src/hw/sdcard.c - seabios-hppa - Git at Google

 // PCI SD Host Controller Interface
 //
 // Copyright (C) 2014  Kevin O'Connor <kevin@koconnor.net>
 //
 // This file may be distributed under the terms of the GNU LGPLv3 license.

 #include "block.h" // struct drive_s
 #include "malloc.h" // malloc_fseg
 #include "output.h" // znprintf
 #include "pcidevice.h" // foreachpci
 #include "pci_ids.h" // PCI_CLASS_SYSTEM_SDHCI
 #include "pci_regs.h" // PCI_BASE_ADDRESS_0
 #include "romfile.h" // romfile_findprefix
 #include "stacks.h" // yield
 #include "std/disk.h" // DISK_RET_SUCCESS
 #include "string.h" // memset
 #include "util.h" // boot_add_hd
 #include "x86.h" // writel

 // SDHCI MMIO registers
 struct sdhci_s {
     u32 sdma_addr;
     u16 block_size;
     u16 block_count;
     u32 arg;
     u16 transfer_mode;
     u16 cmd;
     u32 response[4];
     u32 data;
     u32 present_state;
     u8 host_control;
     u8 power_control;
     u8 block_gap_control;
     u8 wakeup_control;
     u16 clock_control;
     u8 timeout_control;
     u8 software_reset;
     u16 irq_status;
     u16 error_irq_status;
     u16 irq_enable;
     u16 error_irq_enable;
     u16 irq_signal;
     u16 error_signal;
     u16 auto_cmd12;
     u16 host_control2;
     u32 cap_lo, cap_hi;
     u64 max_current;
     u16 force_auto_cmd12;
     u16 force_error;
     u8 adma_error;
     u8 pad_55[3];
     u64 adma_addr;
     u8 pad_60[156];
     u16 slot_irq;
     u16 controller_version;
 } PACKED;

 // SDHCI commands
 #define SCB_R0   0x00 // No response
 #define SCB_R48  0x1a // Response R1 (no data), R5, R6, R7
 #define SCB_R48d 0x3a // Response R1 (with data)
 #define SCB_R48b 0x1b // Response R1b, R5b
 #define SCB_R48o 0x02 // Response R3, R4
 #define SCB_R136 0x09 // Response R2
 #define SC_GO_IDLE_STATE        ((0<<8) | SCB_R0)
 #define SC_SEND_OP_COND         ((1<<8) | SCB_R48o)
 #define SC_ALL_SEND_CID         ((2<<8) | SCB_R136)
 #define SC_SEND_RELATIVE_ADDR   ((3<<8) | SCB_R48)
 #define SC_SELECT_DESELECT_CARD ((7<<8) | SCB_R48b)
 #define SC_SEND_IF_COND         ((8<<8) | SCB_R48)
 #define SC_SEND_EXT_CSD         ((8<<8) | SCB_R48d)
 #define SC_SEND_CSD             ((9<<8) | SCB_R136)
 #define SC_READ_SINGLE          ((17<<8) | SCB_R48d)
 #define SC_READ_MULTIPLE        ((18<<8) | SCB_R48d)
 #define SC_WRITE_SINGLE         ((24<<8) | SCB_R48d)
 #define SC_WRITE_MULTIPLE       ((25<<8) | SCB_R48d)
 #define SC_APP_CMD              ((55<<8) | SCB_R48)
 #define SC_APP_SEND_OP_COND ((41<<8) | SCB_R48o)

 // SDHCI irqs
 #define SI_CMD_COMPLETE (1<<0)
 #define SI_TRANS_DONE   (1<<1)
 #define SI_WRITE_READY  (1<<4)
 #define SI_READ_READY   (1<<5)
 #define SI_ERROR        (1<<15)

 // SDHCI present_state flags
 #define SP_CMD_INHIBIT   (1<<0)
 #define SP_DAT_INHIBIT   (1<<1)
 #define SP_CARD_INSERTED (1<<16)

 // SDHCI transfer_mode flags
 #define ST_BLOCKCOUNT (1<<1)
 #define ST_AUTO_CMD12 (1<<2)
 #define ST_READ       (1<<4)
 #define ST_MULTIPLE   (1<<5)

 // SDHCI capabilities flags
 #define SD_CAPLO_V33             (1<<24)
 #define SD_CAPLO_V30             (1<<25)
 #define SD_CAPLO_V18             (1<<26)
 #define SD_CAPLO_BASECLOCK_SHIFT 8
 #define SD_CAPLO_BASECLOCK_MASK  0xff

 // SDHCI clock control flags
 #define SCC_INTERNAL_ENABLE (1<<0)
 #define SCC_STABLE          (1<<1)
 #define SCC_CLOCK_ENABLE    (1<<2)
 #define SCC_SDCLK_MASK      0xff
 #define SCC_SDCLK_SHIFT     8
 #define SCC_SDCLK_HI_MASK   0x300
 #define SCC_SDCLK_HI_RSHIFT 2

 // SDHCI power control flags
 #define SPC_POWER_ON (1<<0)
 #define SPC_V18      0x0a
 #define SPC_V30      0x0c
 #define SPC_V33      0x0e

 // SDHCI software reset flags
 #define SRF_ALL  0x01
 #define SRF_CMD  0x02
 #define SRF_DATA 0x04

 // SDHCI result flags
 #define SR_OCR_CCS     (1<<30)
 #define SR_OCR_NOTBUSY (1<<31)

 // SDHCI timeouts
 #define SDHCI_POWER_OFF_TIME   1
 #define SDHCI_POWER_ON_TIME    5
 #define SDHCI_CLOCK_ON_TIME    1 // 74 clock cycles
 #define SDHCI_POWERUP_TIMEOUT  1000
 #define SDHCI_PIO_TIMEOUT      1000  // XXX - this is just made up

 // Internal 'struct drive_s' storage for a detected card
 struct sddrive_s {
     struct drive_s drive;
     struct sdhci_s *regs;
     int card_type;
 };

 // SD card types
 #define SF_MMC          (1<<0)
 #define SF_HIGHCAPACITY (1<<1)

 // Repeatedly read a u16 register until any bit in a given mask is set
 static int
 sdcard_waitw(u16 *reg, u16 mask)
 {
     u32 end = timer_calc(SDHCI_PIO_TIMEOUT);
     for (;;) {
         u16 v = readw(reg);
         if (v & mask)
             return v;
         if (timer_check(end)) {
             dprintf(1, "scard_waitw: %p %x %x\n", reg, mask, v);
             warn_timeout();
             return -1;
         }
         yield();
     }
 }

 // Send an sdhci reset
 static int
 sdcard_reset(struct sdhci_s *regs, int flags)
 {
     writeb(&regs->software_reset, flags);
     u32 end = timer_calc(SDHCI_PIO_TIMEOUT);
     while (readb(&regs->software_reset))
         if (timer_check(end)) {
             warn_timeout();
             return -1;
         }
     return 0;
 }

 // Send a command to the card.
 static int
 sdcard_pio(struct sdhci_s *regs, int cmd, u32 *param)
 {
     u32 state = readl(&regs->present_state);
     dprintf(9, "sdcard_pio cmd %x %x %x\n", cmd, *param, state);
     if ((state & SP_CMD_INHIBIT)
         || ((cmd & 0x03) == 0x03 && state & SP_DAT_INHIBIT)) {
         dprintf(1, "sdcard_pio not ready %x\n", state);
         return -1;
     }
     // Send command
     writel(&regs->arg, *param);
     writew(&regs->cmd, cmd);
     int ret = sdcard_waitw(&regs->irq_status, SI_ERROR|SI_CMD_COMPLETE);
     if (ret < 0)
         return ret;
     if (ret & SI_ERROR) {
         u16 err = readw(&regs->error_irq_status);
         dprintf(3, "sdcard_pio command stop (code=%x)\n", err);
         sdcard_reset(regs, SRF_CMD|SRF_DATA);
         writew(&regs->error_irq_status, err);
         return -1;
     }
     writew(&regs->irq_status, SI_CMD_COMPLETE);
     // Read response
     memcpy(param, regs->response, sizeof(regs->response));
     dprintf(9, "sdcard cmd %x response %x %x %x %x\n"
             , cmd, param[0], param[1], param[2], param[3]);
     return 0;
 }

 // Send an "app specific" command to the card.
 static int
 sdcard_pio_app(struct sdhci_s *regs, int cmd, u32 *param)
 {
     u32 aparam[4] = {};
     int ret = sdcard_pio(regs, SC_APP_CMD, aparam);
     if (ret)
         return ret;
     return sdcard_pio(regs, cmd, param);
 }

 // Send a command to the card which transfers data.
 static int
 sdcard_pio_transfer(struct sddrive_s *drive, int cmd, u32 addr
                     , void *data, int count)
 {
     // Send command
     writew(&drive->regs->block_size, DISK_SECTOR_SIZE);
     writew(&drive->regs->block_count, count);
     int isread = cmd != SC_WRITE_SINGLE && cmd != SC_WRITE_MULTIPLE;
     u16 tmode = ((count > 1 ? ST_MULTIPLE|ST_AUTO_CMD12|ST_BLOCKCOUNT : 0)
                  | (isread ? ST_READ : 0));
     writew(&drive->regs->transfer_mode, tmode);
     if (!(drive->card_type & SF_HIGHCAPACITY))
         addr *= DISK_SECTOR_SIZE;
     u32 param[4] = { addr };
     int ret = sdcard_pio(drive->regs, cmd, param);
     if (ret)
         return ret;
     // Read/write data
     u16 cbit = isread ? SI_READ_READY : SI_WRITE_READY;
     while (count--) {
         ret = sdcard_waitw(&drive->regs->irq_status, cbit);
         if (ret < 0)
             return ret;
         writew(&drive->regs->irq_status, cbit);
         int i;
         for (i=0; i<DISK_SECTOR_SIZE/4; i++) {
             if (isread)
                 *(u32*)data = readl(&drive->regs->data);
             else
                 writel(&drive->regs->data, *(u32*)data);
             data += 4;
         }
     }
     // Complete command
     ret = sdcard_waitw(&drive->regs->irq_status, SI_TRANS_DONE);
     if (ret < 0)
         return ret;
     writew(&drive->regs->irq_status, SI_TRANS_DONE);
     return 0;
 }

 // Read/write a block of data to/from the card.
 static int
 sdcard_readwrite(struct disk_op_s *op, int iswrite)
 {
     struct sddrive_s *drive = container_of(
         op->drive_fl, struct sddrive_s, drive);
     int cmd = iswrite ? SC_WRITE_SINGLE : SC_READ_SINGLE;
     if (op->count > 1)
         cmd = iswrite ? SC_WRITE_MULTIPLE : SC_READ_MULTIPLE;
     int ret = sdcard_pio_transfer(drive, cmd, op->lba, op->buf_fl, op->count);
     if (ret)
         return DISK_RET_EBADTRACK;
     return DISK_RET_SUCCESS;
 }

 int
 sdcard_process_op(struct disk_op_s *op)
 {
     if (!CONFIG_SDCARD)
         return 0;
     switch (op->command) {
     case CMD_READ:
         return sdcard_readwrite(op, 0);
     case CMD_WRITE:
         return sdcard_readwrite(op, 1);
     default:
         return default_process_op(op);
     }
 }


 /****************************************************************
  * Setup
  ****************************************************************/

 static int
 sdcard_set_power(struct sdhci_s *regs)
 {
     u32 cap = readl(&regs->cap_lo);
     u32 volt, vbits;
     if (cap & SD_CAPLO_V33) {
         volt = 1<<20;
         vbits = SPC_V33;
     } else if (cap & SD_CAPLO_V30) {
         volt = 1<<18;
         vbits = SPC_V30;
     } else if (cap & SD_CAPLO_V18) {
         volt = 1<<7;
         vbits = SPC_V18;
     } else {
         dprintf(1, "SD controller unsupported volt range (%x)\n", cap);
         return -1;
     }
     writeb(&regs->power_control, 0);
     msleep(SDHCI_POWER_OFF_TIME);
     writeb(&regs->power_control, vbits | SPC_POWER_ON);
     msleep(SDHCI_POWER_ON_TIME);
     return volt;
 }

 static int
 sdcard_set_frequency(struct sdhci_s *regs, u32 khz)
 {
     u16 ver = readw(&regs->controller_version);
     u32 cap = readl(&regs->cap_lo);
     u32 base_freq = (cap >> SD_CAPLO_BASECLOCK_SHIFT) & SD_CAPLO_BASECLOCK_MASK;
     if (!base_freq) {
         dprintf(1, "Unknown base frequency for SD controller\n");
         return -1;
     }
     // Set new frequency
     u32 divisor = DIV_ROUND_UP(base_freq * 1000, khz);
     u16 creg;
     if ((ver & 0xff) <= 0x01) {
         divisor = divisor > 1 ? 1 << __fls(divisor-1) : 0;
         creg = (divisor & SCC_SDCLK_MASK) << SCC_SDCLK_SHIFT;
     } else {
         divisor = DIV_ROUND_UP(divisor, 2);
         creg = (divisor & SCC_SDCLK_MASK) << SCC_SDCLK_SHIFT;
         creg |= (divisor & SCC_SDCLK_HI_MASK) >> SCC_SDCLK_HI_RSHIFT;
     }
     dprintf(3, "sdcard_set_frequency %d %d %x\n", base_freq, khz, creg);
     writew(&regs->clock_control, 0);
     writew(&regs->clock_control, creg | SCC_INTERNAL_ENABLE);
     // Wait for frequency to become active
     int ret = sdcard_waitw(&regs->clock_control, SCC_STABLE);
     if (ret < 0)
         return ret;
     // Enable SD clock
     writew(&regs->clock_control, creg | SCC_INTERNAL_ENABLE | SCC_CLOCK_ENABLE);
     return 0;
 }

 // Obtain the disk size of an SD card
 static int
 sdcard_get_capacity(struct sddrive_s *drive, u8 *csd)
 {
     // Original MMC/SD card capacity formula
     u16 C_SIZE = (csd[6] >> 6) | (csd[7] << 2) | ((csd[8] & 0x03) << 10);
     u8 C_SIZE_MULT = (csd[4] >> 7) | ((csd[5] & 0x03) << 1);
     u8 READ_BL_LEN = csd[9] & 0x0f;
     u32 count = (C_SIZE+1) << (C_SIZE_MULT + 2 + READ_BL_LEN - 9);
     // Check for newer encoding formats.
     u8 CSD_STRUCTURE = csd[14] >> 6;
     if ((drive->card_type & SF_MMC) && CSD_STRUCTURE >= 2) {
         // Get capacity from EXT_CSD register
         u8 ext_csd[512];
         int ret = sdcard_pio_transfer(drive, SC_SEND_EXT_CSD, 0, ext_csd, 1);
         if (ret)
             return ret;
         count = *(u32*)&ext_csd[212];
     } else if (!(drive->card_type & SF_MMC) && CSD_STRUCTURE >= 1) {
         // High capacity SD card
         u32 C_SIZE2 = csd[5] | (csd[6] << 8) | ((csd[7] & 0x3f) << 16);
         count = (C_SIZE2+1) << (19-9);
     }
     // Fill drive struct and return
     drive->drive.blksize = DISK_SECTOR_SIZE;
     drive->drive.sectors = count;
     return 0;
 }

 // Initialize an SD card
 static int
 sdcard_card_setup(struct sddrive_s *drive, int volt, int prio)
 {
     struct sdhci_s *regs = drive->regs;
     // Set controller to initialization clock rate
     int ret = sdcard_set_frequency(regs, 400);
     if (ret)
         return ret;
     msleep(SDHCI_CLOCK_ON_TIME);
     // Reset card
     u32 param[4] = { };
     ret = sdcard_pio(regs, SC_GO_IDLE_STATE, param);
     if (ret)
         return ret;
     // Let card know SDHC/SDXC is supported and confirm voltage
     u32 hcs = 0, vrange = (volt >= (1<<15) ? 0x100 : 0x200) | 0xaa;
     param[0] = vrange;
     ret = sdcard_pio(regs, SC_SEND_IF_COND, param);
     if (!ret && param[0] == vrange)
         hcs = (1<<30);
     // Verify SD card (instead of MMC or SDIO)
     param[0] = 0x00;
     ret = sdcard_pio_app(regs, SC_APP_SEND_OP_COND, param);
     if (ret) {
         // Check for MMC card
         param[0] = 0x00;
         ret = sdcard_pio(regs, SC_SEND_OP_COND, param);
         if (ret)
             return ret;
         drive->card_type |= SF_MMC;
         hcs = (1<<30);
     }
     // Init card
     u32 end = timer_calc(SDHCI_POWERUP_TIMEOUT);
     for (;;) {
         param[0] = hcs | volt; // high-capacity support and voltage level
         if (drive->card_type & SF_MMC)
             ret = sdcard_pio(regs, SC_SEND_OP_COND, param);
         else
             ret = sdcard_pio_app(regs, SC_APP_SEND_OP_COND, param);
         if (ret)
             return ret;
         if (param[0] & SR_OCR_NOTBUSY)
             break;
         if (timer_check(end)) {
             warn_timeout();
             return -1;
         }
         msleep(5); // Avoid flooding log when debugging
     }
     drive->card_type |= (param[0] & SR_OCR_CCS) ? SF_HIGHCAPACITY : 0;
     // Select card (get cid, set rca, get csd, select card)
     param[0] = 0x00;
     ret = sdcard_pio(regs, SC_ALL_SEND_CID, param);
     if (ret)
         return ret;
     u8 cid[16];
     memcpy(cid, param, sizeof(cid));
     param[0] = drive->card_type & SF_MMC ? 0x0001 << 16 : 0x00;
     ret = sdcard_pio(regs, SC_SEND_RELATIVE_ADDR, param);
     if (ret)
         return ret;
     u16 rca = drive->card_type & SF_MMC ? 0x0001 : param[0] >> 16;
     param[0] = rca << 16;
     ret = sdcard_pio(regs, SC_SEND_CSD, param);
     if (ret)
         return ret;
     u8 csd[16];
     memcpy(csd, param, sizeof(csd));
     param[0] = rca << 16;
     ret = sdcard_pio(regs, SC_SELECT_DESELECT_CARD, param);
     if (ret)
         return ret;
     // Set controller to data transfer clock rate
     ret = sdcard_set_frequency(regs, 25000);
     if (ret)
         return ret;
     // Register drive
     ret = sdcard_get_capacity(drive, csd);
     if (ret)
         return ret;
     char pnm[7] = {};
     int i;
     for (i=0; i < (drive->card_type & SF_MMC ? 6 : 5); i++)
         pnm[i] = cid[11-i];
     char *desc = znprintf(MAXDESCSIZE, "%s %s %dMiB"
                           , drive->card_type & SF_MMC ? "MMC drive" : "SD card"
                           , pnm, (u32)(drive->drive.sectors >> 11));
     dprintf(1, "Found sdcard at %p: %s\n", regs, desc);
     boot_add_hd(&drive->drive, desc, prio);
     return 0;
 }

 // Setup and configure an SD card controller
 static void
 sdcard_controller_setup(struct sdhci_s *regs, int prio)
 {
     // Initialize controller
     u32 present_state = readl(&regs->present_state);
     if (!(present_state & SP_CARD_INSERTED))
         // No card present
         return;
     dprintf(3, "sdhci@%p ver=%x cap=%x %x\n", regs
             , readw(&regs->controller_version)
             , readl(&regs->cap_lo), readl(&regs->cap_hi));
     sdcard_reset(regs, SRF_ALL);
     writew(&regs->irq_signal, 0);
     writew(&regs->irq_enable, 0x01ff);
     writew(&regs->irq_status, readw(&regs->irq_status));
     writew(&regs->error_signal, 0);
     writew(&regs->error_irq_enable, 0x01ff);
     writew(&regs->error_irq_status, readw(&regs->error_irq_status));
     writeb(&regs->timeout_control, 0x0e); // Set to max timeout
     int volt = sdcard_set_power(regs);
     if (volt < 0)
         return;

     // Initialize card
     struct sddrive_s *drive = malloc_fseg(sizeof(*drive));
     if (!drive) {
         warn_noalloc();
         goto fail;
     }
     memset(drive, 0, sizeof(*drive));
     drive->drive.type = DTYPE_SDCARD;
     drive->regs = regs;
     int ret = sdcard_card_setup(drive, volt, prio);
     if (ret) {
         free(drive);
         goto fail;
     }
     return;
 fail:
     writeb(&regs->power_control, 0);
     writew(&regs->clock_control, 0);
 }

 static void
 sdcard_pci_setup(void *data)
 {
     struct pci_device *pci = data;
     // XXX - bars dependent on slot index register in pci config space
     struct sdhci_s *regs = pci_enable_membar(pci, PCI_BASE_ADDRESS_0);
     if (!regs)
         return;
     int prio = bootprio_find_pci_device(pci);
     sdcard_controller_setup(regs, prio);
 }

 static void
 sdcard_romfile_setup(void *data)
 {
     struct romfile_s *file = data;
     int prio = bootprio_find_named_rom(file->name, 0);
     u32 addr = romfile_loadint(file->name, 0);
     dprintf(1, "Starting sdcard controller check at addr %x\n", addr);
     sdcard_controller_setup((void*)addr, prio);
 }

 void
 sdcard_setup(void)
 {
     if (!CONFIG_SDCARD)
         return;

     struct romfile_s *file = NULL;
     int num_romfiles = 0;
     for (;;) {
         file = romfile_findprefix("etc/sdcard", file);
         if (!file)
             break;
         run_thread(sdcard_romfile_setup, file);
         num_romfiles++;
     }
     if (num_romfiles)
         // only scan for PCI controllers if etc/sdcard not used
         return;

     struct pci_device *pci;
     foreachpci(pci) {
         if (pci->class != PCI_CLASS_SYSTEM_SDHCI || pci->prog_if >= 2)
             // Not an SDHCI controller following SDHCI spec
             continue;
         run_thread(sdcard_pci_setup, pci);
     }
 }
	// PCI SD Host Controller Interface
	//
	// Copyright (C) 2014 Kevin O'Connor <kevin@koconnor.net>
	//
	// This file may be distributed under the terms of the GNU LGPLv3 license.

	#include "block.h" // struct drive_s
	#include "malloc.h" // malloc_fseg
	#include "output.h" // znprintf
	#include "pcidevice.h" // foreachpci
	#include "pci_ids.h" // PCI_CLASS_SYSTEM_SDHCI
	#include "pci_regs.h" // PCI_BASE_ADDRESS_0
	#include "romfile.h" // romfile_findprefix
	#include "stacks.h" // yield
	#include "std/disk.h" // DISK_RET_SUCCESS
	#include "string.h" // memset
	#include "util.h" // boot_add_hd
	#include "x86.h" // writel

	// SDHCI MMIO registers
	struct sdhci_s {
	u32 sdma_addr;
	u16 block_size;
	u16 block_count;
	u32 arg;
	u16 transfer_mode;
	u16 cmd;
	u32 response[4];
	u32 data;
	u32 present_state;
	u8 host_control;
	u8 power_control;
	u8 block_gap_control;
	u8 wakeup_control;
	u16 clock_control;
	u8 timeout_control;
	u8 software_reset;
	u16 irq_status;
	u16 error_irq_status;
	u16 irq_enable;
	u16 error_irq_enable;
	u16 irq_signal;
	u16 error_signal;
	u16 auto_cmd12;
	u16 host_control2;
	u32 cap_lo, cap_hi;
	u64 max_current;
	u16 force_auto_cmd12;
	u16 force_error;
	u8 adma_error;
	u8 pad_55[3];
	u64 adma_addr;
	u8 pad_60[156];
	u16 slot_irq;
	u16 controller_version;
	} PACKED;

	// SDHCI commands
	#define SCB_R0 0x00 // No response
	#define SCB_R48 0x1a // Response R1 (no data), R5, R6, R7
	#define SCB_R48d 0x3a // Response R1 (with data)
	#define SCB_R48b 0x1b // Response R1b, R5b
	#define SCB_R48o 0x02 // Response R3, R4
	#define SCB_R136 0x09 // Response R2
	#define SC_GO_IDLE_STATE ((0<<8) \| SCB_R0)
	#define SC_SEND_OP_COND ((1<<8) \| SCB_R48o)
	#define SC_ALL_SEND_CID ((2<<8) \| SCB_R136)
	#define SC_SEND_RELATIVE_ADDR ((3<<8) \| SCB_R48)
	#define SC_SELECT_DESELECT_CARD ((7<<8) \| SCB_R48b)
	#define SC_SEND_IF_COND ((8<<8) \| SCB_R48)
	#define SC_SEND_EXT_CSD ((8<<8) \| SCB_R48d)
	#define SC_SEND_CSD ((9<<8) \| SCB_R136)
	#define SC_READ_SINGLE ((17<<8) \| SCB_R48d)
	#define SC_READ_MULTIPLE ((18<<8) \| SCB_R48d)
	#define SC_WRITE_SINGLE ((24<<8) \| SCB_R48d)
	#define SC_WRITE_MULTIPLE ((25<<8) \| SCB_R48d)
	#define SC_APP_CMD ((55<<8) \| SCB_R48)
	#define SC_APP_SEND_OP_COND ((41<<8) \| SCB_R48o)

	// SDHCI irqs
	#define SI_CMD_COMPLETE (1<<0)
	#define SI_TRANS_DONE (1<<1)
	#define SI_WRITE_READY (1<<4)
	#define SI_READ_READY (1<<5)
	#define SI_ERROR (1<<15)

	// SDHCI present_state flags
	#define SP_CMD_INHIBIT (1<<0)
	#define SP_DAT_INHIBIT (1<<1)
	#define SP_CARD_INSERTED (1<<16)

	// SDHCI transfer_mode flags
	#define ST_BLOCKCOUNT (1<<1)
	#define ST_AUTO_CMD12 (1<<2)
	#define ST_READ (1<<4)
	#define ST_MULTIPLE (1<<5)

	// SDHCI capabilities flags
	#define SD_CAPLO_V33 (1<<24)
	#define SD_CAPLO_V30 (1<<25)
	#define SD_CAPLO_V18 (1<<26)
	#define SD_CAPLO_BASECLOCK_SHIFT 8
	#define SD_CAPLO_BASECLOCK_MASK 0xff

	// SDHCI clock control flags
	#define SCC_INTERNAL_ENABLE (1<<0)
	#define SCC_STABLE (1<<1)
	#define SCC_CLOCK_ENABLE (1<<2)
	#define SCC_SDCLK_MASK 0xff
	#define SCC_SDCLK_SHIFT 8
	#define SCC_SDCLK_HI_MASK 0x300
	#define SCC_SDCLK_HI_RSHIFT 2

	// SDHCI power control flags
	#define SPC_POWER_ON (1<<0)
	#define SPC_V18 0x0a
	#define SPC_V30 0x0c
	#define SPC_V33 0x0e

	// SDHCI software reset flags
	#define SRF_ALL 0x01
	#define SRF_CMD 0x02
	#define SRF_DATA 0x04

	// SDHCI result flags
	#define SR_OCR_CCS (1<<30)
	#define SR_OCR_NOTBUSY (1<<31)

	// SDHCI timeouts
	#define SDHCI_POWER_OFF_TIME 1
	#define SDHCI_POWER_ON_TIME 5
	#define SDHCI_CLOCK_ON_TIME 1 // 74 clock cycles
	#define SDHCI_POWERUP_TIMEOUT 1000
	#define SDHCI_PIO_TIMEOUT 1000 // XXX - this is just made up

	// Internal 'struct drive_s' storage for a detected card
	struct sddrive_s {
	struct drive_s drive;
	struct sdhci_s *regs;
	int card_type;
	};

	// SD card types
	#define SF_MMC (1<<0)
	#define SF_HIGHCAPACITY (1<<1)

	// Repeatedly read a u16 register until any bit in a given mask is set
	static int
	sdcard_waitw(u16 *reg, u16 mask)
	{
	u32 end = timer_calc(SDHCI_PIO_TIMEOUT);
	for (;;) {
	u16 v = readw(reg);
	if (v & mask)
	return v;
	if (timer_check(end)) {
	dprintf(1, "scard_waitw: %p %x %x\n", reg, mask, v);
	warn_timeout();
	return -1;
	}
	yield();
	}
	}

	// Send an sdhci reset
	static int
	sdcard_reset(struct sdhci_s *regs, int flags)
	{
	writeb(&regs->software_reset, flags);
	u32 end = timer_calc(SDHCI_PIO_TIMEOUT);
	while (readb(&regs->software_reset))
	if (timer_check(end)) {
	warn_timeout();
	return -1;
	}
	return 0;
	}

	// Send a command to the card.
	static int
	sdcard_pio(struct sdhci_s regs, int cmd, u32 param)
	{
	u32 state = readl(&regs->present_state);
	dprintf(9, "sdcard_pio cmd %x %x %x\n", cmd, *param, state);
	if ((state & SP_CMD_INHIBIT)
	\|\| ((cmd & 0x03) == 0x03 && state & SP_DAT_INHIBIT)) {
	dprintf(1, "sdcard_pio not ready %x\n", state);
	return -1;
	}
	// Send command
	writel(&regs->arg, *param);
	writew(&regs->cmd, cmd);
	int ret = sdcard_waitw(&regs->irq_status, SI_ERROR\|SI_CMD_COMPLETE);
	if (ret < 0)
	return ret;
	if (ret & SI_ERROR) {
	u16 err = readw(&regs->error_irq_status);
	dprintf(3, "sdcard_pio command stop (code=%x)\n", err);
	sdcard_reset(regs, SRF_CMD\|SRF_DATA);
	writew(&regs->error_irq_status, err);
	return -1;
	}
	writew(&regs->irq_status, SI_CMD_COMPLETE);
	// Read response
	memcpy(param, regs->response, sizeof(regs->response));
	dprintf(9, "sdcard cmd %x response %x %x %x %x\n"
	, cmd, param[0], param[1], param[2], param[3]);
	return 0;
	}

	// Send an "app specific" command to the card.
	static int
	sdcard_pio_app(struct sdhci_s regs, int cmd, u32 param)
	{
	u32 aparam[4] = {};
	int ret = sdcard_pio(regs, SC_APP_CMD, aparam);
	if (ret)
	return ret;
	return sdcard_pio(regs, cmd, param);
	}

	// Send a command to the card which transfers data.
	static int
	sdcard_pio_transfer(struct sddrive_s *drive, int cmd, u32 addr
	, void *data, int count)
	{
	// Send command
	writew(&drive->regs->block_size, DISK_SECTOR_SIZE);
	writew(&drive->regs->block_count, count);
	int isread = cmd != SC_WRITE_SINGLE && cmd != SC_WRITE_MULTIPLE;
	u16 tmode = ((count > 1 ? ST_MULTIPLE\|ST_AUTO_CMD12\|ST_BLOCKCOUNT : 0)
	\| (isread ? ST_READ : 0));
	writew(&drive->regs->transfer_mode, tmode);
	if (!(drive->card_type & SF_HIGHCAPACITY))
	addr *= DISK_SECTOR_SIZE;
	u32 param[4] = { addr };
	int ret = sdcard_pio(drive->regs, cmd, param);
	if (ret)
	return ret;
	// Read/write data
	u16 cbit = isread ? SI_READ_READY : SI_WRITE_READY;
	while (count--) {
	ret = sdcard_waitw(&drive->regs->irq_status, cbit);
	if (ret < 0)
	return ret;
	writew(&drive->regs->irq_status, cbit);
	int i;
	for (i=0; i<DISK_SECTOR_SIZE/4; i++) {
	if (isread)
	(u32)data = readl(&drive->regs->data);
	else
	writel(&drive->regs->data, (u32)data);
	data += 4;
	}
	}
	// Complete command
	ret = sdcard_waitw(&drive->regs->irq_status, SI_TRANS_DONE);
	if (ret < 0)
	return ret;
	writew(&drive->regs->irq_status, SI_TRANS_DONE);
	return 0;
	}

	// Read/write a block of data to/from the card.
	static int
	sdcard_readwrite(struct disk_op_s *op, int iswrite)
	{
	struct sddrive_s *drive = container_of(
	op->drive_fl, struct sddrive_s, drive);
	int cmd = iswrite ? SC_WRITE_SINGLE : SC_READ_SINGLE;
	if (op->count > 1)
	cmd = iswrite ? SC_WRITE_MULTIPLE : SC_READ_MULTIPLE;
	int ret = sdcard_pio_transfer(drive, cmd, op->lba, op->buf_fl, op->count);
	if (ret)
	return DISK_RET_EBADTRACK;
	return DISK_RET_SUCCESS;
	}

	int
	sdcard_process_op(struct disk_op_s *op)
	{
	if (!CONFIG_SDCARD)
	return 0;
	switch (op->command) {
	case CMD_READ:
	return sdcard_readwrite(op, 0);
	case CMD_WRITE:
	return sdcard_readwrite(op, 1);
	default:
	return default_process_op(op);
	}
	}


	/****************************************************************
	* Setup
	****************************************************************/

	static int
	sdcard_set_power(struct sdhci_s *regs)
	{
	u32 cap = readl(&regs->cap_lo);
	u32 volt, vbits;
	if (cap & SD_CAPLO_V33) {
	volt = 1<<20;
	vbits = SPC_V33;
	} else if (cap & SD_CAPLO_V30) {
	volt = 1<<18;
	vbits = SPC_V30;
	} else if (cap & SD_CAPLO_V18) {
	volt = 1<<7;
	vbits = SPC_V18;
	} else {
	dprintf(1, "SD controller unsupported volt range (%x)\n", cap);
	return -1;
	}
	writeb(&regs->power_control, 0);
	msleep(SDHCI_POWER_OFF_TIME);
	writeb(&regs->power_control, vbits \| SPC_POWER_ON);
	msleep(SDHCI_POWER_ON_TIME);
	return volt;
	}

	static int
	sdcard_set_frequency(struct sdhci_s *regs, u32 khz)
	{
	u16 ver = readw(&regs->controller_version);
	u32 cap = readl(&regs->cap_lo);
	u32 base_freq = (cap >> SD_CAPLO_BASECLOCK_SHIFT) & SD_CAPLO_BASECLOCK_MASK;
	if (!base_freq) {
	dprintf(1, "Unknown base frequency for SD controller\n");
	return -1;
	}
	// Set new frequency
	u32 divisor = DIV_ROUND_UP(base_freq * 1000, khz);
	u16 creg;
	if ((ver & 0xff) <= 0x01) {
	divisor = divisor > 1 ? 1 << __fls(divisor-1) : 0;
	creg = (divisor & SCC_SDCLK_MASK) << SCC_SDCLK_SHIFT;
	} else {
	divisor = DIV_ROUND_UP(divisor, 2);
	creg = (divisor & SCC_SDCLK_MASK) << SCC_SDCLK_SHIFT;
	creg \|= (divisor & SCC_SDCLK_HI_MASK) >> SCC_SDCLK_HI_RSHIFT;
	}
	dprintf(3, "sdcard_set_frequency %d %d %x\n", base_freq, khz, creg);
	writew(&regs->clock_control, 0);
	writew(&regs->clock_control, creg \| SCC_INTERNAL_ENABLE);
	// Wait for frequency to become active
	int ret = sdcard_waitw(&regs->clock_control, SCC_STABLE);
	if (ret < 0)
	return ret;
	// Enable SD clock
	writew(&regs->clock_control, creg \| SCC_INTERNAL_ENABLE \| SCC_CLOCK_ENABLE);
	return 0;
	}

	// Obtain the disk size of an SD card
	static int
	sdcard_get_capacity(struct sddrive_s drive, u8 csd)
	{
	// Original MMC/SD card capacity formula
	u16 C_SIZE = (csd[6] >> 6) \| (csd[7] << 2) \| ((csd[8] & 0x03) << 10);
	u8 C_SIZE_MULT = (csd[4] >> 7) \| ((csd[5] & 0x03) << 1);
	u8 READ_BL_LEN = csd[9] & 0x0f;
	u32 count = (C_SIZE+1) << (C_SIZE_MULT + 2 + READ_BL_LEN - 9);
	// Check for newer encoding formats.
	u8 CSD_STRUCTURE = csd[14] >> 6;
	if ((drive->card_type & SF_MMC) && CSD_STRUCTURE >= 2) {
	// Get capacity from EXT_CSD register
	u8 ext_csd[512];
	int ret = sdcard_pio_transfer(drive, SC_SEND_EXT_CSD, 0, ext_csd, 1);
	if (ret)
	return ret;
	count = (u32)&ext_csd[212];
	} else if (!(drive->card_type & SF_MMC) && CSD_STRUCTURE >= 1) {
	// High capacity SD card
	u32 C_SIZE2 = csd[5] \| (csd[6] << 8) \| ((csd[7] & 0x3f) << 16);
	count = (C_SIZE2+1) << (19-9);
	}
	// Fill drive struct and return
	drive->drive.blksize = DISK_SECTOR_SIZE;
	drive->drive.sectors = count;
	return 0;
	}

	// Initialize an SD card
	static int
	sdcard_card_setup(struct sddrive_s *drive, int volt, int prio)
	{
	struct sdhci_s *regs = drive->regs;
	// Set controller to initialization clock rate
	int ret = sdcard_set_frequency(regs, 400);
	if (ret)
	return ret;
	msleep(SDHCI_CLOCK_ON_TIME);
	// Reset card
	u32 param[4] = { };
	ret = sdcard_pio(regs, SC_GO_IDLE_STATE, param);
	if (ret)
	return ret;
	// Let card know SDHC/SDXC is supported and confirm voltage
	u32 hcs = 0, vrange = (volt >= (1<<15) ? 0x100 : 0x200) \| 0xaa;
	param[0] = vrange;
	ret = sdcard_pio(regs, SC_SEND_IF_COND, param);
	if (!ret && param[0] == vrange)
	hcs = (1<<30);
	// Verify SD card (instead of MMC or SDIO)
	param[0] = 0x00;
	ret = sdcard_pio_app(regs, SC_APP_SEND_OP_COND, param);
	if (ret) {
	// Check for MMC card
	param[0] = 0x00;
	ret = sdcard_pio(regs, SC_SEND_OP_COND, param);
	if (ret)
	return ret;
	drive->card_type \|= SF_MMC;
	hcs = (1<<30);
	}
	// Init card
	u32 end = timer_calc(SDHCI_POWERUP_TIMEOUT);
	for (;;) {
	param[0] = hcs \| volt; // high-capacity support and voltage level
	if (drive->card_type & SF_MMC)
	ret = sdcard_pio(regs, SC_SEND_OP_COND, param);
	else
	ret = sdcard_pio_app(regs, SC_APP_SEND_OP_COND, param);
	if (ret)
	return ret;
	if (param[0] & SR_OCR_NOTBUSY)
	break;
	if (timer_check(end)) {
	warn_timeout();
	return -1;
	}
	msleep(5); // Avoid flooding log when debugging
	}
	drive->card_type \|= (param[0] & SR_OCR_CCS) ? SF_HIGHCAPACITY : 0;
	// Select card (get cid, set rca, get csd, select card)
	param[0] = 0x00;
	ret = sdcard_pio(regs, SC_ALL_SEND_CID, param);
	if (ret)
	return ret;
	u8 cid[16];
	memcpy(cid, param, sizeof(cid));
	param[0] = drive->card_type & SF_MMC ? 0x0001 << 16 : 0x00;
	ret = sdcard_pio(regs, SC_SEND_RELATIVE_ADDR, param);
	if (ret)
	return ret;
	u16 rca = drive->card_type & SF_MMC ? 0x0001 : param[0] >> 16;
	param[0] = rca << 16;
	ret = sdcard_pio(regs, SC_SEND_CSD, param);
	if (ret)
	return ret;
	u8 csd[16];
	memcpy(csd, param, sizeof(csd));
	param[0] = rca << 16;
	ret = sdcard_pio(regs, SC_SELECT_DESELECT_CARD, param);
	if (ret)
	return ret;
	// Set controller to data transfer clock rate
	ret = sdcard_set_frequency(regs, 25000);
	if (ret)
	return ret;
	// Register drive
	ret = sdcard_get_capacity(drive, csd);
	if (ret)
	return ret;
	char pnm[7] = {};
	int i;
	for (i=0; i < (drive->card_type & SF_MMC ? 6 : 5); i++)
	pnm[i] = cid[11-i];
	char *desc = znprintf(MAXDESCSIZE, "%s %s %dMiB"
	, drive->card_type & SF_MMC ? "MMC drive" : "SD card"
	, pnm, (u32)(drive->drive.sectors >> 11));
	dprintf(1, "Found sdcard at %p: %s\n", regs, desc);
	boot_add_hd(&drive->drive, desc, prio);
	return 0;
	}

	// Setup and configure an SD card controller
	static void
	sdcard_controller_setup(struct sdhci_s *regs, int prio)
	{
	// Initialize controller
	u32 present_state = readl(&regs->present_state);
	if (!(present_state & SP_CARD_INSERTED))
	// No card present
	return;
	dprintf(3, "sdhci@%p ver=%x cap=%x %x\n", regs
	, readw(&regs->controller_version)
	, readl(&regs->cap_lo), readl(&regs->cap_hi));
	sdcard_reset(regs, SRF_ALL);
	writew(&regs->irq_signal, 0);
	writew(&regs->irq_enable, 0x01ff);
	writew(&regs->irq_status, readw(&regs->irq_status));
	writew(&regs->error_signal, 0);
	writew(&regs->error_irq_enable, 0x01ff);
	writew(&regs->error_irq_status, readw(&regs->error_irq_status));
	writeb(&regs->timeout_control, 0x0e); // Set to max timeout
	int volt = sdcard_set_power(regs);
	if (volt < 0)
	return;

	// Initialize card
	struct sddrive_s drive = malloc_fseg(sizeof(drive));
	if (!drive) {
	warn_noalloc();
	goto fail;
	}
	memset(drive, 0, sizeof(*drive));
	drive->drive.type = DTYPE_SDCARD;
	drive->regs = regs;
	int ret = sdcard_card_setup(drive, volt, prio);
	if (ret) {
	free(drive);
	goto fail;
	}
	return;
	fail:
	writeb(&regs->power_control, 0);
	writew(&regs->clock_control, 0);
	}

	static void
	sdcard_pci_setup(void *data)
	{
	struct pci_device *pci = data;
	// XXX - bars dependent on slot index register in pci config space
	struct sdhci_s *regs = pci_enable_membar(pci, PCI_BASE_ADDRESS_0);
	if (!regs)
	return;
	int prio = bootprio_find_pci_device(pci);
	sdcard_controller_setup(regs, prio);
	}

	static void
	sdcard_romfile_setup(void *data)
	{
	struct romfile_s *file = data;
	int prio = bootprio_find_named_rom(file->name, 0);
	u32 addr = romfile_loadint(file->name, 0);
	dprintf(1, "Starting sdcard controller check at addr %x\n", addr);
	sdcard_controller_setup((void*)addr, prio);
	}

	void
	sdcard_setup(void)
	{
	if (!CONFIG_SDCARD)
	return;

	struct romfile_s *file = NULL;
	int num_romfiles = 0;
	for (;;) {
	file = romfile_findprefix("etc/sdcard", file);
	if (!file)
	break;
	run_thread(sdcard_romfile_setup, file);
	num_romfiles++;
	}
	if (num_romfiles)
	// only scan for PCI controllers if etc/sdcard not used
	return;

	struct pci_device *pci;
	foreachpci(pci) {
	if (pci->class != PCI_CLASS_SYSTEM_SDHCI \|\| pci->prog_if >= 2)
	// Not an SDHCI controller following SDHCI spec
	continue;
	run_thread(sdcard_pci_setup, pci);
	}
	}