/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2006 Daniel Ankers * Copyright © 2008-2009 Rafaël Carré * Copyright (C) 2011 Marcin Bukat * * 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" /* for HAVE_MULTIVOLUME */ #include "thread.h" #include "gcc_extensions.h" #include "led.h" #include "sdmmc.h" #include "system.h" #include "kernel.h" #include "cpu.h" #include #include #include #include "panic.h" #include "stdbool.h" #include "storage.h" #include "lcd.h" #include #include "sysfont.h" #define RES_NO (-1) /* debug stuff */ unsigned long sd_debug_time_rd = 0; unsigned long sd_debug_time_wr = 0; static tCardInfo card_info; /* for compatibility */ static long last_disk_activity = -1; static unsigned char aligned_buf[512] STORAGE_ALIGN_ATTR; static struct mutex sd_mtx SHAREDBSS_ATTR; #ifndef BOOTLOADER bool sd_enabled = false; #endif #ifdef CONFIG_STORAGE_MULTI static int sd_first_drive = 0; #else #define sd_first_drive 0 #endif static struct semaphore transfer_completion_signal; static struct semaphore command_completion_signal; static volatile bool retry; static volatile int cmd_error; static void enable_controller(bool on) { /* enable or disable clock signal for SD module */ if (on) { SCU_CLKCFG &= ~CLKCFG_SD; led(true); } else { SCU_CLKCFG |= CLKCFG_SD; led(false); } } /* interrupt handler for SD */ void INT_SD(void) { const int status = SD_INT; SD_INT = 0; /* disable sd interrupts, clear pending interrupts */ /* cmd and response status pending */ if(status & CMD_RES_STAT) { /* get the status */ cmd_error = SD_CMDRES; semaphore_release(&command_completion_signal); } /* data transfer status pending */ if(status & DATA_XFER_STAT) { cmd_error = SD_DATAT; if (cmd_error & DATA_XFER_ERR) retry = true; semaphore_release(&transfer_completion_signal); } SD_INT = CMD_RES_INT_EN | DATA_XFER_INT_EN; } /* Exchange buffers - the one where SD module puts into/reads from * data and the one controlled by MCU. This allows some overlap * in transfer operations and should increase throuput. */ static void mmu_switch_buff(void) { static unsigned int i = 0; if (i++ & 0x01) { MMU_CTRL = MMU_MMU0_BUFII | MMU_CPU_BUFI | MMU_BUFII_RESET | MMU_BUFII_BYTE | MMU_BUFI_RESET | MMU_BUFI_WORD; } else { MMU_CTRL = MMU_MMU0_BUFI | MMU_CPU_BUFII | MMU_BUFII_RESET | MMU_BUFII_WORD | MMU_BUFI_RESET | MMU_BUFI_BYTE; } } /* Reset internal pointers of the MMU submodule */ static void mmu_buff_reset(void) { MMU_CTRL |= MMU_BUFII_RESET | MMU_BUFI_RESET; } static inline bool card_detect_target(void) { #if defined(RK27_GENERIC) || defined(IHIFI770) || defined(IHIFI770C) || defined(IHIFI800) /* PC7, active low */ return !(GPIO_PCDR & 0x80); #elif defined(HM60X) || defined(HM801) /* PF2, active low */ return !(GPIO_PFDR & (1<<2)); #elif defined(MA9) || defined(MA9C) || defined(MA8) || defined(MA8C) /* PC7, active high */ return (GPIO_PCDR & (1<<7)); #elif defined(IHIFI760) || defined(IHIFI960) /* TODO: find out pin */ return true; #else #error "Unknown target" #endif } /* Send command to the SD card. Command finish is signaled in ISR */ static bool send_cmd(const int cmd, const int arg, const int res, unsigned long *response) { SD_CMD = arg; if (res > 0) SD_CMDREST = CMD_XFER_START | RES_XFER_START | res | cmd; else SD_CMDREST = CMD_XFER_START | RES_XFER_END | RES_R1 | cmd; semaphore_wait(&command_completion_signal, TIMEOUT_BLOCK); /* Handle command responses & errors */ if(res != RES_NO) { if(cmd_error & STAT_CMD_RES_ERR) return false; if(res == RES_R2) { response[0] = SD_RES3; response[1] = SD_RES2; response[2] = SD_RES1; response[3] = SD_RES0; } else response[0] = SD_RES3; } return true; } #if 0 /* for some misterious reason the card does not report itself as being in TRAN * but transfers are successful. Rockchip OF does not check the card state * after SELECT. I checked two different cards. */ static void print_card_status(void) { unsigned long response; send_cmd(SD_SEND_STATUS, card_info.rca, RES_R1, &response); printf("card status: 0x%0x, state: 0x%0x", response, (response>>9)&0xf); } static int sd_wait_for_tran_state(void) { unsigned long response; unsigned int timeout = current_tick + 5*HZ; int cmd_retry = 10; while (1) { while (!send_cmd(SD_SEND_STATUS, card_info.rca, RES_R1, &response) && cmd_retry > 0) { cmd_retry--; } if (cmd_retry <= 0) { return -1; } if (((response >> 9) & 0xf) == SD_TRAN) { return 0; } if(TIME_AFTER(current_tick, timeout)) { return -10 * ((response >> 9) & 0xf); } last_disk_activity = current_tick; } } #endif static bool sd_wait_card_busy(void) { unsigned int timeout = current_tick + 5*HZ; while (!(SD_CARD & SD_CARD_BSY)) { if(TIME_AFTER(current_tick, timeout)) return false; } return true; } static int sd_init_card(void) { unsigned long response; long init_timeout; bool sd_v2 = false; card_info.rca = 0; /* assume 50 MHz APB freq / 125 = 400 kHz */ SD_CTRL = (SD_CTRL & ~(0x7FF)) | 0x7D; /* 100 - 400kHz clock required for Identification Mode */ /* Start of Card Identification Mode ************************************/ /* CMD0 Go Idle */ if(!send_cmd(SD_GO_IDLE_STATE, 0, RES_NO, NULL)) return -1; sleep(1); /* CMD8 Check for v2 sd card. Must be sent before using ACMD41 Non v2 cards will not respond to this command*/ if(send_cmd(SD_SEND_IF_COND, 0x1AA, RES_R6, &response)) if((response & 0xFFF) == 0x1AA) sd_v2 = true; /* Timeout for inintialization is 2 sec. According to SD Specification 2.00 it should be >= 1, but it's not enough in some rare cases. */ init_timeout = current_tick + 2*HZ; do { /* this timeout is the only valid error for this loop*/ if(TIME_AFTER(current_tick, init_timeout)) return -2; if(!send_cmd(SD_APP_CMD, card_info.rca, RES_R1, &response)) return -3; sleep(1); /* bus conflict otherwise */ /* ACMD41 For v2 cards set HCS bit[30] & send host voltage range to all */ if(!send_cmd(SD_APP_OP_COND, (0x00FF8000 | (sd_v2 ? 1<<30 : 0)), RES_R3, &card_info.ocr)) return -4; } while(!(card_info.ocr & (1<<31)) ); /* CMD2 send CID */ if(!send_cmd(SD_ALL_SEND_CID, 0, RES_R2, card_info.cid)) return -5; /* CMD3 send RCA */ if(!send_cmd(SD_SEND_RELATIVE_ADDR, 0, RES_R6, &card_info.rca)) return -6; /* End of Card Identification Mode ************************************/ /* CMD9 send CSD */ if(!send_cmd(SD_SEND_CSD, card_info.rca, RES_R2, card_info.csd)) return -11; sd_parse_csd(&card_info); if(!send_cmd(SD_SELECT_CARD, card_info.rca, RES_R1b, &response)) return -20; if (!sd_wait_card_busy()) return -21; /* CMD6 */ if(!send_cmd(SD_SWITCH_FUNC, 0x80fffff1, RES_R1, &response)) return -8; sleep(HZ/10); /* Card back to full speed 25MHz*/ SD_CTRL = (SD_CTRL & ~0x7FF); card_info.initialized = 1; return 0; } static void init_controller(void) { /* reset SD module */ SCU_RSTCFG |= RSTCFG_SD; sleep(1); SCU_RSTCFG &= ~RSTCFG_SD; /* set pins functions as SD signals */ SCU_IOMUXA_CON |= IOMUX_SD; /* enable and unmask SD interrupts in interrupt controller */ SCU_CLKCFG &= ~CLKCFG_SD; INTC_IMR |= IRQ_ARM_SD; INTC_IECR |= IRQ_ARM_SD; SD_CTRL = SD_PWR_CPU | SD_DETECT_MECH | SD_CLOCK_EN | 0x7D; SD_INT = CMD_RES_INT_EN | DATA_XFER_INT_EN; SD_CARD = SD_CARD_SELECT | SD_CARD_PWR_EN; /* setup mmu buffers */ MMU_PNRI = 0x1ff; MMU_PNRII = 0x1ff; MMU_CTRL = MMU_MMU0_BUFII | MMU_CPU_BUFI | MMU_BUFII_RESET | MMU_BUFII_BYTE | MMU_BUFI_RESET | MMU_BUFI_WORD; /* setup A2A DMA CH0 for SD reads */ A2A_ISRC0 = (unsigned long)(&MMU_DATA); A2A_ICNT0 = 512; A2A_LCNT0 = 1; /* setup A2A DMA CH1 for SD writes */ A2A_IDST1 = (unsigned long)(&MMU_DATA); A2A_ICNT1 = 512; A2A_LCNT1 = 1; /* src and dst for CH0 and CH1 is AHB0 */ A2A_DOMAIN = 0; #ifdef RK27XX_SD_DEBUG /* setup Timer1 for profiling purposes */ TMR1CON = (1<<8)|(1<<3); #endif } int sd_init(void) { int ret; mutex_init(&sd_mtx); semaphore_init(&transfer_completion_signal, 1, 0); semaphore_init(&command_completion_signal, 1, 0); init_controller(); ret = sd_init_card(); if(ret < 0) return ret; return 0; } static inline void read_sd_data(unsigned char **dst) { void *buf = *dst; if (!IS_ALIGNED(((unsigned long)*dst), CACHEALIGN_SIZE)) buf = aligned_buf; commit_discard_dcache_range((const void *)buf, 512); A2A_IDST0 = (unsigned long)buf; A2A_CON0 = (3<<9) | /* burst 16 */ (1<<6) | /* fixed src */ (1<<3) | /* DMA start */ (2<<1) | /* word transfer size */ (1<<0); /* software mode */ /* wait for DMA engine to finish transfer */ while (A2A_DMA_STS & 1); if (buf == aligned_buf) memcpy(*dst, aligned_buf, 512); *dst += 512; } static inline void write_sd_data(unsigned char **src) { void *buf = *src; if (!IS_ALIGNED(((unsigned long)*src), CACHEALIGN_SIZE)) { buf = aligned_buf; memcpy(aligned_buf, *src, 512); } commit_discard_dcache_range((const void *)buf, 512); A2A_ISRC1 = (unsigned long)buf; A2A_CON1 = (3<<9) | /* burst 16 */ (1<<5) | /* fixed dst */ (1<<3) | /* DMA start */ (2<<1) | /* word transfer size */ (1<<0); /* software mode */ /* wait for DMA engine to finish transfer */ while (A2A_DMA_STS & 2); *src += 512; } int sd_read_sectors(IF_MD(int drive,) unsigned long start, int count, void* buf) { #ifdef HAVE_MULTIDRIVE (void)drive; #endif unsigned long response; unsigned int retry_cnt = 0; int cnt, ret = 0; unsigned char *dst; mutex_lock(&sd_mtx); enable_controller(true); if (count <= 0 || start + count > card_info.numblocks) return -1; if(!(card_info.ocr & (1<<30))) start <<= 9; /* not SDHC */ while (retry_cnt++ < 20) { cnt = count; dst = (unsigned char *)buf; ret = 0; retry = false; /* reset retry flag */ mmu_buff_reset(); if (cnt == 1) { /* last block to transfer */ SD_DATAT = DATA_XFER_START | DATA_XFER_READ | DATA_BUS_1LINE | DATA_XFER_DMA_DIS | DATA_XFER_SINGLE; } else { /* more than one block to transfer */ SD_DATAT = DATA_XFER_START | DATA_XFER_READ | DATA_BUS_1LINE | DATA_XFER_DMA_DIS | DATA_XFER_MULTI; } /* issue read command to the card */ if (!send_cmd(SD_READ_MULTIPLE_BLOCK, start, RES_R1, &response)) { ret = -2; continue; } while (cnt > 0) { #ifdef RK27XX_SD_DEBUG /* debug stuff */ TMR1LR = 0xffffffff; #endif /* wait for transfer completion */ semaphore_wait(&transfer_completion_signal, TIMEOUT_BLOCK); #ifdef RK27XX_SD_DEBUG /* debug stuff */ sd_debug_time_rd = 0xffffffff - TMR1CVR; #endif if (retry) { /* data transfer error */ ret = -3; break; } /* exchange buffers */ mmu_switch_buff(); cnt--; if (cnt == 0) { if (!send_cmd(SD_STOP_TRANSMISSION, 0, RES_R1b, &response)) ret = -4; read_sd_data(&dst); break; } else if (cnt == 1) { /* last block to transfer */ SD_DATAT = DATA_XFER_START | DATA_XFER_READ | DATA_BUS_1LINE | DATA_XFER_DMA_DIS | DATA_XFER_SINGLE; read_sd_data(&dst); } else { /* more than one block to transfer */ SD_DATAT = DATA_XFER_START | DATA_XFER_READ | DATA_BUS_1LINE | DATA_XFER_DMA_DIS | DATA_XFER_MULTI; read_sd_data(&dst); } last_disk_activity = current_tick; } /* while (cnt > 0) */ /* transfer successfull - leave retry loop */ if (ret == 0) break; } /* while (retry_cnt++ < 20) */ enable_controller(false); mutex_unlock(&sd_mtx); return ret; } /* Not tested */ int sd_write_sectors(IF_MD(int drive,) unsigned long start, int count, const void* buf) { #ifdef HAVE_MULTIDRIVE (void) drive; #endif #if defined(BOOTLOADER) /* we don't need write support in bootloader */ (void) start; (void) count; (void) buf; return -1; #else #ifdef RK27XX_SD_DEBUG /* debug stuff */ TMR1LR = 0xffffffff; #endif unsigned long response; unsigned int retry_cnt = 0; int cnt, ret = 0; unsigned char *src; /* bool card_selected = false; */ mutex_lock(&sd_mtx); enable_controller(true); if (count <= 0 || start + count > card_info.numblocks) return -1; if(!(card_info.ocr & (1<<30))) start <<= 9; /* not SDHC */ while (retry_cnt++ < 20) { cnt = count; src = (unsigned char *)buf; ret = 0; retry = false; /* reset retry flag */ mmu_buff_reset(); /* reset recive buff state */ write_sd_data(&src); /* put data into transfer buffer */ if (!send_cmd(SD_WRITE_MULTIPLE_BLOCK, start, RES_R1, &response)) { ret = -3; continue; } while (cnt > 0) { /* exchange buffers */ mmu_switch_buff(); if (cnt == 1) { /* last block to transfer */ SD_DATAT = DATA_XFER_START | DATA_XFER_WRITE | DATA_BUS_1LINE | DATA_XFER_DMA_DIS | DATA_XFER_SINGLE; } else { /* more than one block to transfer */ SD_DATAT = DATA_XFER_START | DATA_XFER_WRITE | DATA_BUS_1LINE | DATA_XFER_DMA_DIS | DATA_XFER_MULTI; /* put more data */ write_sd_data(&src); } /* wait for transfer completion */ semaphore_wait(&transfer_completion_signal, TIMEOUT_BLOCK); if (retry) { /* data transfer error */ ret = -3; break; } cnt--; } /* while (cnt > 0) */ if (!send_cmd(SD_STOP_TRANSMISSION, 0, RES_R1b, &response)) ret = -4; if (!sd_wait_card_busy()) ret = -5; /* transfer successfull - leave retry loop */ if (ret == 0) break; } enable_controller(false); mutex_unlock(&sd_mtx); #ifdef RK27XX_SD_DEBUG /* debug stuff */ sd_debug_time_wr = 0xffffffff - TMR1CVR; #endif return ret; #endif /* defined(BOOTLOADER) */ } void sd_enable(bool on) { mutex_lock(&sd_mtx); enable_controller(on); mutex_unlock(&sd_mtx); } #ifndef BOOTLOADER long sd_last_disk_activity(void) { return last_disk_activity; } tCardInfo *card_get_info_target(int card_no) { (void)card_no; return &card_info; } #endif /* BOOTLOADER */ #ifdef HAVE_HOTSWAP /* Not complete and disabled in config */ bool sd_removable(IF_MD_NONVOID(int drive)) { (void)drive; return true; } bool sd_present(IF_MD_NONVOID(int drive)) { (void)drive; return card_detect_target(); } static int sd_oneshot_callback(struct timeout *tmo) { /* This is called only if the state was stable for 300ms - check state * and post appropriate event. */ queue_broadcast(card_detect_target() ? SYS_HOTSWAP_INSERTED : SYS_HOTSWAP_EXTRACTED, sd_first_drive); return 0; (void)tmo; } /* interrupt handler for SD detect */ #endif /* HAVE_HOTSWAP */ #ifdef CONFIG_STORAGE_MULTI int sd_num_drives(int first_drive) { /* we have only one SD drive */ sd_first_drive = first_drive; return 1; } #endif /* CONFIG_STORAGE_MULTI */ int sd_event(long id, intptr_t data) { int rc = 0; switch (id) { #ifdef HAVE_HOTSWAP case SYS_HOTSWAP_INSERTED: case SYS_HOTSWAP_EXTRACTED: mutex_lock(&sd_mtx); /* lock-out card activity */ /* 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_info.initialized = 0; if (id == SYS_HOTSWAP_INSERTED) { enable_controller(true); rc = sd_init_card(); enable_controller(false); } mutex_unlock(&sd_mtx); break; #endif /* HAVE_HOTSWAP */ default: rc = storage_event_default_handler(id, data, last_disk_activity, STORAGE_SD); break; } return rc; }