/* * tifm_sd.c - TI FlashMedia driver * * Copyright (C) 2006 Alex Dubov * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * */ #include #include #include #include #define DRIVER_NAME "tifm_sd" #define DRIVER_VERSION "0.6" static int no_dma = 0; static int fixed_timeout = 0; module_param(no_dma, bool, 0644); module_param(fixed_timeout, bool, 0644); /* Constants here are mostly from OMAP5912 datasheet */ #define TIFM_MMCSD_RESET 0x0002 #define TIFM_MMCSD_CLKMASK 0x03ff #define TIFM_MMCSD_POWER 0x0800 #define TIFM_MMCSD_4BBUS 0x8000 #define TIFM_MMCSD_RXDE 0x8000 /* rx dma enable */ #define TIFM_MMCSD_TXDE 0x0080 /* tx dma enable */ #define TIFM_MMCSD_BUFINT 0x0c00 /* set bits: AE, AF */ #define TIFM_MMCSD_DPE 0x0020 /* data timeout counted in kilocycles */ #define TIFM_MMCSD_INAB 0x0080 /* abort / initialize command */ #define TIFM_MMCSD_READ 0x8000 #define TIFM_MMCSD_DATAMASK 0x001d /* set bits: EOFB, BRS, CB, EOC */ #define TIFM_MMCSD_ERRMASK 0x41e0 /* set bits: CERR, CCRC, CTO, DCRC, DTO */ #define TIFM_MMCSD_EOC 0x0001 /* end of command phase */ #define TIFM_MMCSD_CB 0x0004 /* card enter busy state */ #define TIFM_MMCSD_BRS 0x0008 /* block received/sent */ #define TIFM_MMCSD_EOFB 0x0010 /* card exit busy state */ #define TIFM_MMCSD_DTO 0x0020 /* data time-out */ #define TIFM_MMCSD_DCRC 0x0040 /* data crc error */ #define TIFM_MMCSD_CTO 0x0080 /* command time-out */ #define TIFM_MMCSD_CCRC 0x0100 /* command crc error */ #define TIFM_MMCSD_AF 0x0400 /* fifo almost full */ #define TIFM_MMCSD_AE 0x0800 /* fifo almost empty */ #define TIFM_MMCSD_CERR 0x4000 /* card status error */ #define TIFM_MMCSD_FIFO_SIZE 0x0020 #define TIFM_MMCSD_RSP_R0 0x0000 #define TIFM_MMCSD_RSP_R1 0x0100 #define TIFM_MMCSD_RSP_R2 0x0200 #define TIFM_MMCSD_RSP_R3 0x0300 #define TIFM_MMCSD_RSP_R4 0x0400 #define TIFM_MMCSD_RSP_R5 0x0500 #define TIFM_MMCSD_RSP_R6 0x0600 #define TIFM_MMCSD_RSP_BUSY 0x0800 #define TIFM_MMCSD_CMD_BC 0x0000 #define TIFM_MMCSD_CMD_BCR 0x1000 #define TIFM_MMCSD_CMD_AC 0x2000 #define TIFM_MMCSD_CMD_ADTC 0x3000 typedef enum { IDLE = 0, CMD, /* main command ended */ BRS, /* block transfer finished */ SCMD, /* stop command ended */ CARD, /* card left busy state */ FIFO, /* FIFO operation completed (uncertain) */ READY } card_state_t; enum { FIFO_RDY = 0x0001, /* hardware dependent value */ HOST_REG = 0x0002, EJECT = 0x0004, EJECT_DONE = 0x0008, CARD_BUSY = 0x0010, OPENDRAIN = 0x0040, /* hardware dependent value */ CARD_EVENT = 0x0100, /* hardware dependent value */ CARD_RO = 0x0200, /* hardware dependent value */ FIFO_EVENT = 0x10000 }; /* hardware dependent value */ struct tifm_sd { struct tifm_dev *dev; unsigned int flags; card_state_t state; unsigned int clk_freq; unsigned int clk_div; unsigned long timeout_jiffies; // software timeout - 2 sec struct mmc_request *req; struct work_struct cmd_handler; struct work_struct abort_handler; wait_queue_head_t can_eject; size_t written_blocks; char *buffer; size_t buffer_size; size_t buffer_pos; }; static int tifm_sd_transfer_data(struct tifm_dev *sock, struct tifm_sd *host, unsigned int host_status) { struct mmc_command *cmd = host->req->cmd; unsigned int t_val = 0, cnt = 0; if (host_status & TIFM_MMCSD_BRS) { /* in non-dma rx mode BRS fires when fifo is still not empty */ if (host->buffer && (cmd->data->flags & MMC_DATA_READ)) { while (host->buffer_size > host->buffer_pos) { t_val = readl(sock->addr + SOCK_MMCSD_DATA); host->buffer[host->buffer_pos++] = t_val & 0xff; host->buffer[host->buffer_pos++] = (t_val >> 8) & 0xff; } } return 1; } else if (host->buffer) { if ((cmd->data->flags & MMC_DATA_READ) && (host_status & TIFM_MMCSD_AF)) { for (cnt = 0; cnt < TIFM_MMCSD_FIFO_SIZE; cnt++) { t_val = readl(sock->addr + SOCK_MMCSD_DATA); if (host->buffer_size > host->buffer_pos) { host->buffer[host->buffer_pos++] = t_val & 0xff; host->buffer[host->buffer_pos++] = (t_val >> 8) & 0xff; } } } else if ((cmd->data->flags & MMC_DATA_WRITE) && (host_status & TIFM_MMCSD_AE)) { for (cnt = 0; cnt < TIFM_MMCSD_FIFO_SIZE; cnt++) { if (host->buffer_size > host->buffer_pos) { t_val = host->buffer[host->buffer_pos++] & 0x00ff; t_val |= ((host->buffer[host->buffer_pos++]) << 8) & 0xff00; writel(t_val, sock->addr + SOCK_MMCSD_DATA); } } } } return 0; } static unsigned int tifm_sd_op_flags(struct mmc_command *cmd) { unsigned int rc = 0; switch (mmc_resp_type(cmd)) { case MMC_RSP_NONE: rc |= TIFM_MMCSD_RSP_R0; break; case MMC_RSP_R1B: rc |= TIFM_MMCSD_RSP_BUSY; // deliberate fall-through case MMC_RSP_R1: rc |= TIFM_MMCSD_RSP_R1; break; case MMC_RSP_R2: rc |= TIFM_MMCSD_RSP_R2; break; case MMC_RSP_R3: rc |= TIFM_MMCSD_RSP_R3; break; case MMC_RSP_R6: rc |= TIFM_MMCSD_RSP_R6; break; default: BUG(); } switch (mmc_cmd_type(cmd)) { case MMC_CMD_BC: rc |= TIFM_MMCSD_CMD_BC; break; case MMC_CMD_BCR: rc |= TIFM_MMCSD_CMD_BCR; break; case MMC_CMD_AC: rc |= TIFM_MMCSD_CMD_AC; break; case MMC_CMD_ADTC: rc |= TIFM_MMCSD_CMD_ADTC; break; default: BUG(); } return rc; } static void tifm_sd_exec(struct tifm_sd *host, struct mmc_command *cmd) { struct tifm_dev *sock = host->dev; unsigned int cmd_mask = tifm_sd_op_flags(cmd) | (host->flags & OPENDRAIN); if (cmd->data && (cmd->data->flags & MMC_DATA_READ)) cmd_mask |= TIFM_MMCSD_READ; dev_dbg(&sock->dev, "executing opcode 0x%x, arg: 0x%x, mask: 0x%x\n", cmd->opcode, cmd->arg, cmd_mask); writel((cmd->arg >> 16) & 0xffff, sock->addr + SOCK_MMCSD_ARG_HIGH); writel(cmd->arg & 0xffff, sock->addr + SOCK_MMCSD_ARG_LOW); writel(cmd->opcode | cmd_mask, sock->addr + SOCK_MMCSD_COMMAND); } static void tifm_sd_fetch_resp(struct mmc_command *cmd, struct tifm_dev *sock) { cmd->resp[0] = (readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x1c) << 16) | readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x18); cmd->resp[1] = (readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x14) << 16) | readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x10); cmd->resp[2] = (readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x0c) << 16) | readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x08); cmd->resp[3] = (readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x04) << 16) | readl(sock->addr + SOCK_MMCSD_RESPONSE + 0x00); } static void tifm_sd_process_cmd(struct tifm_dev *sock, struct tifm_sd *host, unsigned int host_status) { struct mmc_command *cmd = host->req->cmd; change_state: switch (host->state) { case IDLE: return; case CMD: if (host_status & TIFM_MMCSD_EOC) { tifm_sd_fetch_resp(cmd, sock); if (cmd->data) { host->state = BRS; } else host->state = READY; goto change_state; } break; case BRS: if (tifm_sd_transfer_data(sock, host, host_status)) { if (!host->req->stop) { if (cmd->data->flags & MMC_DATA_WRITE) { host->state = CARD; } else { host->state = host->buffer ? READY : FIFO; } goto change_state; } tifm_sd_exec(host, host->req->stop); host->state = SCMD; } break; case SCMD: if (host_status & TIFM_MMCSD_EOC) { tifm_sd_fetch_resp(host->req->stop, sock); if (cmd->error) { host->state = READY; } else if (cmd->data->flags & MMC_DATA_WRITE) { host->state = CARD; } else { host->state = host->buffer ? READY : FIFO; } goto change_state; } break; case CARD: if (!(host->flags & CARD_BUSY) && (host->written_blocks == cmd->data->blocks)) { host->state = host->buffer ? READY : FIFO; goto change_state; } break; case FIFO: if (host->flags & FIFO_RDY) { host->state = READY; host->flags &= ~FIFO_RDY; goto change_state; } break; case READY: queue_work(sock->wq, &host->cmd_handler); return; } queue_delayed_work(sock->wq, &host->abort_handler, host->timeout_jiffies); } /* Called from interrupt handler */ static unsigned int tifm_sd_signal_irq(struct tifm_dev *sock, unsigned int sock_irq_status) { struct tifm_sd *host; unsigned int host_status = 0, fifo_status = 0; int error_code = 0; spin_lock(&sock->lock); host = mmc_priv((struct mmc_host*)tifm_get_drvdata(sock)); cancel_delayed_work(&host->abort_handler); if (sock_irq_status & FIFO_EVENT) { fifo_status = readl(sock->addr + SOCK_DMA_FIFO_STATUS); writel(fifo_status, sock->addr + SOCK_DMA_FIFO_STATUS); host->flags |= fifo_status & FIFO_RDY; } if (sock_irq_status & CARD_EVENT) { host_status = readl(sock->addr + SOCK_MMCSD_STATUS); writel(host_status, sock->addr + SOCK_MMCSD_STATUS); if (!(host->flags & HOST_REG)) queue_work(sock->wq, &host->cmd_handler); if (!host->req) goto done; if (host_status & TIFM_MMCSD_ERRMASK) { if (host_status & TIFM_MMCSD_CERR) error_code = MMC_ERR_FAILED; else if (host_status & (TIFM_MMCSD_CTO | TIFM_MMCSD_DTO)) error_code = MMC_ERR_TIMEOUT; else if (host_status & (TIFM_MMCSD_CCRC | TIFM_MMCSD_DCRC)) error_code = MMC_ERR_BADCRC; writel(TIFM_FIFO_INT_SETALL, sock->addr + SOCK_DMA_FIFO_INT_ENABLE_CLEAR); writel(TIFM_DMA_RESET, sock->addr + SOCK_DMA_CONTROL); if (host->req->stop) { if (host->state == SCMD) { host->req->stop->error = error_code; } else if(host->state == BRS) { host->req->cmd->error = error_code; tifm_sd_exec(host, host->req->stop); queue_delayed_work(sock->wq, &host->abort_handler, host->timeout_jiffies); host->state = SCMD; goto done; } else { host->req->cmd->error = error_code; } } else { host->req->cmd->error = error_code; } host->state = READY; } if (host_status & TIFM_MMCSD_CB) host->flags |= CARD_BUSY; if ((host_status & TIFM_MMCSD_EOFB) && (host->flags & CARD_BUSY)) { host->written_blocks++; host->flags &= ~CARD_BUSY; } } if (host->req) tifm_sd_process_cmd(sock, host, host_status); done: dev_dbg(&sock->dev, "host_status %x, fifo_status %x\n", host_status, fifo_status); spin_unlock(&sock->lock); return sock_irq_status; } static void tifm_sd_prepare_data(struct tifm_sd *card, struct mmc_command *cmd) { struct tifm_dev *sock = card->dev; unsigned int dest_cnt; /* DMA style IO */ writel(TIFM_FIFO_INT_SETALL, sock->addr + SOCK_DMA_FIFO_INT_ENABLE_CLEAR); writel(long_log2(cmd->data->blksz) - 2, sock->addr + SOCK_FIFO_PAGE_SIZE); writel(TIFM_FIFO_ENABLE, sock->addr + SOCK_FIFO_CONTROL); writel(TIFM_FIFO_INTMASK, sock->addr + SOCK_DMA_FIFO_INT_ENABLE_SET); dest_cnt = (cmd->data->blocks) << 8; writel(sg_dma_address(cmd->data->sg), sock->addr + SOCK_DMA_ADDRESS); writel(cmd->data->blocks - 1, sock->addr + SOCK_MMCSD_NUM_BLOCKS); writel(cmd->data->blksz - 1, sock->addr + SOCK_MMCSD_BLOCK_LEN); if (cmd->data->flags & MMC_DATA_WRITE) { writel(TIFM_MMCSD_TXDE, sock->addr + SOCK_MMCSD_BUFFER_CONFIG); writel(dest_cnt | TIFM_DMA_TX | TIFM_DMA_EN, sock->addr + SOCK_DMA_CONTROL); } else { writel(TIFM_MMCSD_RXDE, sock->addr + SOCK_MMCSD_BUFFER_CONFIG); writel(dest_cnt | TIFM_DMA_EN, sock->addr + SOCK_DMA_CONTROL); } } static void tifm_sd_set_data_timeout(struct tifm_sd *host, struct mmc_data *data) { struct tifm_dev *sock = host->dev; unsigned int data_timeout = data->timeout_clks; if (fixed_timeout) return; data_timeout += data->timeout_ns / ((1000000000 / host->clk_freq) * host->clk_div); data_timeout *= 10; // call it fudge factor for now if (data_timeout < 0xffff) { writel((~TIFM_MMCSD_DPE) & readl(sock->addr + SOCK_MMCSD_SDIO_MODE_CONFIG), sock->addr + SOCK_MMCSD_SDIO_MODE_CONFIG); writel(data_timeout, sock->addr + SOCK_MMCSD_DATA_TO); } else { writel(TIFM_MMCSD_DPE | readl(sock->addr + SOCK_MMCSD_SDIO_MODE_CONFIG), sock->addr + SOCK_MMCSD_SDIO_MODE_CONFIG); data_timeout = (data_timeout >> 10) + 1; if(data_timeout > 0xffff) data_timeout = 0; /* set to unlimited */ writel(data_timeout, sock->addr + SOCK_MMCSD_DATA_TO); } } static void tifm_sd_request(struct mmc_host *mmc, struct mmc_request *mrq) { struct tifm_sd *host = mmc_priv(mmc); struct tifm_dev *sock = host->dev; unsigned long flags; int sg_count = 0; struct mmc_data *r_data = mrq->cmd->data; spin_lock_irqsave(&sock->lock, flags); if (host->flags & EJECT) { spin_unlock_irqrestore(&sock->lock, flags); goto err_out; } if (host->req) { printk(KERN_ERR DRIVER_NAME ": unfinished request detected\n"); spin_unlock_irqrestore(&sock->lock, flags); goto err_out; } if (r_data) { tifm_sd_set_data_timeout(host, r_data); sg_count = tifm_map_sg(sock, r_data->sg, r_data->sg_len, mrq->cmd->flags & MMC_DATA_WRITE ? PCI_DMA_TODEVICE : PCI_DMA_FROMDEVICE); if (sg_count != 1) { printk(KERN_ERR DRIVER_NAME ": scatterlist map failed\n"); spin_unlock_irqrestore(&sock->lock, flags); goto err_out; } host->written_blocks = 0; host->flags &= ~CARD_BUSY; tifm_sd_prepare_data(host, mrq->cmd); } host->req = mrq; host->state = CMD; queue_delayed_work(sock->wq, &host->abort_handler, host->timeout_jiffies); writel(TIFM_CTRL_LED | readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); tifm_sd_exec(host, mrq->cmd); spin_unlock_irqrestore(&sock->lock, flags); return; err_out: if (sg_count > 0) tifm_unmap_sg(sock, r_data->sg, r_data->sg_len, (r_data->flags & MMC_DATA_WRITE) ? PCI_DMA_TODEVICE : PCI_DMA_FROMDEVICE); mrq->cmd->error = MMC_ERR_TIMEOUT; mmc_request_done(mmc, mrq); } static void tifm_sd_end_cmd(void *data) { struct tifm_sd *host = data; struct tifm_dev *sock = host->dev; struct mmc_host *mmc = tifm_get_drvdata(sock); struct mmc_request *mrq; struct mmc_data *r_data = 0; unsigned long flags; spin_lock_irqsave(&sock->lock, flags); mrq = host->req; host->req = 0; host->state = IDLE; if (!mrq) { printk(KERN_ERR DRIVER_NAME ": no request to complete?\n"); spin_unlock_irqrestore(&sock->lock, flags); return; } r_data = mrq->cmd->data; if (r_data) { if (r_data->flags & MMC_DATA_WRITE) { r_data->bytes_xfered = host->written_blocks * r_data->blksz; } else { r_data->bytes_xfered = r_data->blocks - readl(sock->addr + SOCK_MMCSD_NUM_BLOCKS) - 1; r_data->bytes_xfered *= r_data->blksz; r_data->bytes_xfered += r_data->blksz - readl(sock->addr + SOCK_MMCSD_BLOCK_LEN) + 1; } tifm_unmap_sg(sock, r_data->sg, r_data->sg_len, (r_data->flags & MMC_DATA_WRITE) ? PCI_DMA_TODEVICE : PCI_DMA_FROMDEVICE); } writel((~TIFM_CTRL_LED) & readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); spin_unlock_irqrestore(&sock->lock, flags); mmc_request_done(mmc, mrq); } static void tifm_sd_request_nodma(struct mmc_host *mmc, struct mmc_request *mrq) { struct tifm_sd *host = mmc_priv(mmc); struct tifm_dev *sock = host->dev; unsigned long flags; struct mmc_data *r_data = mrq->cmd->data; char *t_buffer = 0; if (r_data) { t_buffer = kmap(r_data->sg->page); if (!t_buffer) { printk(KERN_ERR DRIVER_NAME ": kmap failed\n"); goto err_out; } } spin_lock_irqsave(&sock->lock, flags); if (host->flags & EJECT) { spin_unlock_irqrestore(&sock->lock, flags); goto err_out; } if (host->req) { printk(KERN_ERR DRIVER_NAME ": unfinished request detected\n"); spin_unlock_irqrestore(&sock->lock, flags); goto err_out; } if (r_data) { tifm_sd_set_data_timeout(host, r_data); host->buffer = t_buffer + r_data->sg->offset; host->buffer_size = mrq->cmd->data->blocks * mrq->cmd->data->blksz; writel(TIFM_MMCSD_BUFINT | readl(sock->addr + SOCK_MMCSD_INT_ENABLE), sock->addr + SOCK_MMCSD_INT_ENABLE); writel(((TIFM_MMCSD_FIFO_SIZE - 1) << 8) | (TIFM_MMCSD_FIFO_SIZE - 1), sock->addr + SOCK_MMCSD_BUFFER_CONFIG); host->written_blocks = 0; host->flags &= ~CARD_BUSY; host->buffer_pos = 0; writel(r_data->blocks - 1, sock->addr + SOCK_MMCSD_NUM_BLOCKS); writel(r_data->blksz - 1, sock->addr + SOCK_MMCSD_BLOCK_LEN); } host->req = mrq; host->state = CMD; queue_delayed_work(sock->wq, &host->abort_handler, host->timeout_jiffies); writel(TIFM_CTRL_LED | readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); tifm_sd_exec(host, mrq->cmd); spin_unlock_irqrestore(&sock->lock, flags); return; err_out: if (t_buffer) kunmap(r_data->sg->page); mrq->cmd->error = MMC_ERR_TIMEOUT; mmc_request_done(mmc, mrq); } static void tifm_sd_end_cmd_nodma(void *data) { struct tifm_sd *host = (struct tifm_sd*)data; struct tifm_dev *sock = host->dev; struct mmc_host *mmc = tifm_get_drvdata(sock); struct mmc_request *mrq; struct mmc_data *r_data = 0; unsigned long flags; spin_lock_irqsave(&sock->lock, flags); mrq = host->req; host->req = 0; host->state = IDLE; if (!mrq) { printk(KERN_ERR DRIVER_NAME ": no request to complete?\n"); spin_unlock_irqrestore(&sock->lock, flags); return; } r_data = mrq->cmd->data; if (r_data) { writel((~TIFM_MMCSD_BUFINT) & readl(sock->addr + SOCK_MMCSD_INT_ENABLE), sock->addr + SOCK_MMCSD_INT_ENABLE); if (r_data->flags & MMC_DATA_WRITE) { r_data->bytes_xfered = host->written_blocks * r_data->blksz; } else { r_data->bytes_xfered = r_data->blocks - readl(sock->addr + SOCK_MMCSD_NUM_BLOCKS) - 1; r_data->bytes_xfered *= r_data->blksz; r_data->bytes_xfered += r_data->blksz - readl(sock->addr + SOCK_MMCSD_BLOCK_LEN) + 1; } host->buffer = 0; host->buffer_pos = 0; host->buffer_size = 0; } writel((~TIFM_CTRL_LED) & readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); spin_unlock_irqrestore(&sock->lock, flags); if (r_data) kunmap(r_data->sg->page); mmc_request_done(mmc, mrq); } static void tifm_sd_abort(void *data) { printk(KERN_ERR DRIVER_NAME ": card failed to respond for a long period of time"); tifm_eject(((struct tifm_sd*)data)->dev); } static void tifm_sd_ios(struct mmc_host *mmc, struct mmc_ios *ios) { struct tifm_sd *host = mmc_priv(mmc); struct tifm_dev *sock = host->dev; unsigned int clk_div1, clk_div2; unsigned long flags; spin_lock_irqsave(&sock->lock, flags); dev_dbg(&sock->dev, "Setting bus width %d, power %d\n", ios->bus_width, ios->power_mode); if (ios->bus_width == MMC_BUS_WIDTH_4) { writel(TIFM_MMCSD_4BBUS | readl(sock->addr + SOCK_MMCSD_CONFIG), sock->addr + SOCK_MMCSD_CONFIG); } else { writel((~TIFM_MMCSD_4BBUS) & readl(sock->addr + SOCK_MMCSD_CONFIG), sock->addr + SOCK_MMCSD_CONFIG); } if (ios->clock) { clk_div1 = 20000000 / ios->clock; if (!clk_div1) clk_div1 = 1; clk_div2 = 24000000 / ios->clock; if (!clk_div2) clk_div2 = 1; if ((20000000 / clk_div1) > ios->clock) clk_div1++; if ((24000000 / clk_div2) > ios->clock) clk_div2++; if ((20000000 / clk_div1) > (24000000 / clk_div2)) { host->clk_freq = 20000000; host->clk_div = clk_div1; writel((~TIFM_CTRL_FAST_CLK) & readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); } else { host->clk_freq = 24000000; host->clk_div = clk_div2; writel(TIFM_CTRL_FAST_CLK | readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); } } else { host->clk_div = 0; } host->clk_div &= TIFM_MMCSD_CLKMASK; writel(host->clk_div | ((~TIFM_MMCSD_CLKMASK) & readl(sock->addr + SOCK_MMCSD_CONFIG)), sock->addr + SOCK_MMCSD_CONFIG); if (ios->bus_mode == MMC_BUSMODE_OPENDRAIN) host->flags |= OPENDRAIN; else host->flags &= ~OPENDRAIN; /* chip_select : maybe later */ //vdd //power is set before probe / after remove //I believe, power_off when already marked for eject is sufficient to // allow removal. if ((host->flags & EJECT) && ios->power_mode == MMC_POWER_OFF) { host->flags |= EJECT_DONE; wake_up_all(&host->can_eject); } spin_unlock_irqrestore(&sock->lock, flags); } static int tifm_sd_ro(struct mmc_host *mmc) { int rc; struct tifm_sd *host = mmc_priv(mmc); struct tifm_dev *sock = host->dev; unsigned long flags; spin_lock_irqsave(&sock->lock, flags); host->flags |= (CARD_RO & readl(sock->addr + SOCK_PRESENT_STATE)); rc = (host->flags & CARD_RO) ? 1 : 0; spin_unlock_irqrestore(&sock->lock, flags); return rc; } static struct mmc_host_ops tifm_sd_ops = { .request = tifm_sd_request, .set_ios = tifm_sd_ios, .get_ro = tifm_sd_ro }; static void tifm_sd_register_host(void *data) { struct tifm_sd *host = (struct tifm_sd*)data; struct tifm_dev *sock = host->dev; struct mmc_host *mmc = tifm_get_drvdata(sock); unsigned long flags; spin_lock_irqsave(&sock->lock, flags); host->flags |= HOST_REG; PREPARE_WORK(&host->cmd_handler, no_dma ? tifm_sd_end_cmd_nodma : tifm_sd_end_cmd, data); spin_unlock_irqrestore(&sock->lock, flags); dev_dbg(&sock->dev, "adding host\n"); mmc_add_host(mmc); } static int tifm_sd_probe(struct tifm_dev *sock) { struct mmc_host *mmc; struct tifm_sd *host; int rc = -EIO; if (!(TIFM_SOCK_STATE_OCCUPIED & readl(sock->addr + SOCK_PRESENT_STATE))) { printk(KERN_WARNING DRIVER_NAME ": card gone, unexpectedly\n"); return rc; } mmc = mmc_alloc_host(sizeof(struct tifm_sd), &sock->dev); if (!mmc) return -ENOMEM; host = mmc_priv(mmc); host->dev = sock; host->clk_div = 61; init_waitqueue_head(&host->can_eject); INIT_WORK(&host->cmd_handler, tifm_sd_register_host, host); INIT_WORK(&host->abort_handler, tifm_sd_abort, host); tifm_set_drvdata(sock, mmc); sock->signal_irq = tifm_sd_signal_irq; host->clk_freq = 20000000; host->timeout_jiffies = msecs_to_jiffies(1000); tifm_sd_ops.request = no_dma ? tifm_sd_request_nodma : tifm_sd_request; mmc->ops = &tifm_sd_ops; mmc->ocr_avail = MMC_VDD_32_33 | MMC_VDD_33_34; mmc->caps = MMC_CAP_4_BIT_DATA; mmc->f_min = 20000000 / 60; mmc->f_max = 24000000; mmc->max_hw_segs = 1; mmc->max_phys_segs = 1; mmc->max_sectors = 127; mmc->max_seg_size = mmc->max_sectors << 11; //2k maximum hw block length writel(0, sock->addr + SOCK_MMCSD_INT_ENABLE); writel(TIFM_MMCSD_RESET, sock->addr + SOCK_MMCSD_SYSTEM_CONTROL); writel(host->clk_div | TIFM_MMCSD_POWER, sock->addr + SOCK_MMCSD_CONFIG); for (rc = 0; rc < 50; rc++) { /* Wait for reset ack */ if (1 & readl(sock->addr + SOCK_MMCSD_SYSTEM_STATUS)) { rc = 0; break; } msleep(10); } if (rc) { printk(KERN_ERR DRIVER_NAME ": card not ready - probe failed\n"); mmc_free_host(mmc); return -ENODEV; } writel(0, sock->addr + SOCK_MMCSD_NUM_BLOCKS); writel(host->clk_div | TIFM_MMCSD_POWER, sock->addr + SOCK_MMCSD_CONFIG); writel(TIFM_MMCSD_RXDE, sock->addr + SOCK_MMCSD_BUFFER_CONFIG); writel(TIFM_MMCSD_DATAMASK | TIFM_MMCSD_ERRMASK, sock->addr + SOCK_MMCSD_INT_ENABLE); writel(64, sock->addr + SOCK_MMCSD_COMMAND_TO); // command timeout 64 clocks for now writel(TIFM_MMCSD_INAB, sock->addr + SOCK_MMCSD_COMMAND); writel(host->clk_div | TIFM_MMCSD_POWER, sock->addr + SOCK_MMCSD_CONFIG); queue_delayed_work(sock->wq, &host->abort_handler, host->timeout_jiffies); return 0; } static int tifm_sd_host_is_down(struct tifm_dev *sock) { struct mmc_host *mmc = tifm_get_drvdata(sock); struct tifm_sd *host = mmc_priv(mmc); unsigned long flags; int rc = 0; spin_lock_irqsave(&sock->lock, flags); rc = (host->flags & EJECT_DONE); spin_unlock_irqrestore(&sock->lock, flags); return rc; } static void tifm_sd_remove(struct tifm_dev *sock) { struct mmc_host *mmc = tifm_get_drvdata(sock); struct tifm_sd *host = mmc_priv(mmc); unsigned long flags; spin_lock_irqsave(&sock->lock, flags); host->flags |= EJECT; if (host->req) queue_work(sock->wq, &host->cmd_handler); spin_unlock_irqrestore(&sock->lock, flags); wait_event_timeout(host->can_eject, tifm_sd_host_is_down(sock), host->timeout_jiffies); if (host->flags & HOST_REG) mmc_remove_host(mmc); /* The meaning of the bit majority in this constant is unknown. */ writel(0xfff8 & readl(sock->addr + SOCK_CONTROL), sock->addr + SOCK_CONTROL); writel(0, sock->addr + SOCK_MMCSD_INT_ENABLE); writel(TIFM_FIFO_INT_SETALL, sock->addr + SOCK_DMA_FIFO_INT_ENABLE_CLEAR); writel(0, sock->addr + SOCK_DMA_FIFO_INT_ENABLE_SET); tifm_set_drvdata(sock, 0); mmc_free_host(mmc); } static tifm_media_id tifm_sd_id_tbl[] = { FM_SD, 0 }; static struct tifm_driver tifm_sd_driver = { .driver = { .name = DRIVER_NAME, .owner = THIS_MODULE }, .id_table = tifm_sd_id_tbl, .probe = tifm_sd_probe, .remove = tifm_sd_remove }; static int __init tifm_sd_init(void) { return tifm_register_driver(&tifm_sd_driver); } static void __exit tifm_sd_exit(void) { tifm_unregister_driver(&tifm_sd_driver); } MODULE_AUTHOR("Alex Dubov"); MODULE_DESCRIPTION("TI FlashMedia SD driver"); MODULE_LICENSE("GPL"); MODULE_DEVICE_TABLE(tifm, tifm_sd_id_tbl); MODULE_VERSION(DRIVER_VERSION); module_init(tifm_sd_init); module_exit(tifm_sd_exit);