cd_gpio == GPIO_NONE) return true; return gpio_get_level(d->config->cd_gpio) == d->config->cd_active_level; } /* --------------------------------------------------------------------------- * Controller API */ void msc_ctl_reset(msc_drv* d) { /* Ingenic code suggests a reset changes clkrt */ int clkrt = REG_MSC_CLKRT(d->msc_nr); /* Send reset -- bit is NOT self clearing */ jz_overwritef(MSC_CTRL(d->msc_nr), RESET(1)); udelay(100); jz_writef(MSC_CTRL(d->msc_nr), RESET(0)); /* Verify reset in the status register */ long deadline = current_tick + HZ; while(jz_readf(MSC_STAT(d->msc_nr), IS_RESETTING) && current_tick < deadline) { sleep(1); } /* Ensure the clock state is as expected */ if(d->clk_status & MSC_CLKST_AUTO) jz_writef(MSC_LPM(d->msc_nr), ENABLE(1)); else if(d->clk_status & MSC_CLKST_ENABLE) jz_overwritef(MSC_CTRL(d->msc_nr), CLOCK_V(START)); else jz_overwritef(MSC_CTRL(d->msc_nr), CLOCK_V(STOP)); /* Clear and mask interrupts */ REG_MSC_IMASK(d->msc_nr) = 0xffffffff; REG_MSC_IFLAG(d->msc_nr) = 0xffffffff; /* Restore clkrt */ REG_MSC_CLKRT(d->msc_nr) = clkrt; } void msc_set_clock_mode(msc_drv* d, int mode) { int cur_mode = (d->clk_status & MSC_CLKST_AUTO) ? MSC_CLK_AUTOMATIC : MSC_CLK_MANUAL; if(mode == cur_mode) return; d->clk_status &= ~MSC_CLKST_ENABLE; if(mode == MSC_CLK_AUTOMATIC) { d->clk_status |= MSC_CLKST_AUTO; jz_writef(MSC_CTRL(d->msc_nr), CLOCK_V(STOP)); jz_writef(MSC_LPM(d->msc_nr), ENABLE(1)); } else { d->clk_status &= ~MSC_CLKST_AUTO; jz_writef(MSC_LPM(d->msc_nr), ENABLE(0)); jz_writef(MSC_CTRL(d->msc_nr), CLOCK_V(STOP)); } } void msc_enable_clock(msc_drv* d, bool enable) { if(d->clk_status & MSC_CLKST_AUTO) return; bool is_enabled = (d->clk_status & MSC_CLKST_ENABLE); if(enable == is_enabled) return; if(enable) { jz_writef(MSC_CTRL(d->msc_nr), CLOCK_V(START)); d->clk_status |= MSC_CLKST_ENABLE; } else { jz_writef(MSC_CTRL(d->msc_nr), CLOCK_V(STOP)); d->clk_status &= ~MSC_CLKST_ENABLE; } } void msc_set_speed(msc_drv* d, int rate) { /* Shut down clock while we change frequencies */ if(d->clk_status & MSC_CLKST_ENABLE) jz_writef(MSC_CTRL(d->msc_nr), CLOCK_V(STOP)); /* Wait for clock to go idle */ while(jz_readf(MSC_STAT(d->msc_nr), CLOCK_EN)) sleep(1); /* freq1 is output by MSCxDIV; freq2 is output by MSC_CLKRT */ uint32_t freq1 = rate; uint32_t freq2 = rate; if(freq1 < MSC_SPEED_FAST) freq1 = MSC_SPEED_FAST; /* Handle MSCxDIV */ uint32_t src_freq = clk_get(MSC_CLOCK_SOURCE) / 2; uint32_t div = clk_calc_div(src_freq, freq1); if(d->msc_nr == 0) { jz_writef(CPM_MSC0CDR, CE(1), CLKDIV(div - 1)); while(jz_readf(CPM_MSC0CDR, BUSY)); jz_writef(CPM_MSC0CDR, CE(0)); } else { jz_writef(CPM_MSC1CDR, CE(1), CLKDIV(div - 1)); while(jz_readf(CPM_MSC1CDR, BUSY)); jz_writef(CPM_MSC1CDR, CE(0)); } /* Handle MSC_CLKRT */ uint32_t clkrt = clk_calc_shift(src_freq/div, freq2); REG_MSC_CLKRT(d->msc_nr) = clkrt; /* Handle frequency dependent timing settings * TODO - these settings might be SD specific... */ uint32_t out_freq = (src_freq/div) >> clkrt; if(out_freq > MSC_SPEED_FAST) { jz_writef(MSC_LPM(d->msc_nr), DRV_SEL_V(RISE_EDGE_DELAY_QTR_PHASE), SMP_SEL_V(RISE_EDGE_DELAYED)); jz_writef(MSC_CTRL2(d->msc_nr), SPEED_V(HIGHSPEED)); } else { jz_writef(MSC_LPM(d->msc_nr), DRV_SEL_V(FALL_EDGE), SMP_SEL_V(RISE_EDGE)); jz_writef(MSC_CTRL2(d->msc_nr), SPEED_V(DEFAULT)); } /* Restart clock if it was running before */ if(d->clk_status & MSC_CLKST_ENABLE) jz_writef(MSC_CTRL(d->msc_nr), CLOCK_V(START)); } void msc_set_width(msc_drv* d, int width) { /* Bus width is controlled per command with MSC_CMDAT. */ if(width == 8) jz_vwritef(d->cmdat_def, MSC_CMDAT, BUS_WIDTH_V(8BIT)); else if(width == 4) jz_vwritef(d->cmdat_def, MSC_CMDAT, BUS_WIDTH_V(4BIT)); else jz_vwritef(d->cmdat_def, MSC_CMDAT, BUS_WIDTH_V(1BIT)); } /* --------------------------------------------------------------------------- * Request API */ /* Note -- this must only be called with IRQs disabled */ static void msc_finish_request(msc_drv* d, int status) { REG_MSC_IMASK(d->msc_nr) = 0xffffffff; REG_MSC_IFLAG(d->msc_nr) = 0xffffffff; if(d->req->flags & MSC_RF_DATA) jz_writef(MSC_DMAC(d->msc_nr), ENABLE(0)); d->req->status = status; d->req_running = 0; d->iflag_done = 0; timeout_cancel(&d->cmd_tmo); semaphore_release(&d->cmd_done); } static int msc_req_timeout(struct timeout* tmo) { msc_drv* d = (msc_drv*)tmo->data; msc_async_abort(d, MSC_REQ_LOCKUP); return 0; } void msc_async_start(msc_drv* d, msc_req* r) { /* Determined needed cmdat and interrupts */ unsigned cmdat = d->cmdat_def; d->iflag_done = jz_orm(MSC_IFLAG, END_CMD_RES); cmdat |= jz_orf(MSC_CMDAT, RESP_FMT(r->resptype & ~MSC_RESP_BUSY)); if(r->resptype & MSC_RESP_BUSY) cmdat |= jz_orm(MSC_CMDAT, BUSY); if(r->flags & MSC_RF_INIT) cmdat |= jz_orm(MSC_CMDAT, INIT); if(r->flags & MSC_RF_DATA) { cmdat |= jz_orm(MSC_CMDAT, DATA_EN); if(r->flags & MSC_RF_PROG) d->iflag_done = jz_orm(MSC_IFLAG, WR_ALL_DONE); else d->iflag_done = jz_orm(MSC_IFLAG, DMA_DATA_DONE); } if(r->flags & MSC_RF_WRITE) cmdat |= jz_orm(MSC_CMDAT, WRITE_READ); if(r->flags & MSC_RF_AUTO_CMD12) cmdat |= jz_orm(MSC_CMDAT, AUTO_CMD12); if(r->flags & MSC_RF_ABORT) cmdat |= jz_orm(MSC_CMDAT, IO_ABORT); unsigned imask = jz_orm(MSC_IMASK, CRC_RES_ERROR, CRC_READ_ERROR, CRC_WRITE_ERROR, TIME_OUT_RES, TIME_OUT_READ, END_CMD_RES); imask |= d->iflag_done; /* Program the controller */ if(r->flags & MSC_RF_DATA) { REG_MSC_NOB(d->msc_nr) = r->nr_blocks; REG_MSC_BLKLEN(d->msc_nr) = r->block_len; } REG_MSC_CMD(d->msc_nr) = r->command; REG_MSC_ARG(d->msc_nr) = r->argument; REG_MSC_CMDAT(d->msc_nr) = cmdat; REG_MSC_IFLAG(d->msc_nr) = imask; REG_MSC_IMASK(d->msc_nr) &= ~imask; if(r->flags & MSC_RF_DATA) { d->dma_desc.nda = 0; d->dma_desc.mem = PHYSADDR(r->data); d->dma_desc.len = r->nr_blocks * r->block_len; d->dma_desc.cmd = 2; /* ID=0, ENDI=1, LINK=0 */ commit_dcache_range(&d->dma_desc, sizeof(d->dma_desc)); if(r->flags & MSC_RF_WRITE) commit_dcache_range(r->data, d->dma_desc.len); else discard_dcache_range(r->data, d->dma_desc.len); /* Unaligned address for DMA doesn't seem to work correctly. * FAT FS driver should ensure proper alignment of all buffers, * so in practice this panic should not occur, but if it does * I want to hear about it. */ if(UNLIKELY(d->dma_desc.mem & 3)) { panicf("msc%d bad align: %08x", d->msc_nr, (unsigned)d->dma_desc.mem); } jz_writef(MSC_DMAC(d->msc_nr), MODE_SEL(0), INCR(0), DMASEL(0)); REG_MSC_DMANDA(d->msc_nr) = PHYSADDR(&d->dma_desc); } /* Begin processing */ d->req = r; d->req_running = 1; jz_writef(MSC_CTRL(d->msc_nr), START_OP(1)); if(r->flags & MSC_RF_DATA) jz_writef(MSC_DMAC(d->msc_nr), ENABLE(1)); /* TODO: calculate a suitable lower value for the lockup timeout. * * The SD spec defines timings based on the number of blocks transferred, * see sec. 4.6.2 "Read, write, and erase timeout conditions". This should * reduce the long delays which happen if errors occur. * * Also need to check if registers MSC_RDTO / MSC_RESTO are correctly set. */ timeout_register(&d->cmd_tmo, msc_req_timeout, 10*HZ, (intptr_t)d); } void msc_async_abort(msc_drv* d, int status) { int irq = disable_irq_save(); if(d->req_running) { logf("msc%d: async abort status:%d", d->msc_nr, status); msc_finish_request(d, status); } restore_irq(irq); } int msc_async_wait(msc_drv* d, int timeout) { if(semaphore_wait(&d->cmd_done, timeout) == OBJ_WAIT_TIMEDOUT) return MSC_REQ_INCOMPLETE; return d->req->status; } int msc_request(msc_drv* d, msc_req* r) { msc_async_start(d, r); return msc_async_wait(d, TIMEOUT_BLOCK); } /* --------------------------------------------------------------------------- * Command response handling */ static void msc_read_response(msc_drv* d) { unsigned res = REG_MSC_RES(d->msc_nr); unsigned dat; switch(d->req->resptype) { case MSC_RESP_R1: case MSC_RESP_R1B: case MSC_RESP_R3: case MSC_RESP_R6: case MSC_RESP_R7: dat = res << 24; res = REG_MSC_RES(d->msc_nr); dat |= res << 8; res = REG_MSC_RES(d->msc_nr); dat |= res & 0xff; d->req->response[0] = dat; break; case MSC_RESP_R2: for(int i = 0; i < 4; ++i) { dat = res << 24; res = REG_MSC_RES(d->msc_nr); dat |= res << 8; res = REG_MSC_RES(d->msc_nr); dat |= res >> 8; d->req->response[i] = dat; } break; default: return; } } static int msc_check_sd_response(msc_drv* d) { if(d->req->resptype == MSC_RESP_R1 || d->req->resptype == MSC_RESP_R1B) { if(d->req->response[0] & SD_R1_CARD_ERROR) { logf("msc%d: R1 card error: %08x", d->msc_nr, d->req->response[0]); return MSC_REQ_CARD_ERR; } } return MSC_REQ_SUCCESS; } static int msc_check_response(msc_drv* d) { switch(d->config->msc_type) { case MSC_TYPE_SD: return msc_check_sd_response(d); default: /* TODO - implement msc_check_response for MMC and CE-ATA */ return 0; } } /* --------------------------------------------------------------------------- * Interrupt handlers */ static void msc_interrupt(msc_drv* d) { const unsigned tmo_bits = jz_orm(MSC_IFLAG, TIME_OUT_READ, TIME_OUT_RES); const unsigned crc_bits = jz_orm(MSC_IFLAG, CRC_RES_ERROR, CRC_READ_ERROR, CRC_WRITE_ERROR); const unsigned err_bits = tmo_bits | crc_bits; unsigned iflag = REG_MSC_IFLAG(d->msc_nr) & ~REG_MSC_IMASK(d->msc_nr); bool handled = false; /* In case card was removed */ if(!msc_card_detect(d)) { msc_finish_request(d, MSC_REQ_EXTRACTED); return; } /* Check for errors */ if(iflag & err_bits) { int st; if(iflag & crc_bits) st = MSC_REQ_CRC_ERR; else if(iflag & tmo_bits) st = MSC_REQ_TIMEOUT; else st = MSC_REQ_ERROR; msc_finish_request(d, st); return; } /* Read and check the command response */ if(iflag & BM_MSC_IFLAG_END_CMD_RES) { msc_read_response(d); int st = msc_check_response(d); if(st == MSC_REQ_SUCCESS) { jz_writef(MSC_IMASK(d->msc_nr), END_CMD_RES(1)); jz_overwritef(MSC_IFLAG(d->msc_nr), END_CMD_RES(1)); handled = true; } else { msc_finish_request(d, st); return; } } /* Check if the "done" interrupt is signaled */ if(iflag & d->iflag_done) { /* Discard after DMA in case of hardware cache prefetching. * Only needed for read operations. */ if((d->req->flags & MSC_RF_DATA) != 0 && (d->req->flags & MSC_RF_WRITE) == 0) { discard_dcache_range(d->req->data, d->req->block_len * d->req->nr_blocks); } msc_finish_request(d, MSC_REQ_SUCCESS); return; } if(!handled) { panicf("msc%d: irq bug! iflag:%08x raw_iflag:%08lx imask:%08lx", d->msc_nr, iflag, REG_MSC_IFLAG(d->msc_nr), REG_MSC_IMASK(d->msc_nr)); } } static int msc_cd_callback(struct timeout* tmo) { msc_drv* d = (msc_drv*)tmo->data; /* If card is still present we assume the card is properly inserted */ if(msc_card_detect(d)) { d->card_present = 1; queue_broadcast(SYS_HOTSWAP_INSERTED, d->drive_nr); } return 0; } static void msc_cd_interrupt(msc_drv* d) { if(!msc_card_detect(d)) { /* Immediately abort and notify when removing a card */ msc_async_abort(d, MSC_REQ_EXTRACTED); if(d->card_present) { d->card_present = 0; queue_broadcast(SYS_HOTSWAP_EXTRACTED, d->drive_nr); } } else { /* Timer to debounce input */ timeout_register(&d->cd_tmo, msc_cd_callback, HZ/4, (intptr_t)d); } /* Invert the IRQ */ gpio_flip_edge_irq(d->config->cd_gpio); } void MSC0(void) { msc_interrupt(&msc_drivers[0]); } void MSC1(void) { msc_interrupt(&msc_drivers[1]); } #ifdef msc0_cd_interrupt void msc0_cd_interrupt(void) { msc_cd_interrupt(&msc_drivers[0]); } #endif #ifdef msc1_cd_interrupt void msc1_cd_interrupt(void) { msc_cd_interrupt(&msc_drivers[1]); } #endif /* --------------------------------------------------------------------------- * SD command helpers */ int msc_cmd_exec(msc_drv* d, msc_req* r) { int status = msc_request(d, r); if(status == MSC_REQ_SUCCESS) return status; else if(status == MSC_REQ_LOCKUP || status == MSC_REQ_EXTRACTED) d->driver_flags |= MSC_DF_ERRSTATE; else if(r->flags & (MSC_RF_ERR_CMD12|MSC_RF_AUTO_CMD12)) { /* After an error, the controller does not automatically issue CMD12, * so we need to send it if it's needed, as required by the SD spec. */ msc_req nreq = {0}; nreq.command = SD_STOP_TRANSMISSION; nreq.resptype = MSC_RESP_R1B; nreq.flags = MSC_RF_ABORT; logf("msc%d: cmd%d error, sending cmd12", d->msc_nr, r->command); if(msc_cmd_exec(d, &nreq)) d->driver_flags |= MSC_DF_ERRSTATE; } logf("msc%d: err:%d, cmd%d, arg:%x", d->msc_nr, status, r->command, r->argument); return status; } int msc_app_cmd_exec(msc_drv* d, msc_req* r) { msc_req areq = {0}; areq.command = SD_APP_CMD; areq.argument = d->cardinfo.rca; areq.resptype = MSC_RESP_R1; if(msc_cmd_exec(d, &areq)) return areq.status; /* Verify that CMD55 was accepted */ if((areq.response[0] & (1 << 5)) == 0) return MSC_REQ_ERROR; return msc_cmd_exec(d, r); } int msc_cmd_go_idle_state(msc_drv* d) { msc_req req = {0}; req.command = SD_GO_IDLE_STATE; req.resptype = MSC_RESP_NONE; req.flags = MSC_RF_INIT; return msc_cmd_exec(d, &req); } int msc_cmd_send_if_cond(msc_drv* d) { msc_req req = {0}; req.command = SD_SEND_IF_COND; req.argument = 0x1aa; req.resptype = MSC_RESP_R7; /* TODO - Check if SEND_IF_COND timeout is really an error * IIRC, this can occur if the card isn't HCS (old cards < 2 GiB). */ if(msc_cmd_exec(d, &req)) return req.status; /* Set HCS bit if the card responds correctly */ if((req.response[0] & 0xff) == 0xaa) d->driver_flags |= MSC_DF_HCS_CARD; return MSC_REQ_SUCCESS; } int msc_cmd_app_op_cond(msc_drv* d) { msc_req req = {0}; req.command = SD_APP_OP_COND; req.argument = 0x00300000; /* 3.4 - 3.6 V */ req.resptype = MSC_RESP_R3; if(d->driver_flags & MSC_DF_HCS_CARD) req.argument |= (1 << 30); int timeout = 2 * HZ; do { if(msc_app_cmd_exec(d, &req)) return req.status; if(req.response[0] & (1 << 31)) break; sleep(1); } while(--timeout > 0); if(timeout == 0) return MSC_REQ_TIMEOUT; return MSC_REQ_SUCCESS; } int msc_cmd_all_send_cid(msc_drv* d) { msc_req req = {0}; req.command = SD_ALL_SEND_CID; req.resptype = MSC_RESP_R2; if(msc_cmd_exec(d, &req)) return req.status; for(int i = 0; i < 4; ++i) d->cardinfo.cid[i] = req.response[i]; return MSC_REQ_SUCCESS; } int msc_cmd_send_rca(msc_drv* d) { msc_req req = {0}; req.command = SD_SEND_RELATIVE_ADDR; req.resptype = MSC_RESP_R6; if(msc_cmd_exec(d, &req)) return req.status; d->cardinfo.rca = req.response[0] & 0xffff0000; return MSC_REQ_SUCCESS; } int msc_cmd_send_csd(msc_drv* d) { msc_req req = {0}; req.command = SD_SEND_CSD; req.argument = d->cardinfo.rca; req.resptype = MSC_RESP_R2; if(msc_cmd_exec(d, &req)) return req.status; for(int i = 0; i < 4; ++i) d->cardinfo.csd[i] = req.response[i]; sd_parse_csd(&d->cardinfo); if((req.response[0] >> 30) == 1) d->driver_flags |= MSC_DF_V2_CARD; return 0; } int msc_cmd_select_card(msc_drv* d) { msc_req req = {0}; req.command = SD_SELECT_CARD; req.argument = d->cardinfo.rca; req.resptype = MSC_RESP_R1B; return msc_cmd_exec(d, &req); } int msc_cmd_set_bus_width(msc_drv* d, int width) { /* TODO - must we check bus width is supported in the cardinfo? */ msc_req req = {0}; req.command = SD_SET_BUS_WIDTH; req.resptype = MSC_RESP_R1; switch(width) { case 1: req.argument = 0; break; case 4: req.argument = 2; break; default: return MSC_REQ_ERROR; } if(msc_app_cmd_exec(d, &req)) return req.status; msc_set_width(d, width); return MSC_REQ_SUCCESS; } int msc_cmd_set_clr_card_detect(msc_drv* d, int arg) { msc_req req = {0}; req.command = SD_SET_CLR_CARD_DETECT; req.argument = arg; req.resptype = MSC_RESP_R1; return msc_app_cmd_exec(d, &req); } int msc_cmd_switch_freq(msc_drv* d) { /* If card doesn't support High Speed, we don't need to send a command */ if((d->driver_flags & MSC_DF_V2_CARD) == 0) { msc_set_speed(d, MSC_SPEED_FAST); return MSC_REQ_SUCCESS; } /* Try switching to High Speed (50 MHz) */ char buffer[64] CACHEALIGN_ATTR; msc_req req = {0}; req.command = SD_SWITCH_FUNC; req.argument = 0x80fffff1; req.resptype = MSC_RESP_R1; req.flags = MSC_RF_DATA; req.data = &buffer[0]; req.block_len = 64; req.nr_blocks = 1; if(msc_cmd_exec(d, &req)) return req.status; msc_set_speed(d, MSC_SPEED_HIGH); return MSC_REQ_SUCCESS; } int msc_cmd_send_status(msc_drv* d) { msc_req req = {0}; req.command = SD_SEND_STATUS; req.argument = d->cardinfo.rca; req.resptype = MSC_RESP_R1; return msc_cmd_exec(d, &req); } int msc_cmd_set_block_len(msc_drv* d, unsigned len) { msc_req req = {0}; req.command = SD_SET_BLOCKLEN; req.argument = len; req.resptype = MSC_RESP_R1; return msc_cmd_exec(d, &req); }