pcie_imx: increment timeout for link up

[oweals/u-boot.git] / tools / mxsboot.c

/*
 * Freescale i.MX28 image generator
 *
 * Copyright (C) 2011 Marek Vasut <marek.vasut@gmail.com>
 * on behalf of DENX Software Engineering GmbH
 *
 * SPDX-License-Identifier:     GPL-2.0+
 */

#include <fcntl.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <unistd.h>

#include "compiler.h"

/* Taken from <linux/kernel.h> */
#define __round_mask(x, y) ((__typeof__(x))((y)-1))
#define round_down(x, y) ((x) & ~__round_mask(x, y))

/*
 * Default BCB layout.
 *
 * TWEAK this if you have blown any OCOTP fuses.
 */
#define STRIDE_PAGES            64
#define STRIDE_COUNT            4

/*
 * Layout for 256Mb big NAND with 2048b page size, 64b OOB size and
 * 128kb erase size.
 *
 * TWEAK this if you have different kind of NAND chip.
 */
static uint32_t nand_writesize = 2048;
static uint32_t nand_oobsize = 64;
static uint32_t nand_erasesize = 128 * 1024;

/*
 * Sector on which the SigmaTel boot partition (0x53) starts.
 */
static uint32_t sd_sector = 2048;

/*
 * Each of the U-Boot bootstreams is at maximum 1MB big.
 *
 * TWEAK this if, for some wild reason, you need to boot bigger image.
 */
#define MAX_BOOTSTREAM_SIZE     (1 * 1024 * 1024)

/* i.MX28 NAND controller-specific constants. DO NOT TWEAK! */
#define MXS_NAND_DMA_DESCRIPTOR_COUNT           4
#define MXS_NAND_CHUNK_DATA_CHUNK_SIZE          512
#define MXS_NAND_METADATA_SIZE                  10
#define MXS_NAND_BITS_PER_ECC_LEVEL             13
#define MXS_NAND_COMMAND_BUFFER_SIZE            32

struct mx28_nand_fcb {
        uint32_t                checksum;
        uint32_t                fingerprint;
        uint32_t                version;
        struct {
                uint8_t                 data_setup;
                uint8_t                 data_hold;
                uint8_t                 address_setup;
                uint8_t                 dsample_time;
                uint8_t                 nand_timing_state;
                uint8_t                 rea;
                uint8_t                 rloh;
                uint8_t                 rhoh;
        }                       timing;
        uint32_t                page_data_size;
        uint32_t                total_page_size;
        uint32_t                sectors_per_block;
        uint32_t                number_of_nands;                /* Ignored */
        uint32_t                total_internal_die;             /* Ignored */
        uint32_t                cell_type;                      /* Ignored */
        uint32_t                ecc_block_n_ecc_type;
        uint32_t                ecc_block_0_size;
        uint32_t                ecc_block_n_size;
        uint32_t                ecc_block_0_ecc_type;
        uint32_t                metadata_bytes;
        uint32_t                num_ecc_blocks_per_page;
        uint32_t                ecc_block_n_ecc_level_sdk;      /* Ignored */
        uint32_t                ecc_block_0_size_sdk;           /* Ignored */
        uint32_t                ecc_block_n_size_sdk;           /* Ignored */
        uint32_t                ecc_block_0_ecc_level_sdk;      /* Ignored */
        uint32_t                num_ecc_blocks_per_page_sdk;    /* Ignored */
        uint32_t                metadata_bytes_sdk;             /* Ignored */
        uint32_t                erase_threshold;
        uint32_t                boot_patch;
        uint32_t                patch_sectors;
        uint32_t                firmware1_starting_sector;
        uint32_t                firmware2_starting_sector;
        uint32_t                sectors_in_firmware1;
        uint32_t                sectors_in_firmware2;
        uint32_t                dbbt_search_area_start_address;
        uint32_t                badblock_marker_byte;
        uint32_t                badblock_marker_start_bit;
        uint32_t                bb_marker_physical_offset;
};

struct mx28_nand_dbbt {
        uint32_t                checksum;
        uint32_t                fingerprint;
        uint32_t                version;
        uint32_t                number_bb;
        uint32_t                number_2k_pages_bb;
};

struct mx28_nand_bbt {
        uint32_t                nand;
        uint32_t                number_bb;
        uint32_t                badblock[510];
};

struct mx28_sd_drive_info {
        uint32_t                chip_num;
        uint32_t                drive_type;
        uint32_t                tag;
        uint32_t                first_sector_number;
        uint32_t                sector_count;
};

struct mx28_sd_config_block {
        uint32_t                        signature;
        uint32_t                        primary_boot_tag;
        uint32_t                        secondary_boot_tag;
        uint32_t                        num_copies;
        struct mx28_sd_drive_info       drv_info[1];
};

static inline uint32_t mx28_nand_ecc_chunk_cnt(uint32_t page_data_size)
{
        return page_data_size / MXS_NAND_CHUNK_DATA_CHUNK_SIZE;
}

static inline uint32_t mx28_nand_ecc_size_in_bits(uint32_t ecc_strength)
{
        return ecc_strength * MXS_NAND_BITS_PER_ECC_LEVEL;
}

static inline uint32_t mx28_nand_get_ecc_strength(uint32_t page_data_size,
                                                uint32_t page_oob_size)
{
        int ecc_strength;

        /*
         * Determine the ECC layout with the formula:
         *      ECC bits per chunk = (total page spare data bits) /
         *              (bits per ECC level) / (chunks per page)
         * where:
         *      total page spare data bits =
         *              (page oob size - meta data size) * (bits per byte)
         */
        ecc_strength = ((page_oob_size - MXS_NAND_METADATA_SIZE) * 8)
                        / (MXS_NAND_BITS_PER_ECC_LEVEL *
                                mx28_nand_ecc_chunk_cnt(page_data_size));

        return round_down(ecc_strength, 2);
}

static inline uint32_t mx28_nand_get_mark_offset(uint32_t page_data_size,
                                                uint32_t ecc_strength)
{
        uint32_t chunk_data_size_in_bits;
        uint32_t chunk_ecc_size_in_bits;
        uint32_t chunk_total_size_in_bits;
        uint32_t block_mark_chunk_number;
        uint32_t block_mark_chunk_bit_offset;
        uint32_t block_mark_bit_offset;

        chunk_data_size_in_bits = MXS_NAND_CHUNK_DATA_CHUNK_SIZE * 8;
        chunk_ecc_size_in_bits  = mx28_nand_ecc_size_in_bits(ecc_strength);

        chunk_total_size_in_bits =
                        chunk_data_size_in_bits + chunk_ecc_size_in_bits;

        /* Compute the bit offset of the block mark within the physical page. */
        block_mark_bit_offset = page_data_size * 8;

        /* Subtract the metadata bits. */
        block_mark_bit_offset -= MXS_NAND_METADATA_SIZE * 8;

        /*
         * Compute the chunk number (starting at zero) in which the block mark
         * appears.
         */
        block_mark_chunk_number =
                        block_mark_bit_offset / chunk_total_size_in_bits;

        /*
         * Compute the bit offset of the block mark within its chunk, and
         * validate it.
         */
        block_mark_chunk_bit_offset = block_mark_bit_offset -
                        (block_mark_chunk_number * chunk_total_size_in_bits);

        if (block_mark_chunk_bit_offset > chunk_data_size_in_bits)
                return 1;

        /*
         * Now that we know the chunk number in which the block mark appears,
         * we can subtract all the ECC bits that appear before it.
         */
        block_mark_bit_offset -=
                block_mark_chunk_number * chunk_ecc_size_in_bits;

        return block_mark_bit_offset;
}

static inline uint32_t mx28_nand_mark_byte_offset(void)
{
        uint32_t ecc_strength;
        ecc_strength = mx28_nand_get_ecc_strength(nand_writesize, nand_oobsize);
        return mx28_nand_get_mark_offset(nand_writesize, ecc_strength) >> 3;
}

static inline uint32_t mx28_nand_mark_bit_offset(void)
{
        uint32_t ecc_strength;
        ecc_strength = mx28_nand_get_ecc_strength(nand_writesize, nand_oobsize);
        return mx28_nand_get_mark_offset(nand_writesize, ecc_strength) & 0x7;
}

static uint32_t mx28_nand_block_csum(uint8_t *block, uint32_t size)
{
        uint32_t csum = 0;
        int i;

        for (i = 0; i < size; i++)
                csum += block[i];

        return csum ^ 0xffffffff;
}

static struct mx28_nand_fcb *mx28_nand_get_fcb(uint32_t size)
{
        struct mx28_nand_fcb *fcb;
        uint32_t bcb_size_bytes;
        uint32_t stride_size_bytes;
        uint32_t bootstream_size_pages;
        uint32_t fw1_start_page;
        uint32_t fw2_start_page;

        fcb = malloc(nand_writesize);
        if (!fcb) {
                printf("MX28 NAND: Unable to allocate FCB\n");
                return NULL;
        }

        memset(fcb, 0, nand_writesize);

        fcb->fingerprint =                      0x20424346;
        fcb->version =                          0x01000000;

        /*
         * FIXME: These here are default values as found in kobs-ng. We should
         * probably retrieve the data from NAND or something.
         */
        fcb->timing.data_setup =                80;
        fcb->timing.data_hold =                 60;
        fcb->timing.address_setup =             25;
        fcb->timing.dsample_time =              6;

        fcb->page_data_size =           nand_writesize;
        fcb->total_page_size =          nand_writesize + nand_oobsize;
        fcb->sectors_per_block =        nand_erasesize / nand_writesize;

        fcb->num_ecc_blocks_per_page =  (nand_writesize / 512) - 1;
        fcb->ecc_block_0_size =         512;
        fcb->ecc_block_n_size =         512;
        fcb->metadata_bytes =           10;
        fcb->ecc_block_n_ecc_type = mx28_nand_get_ecc_strength(
                                        nand_writesize, nand_oobsize) >> 1;
        fcb->ecc_block_0_ecc_type = mx28_nand_get_ecc_strength(
                                        nand_writesize, nand_oobsize) >> 1;
        if (fcb->ecc_block_n_ecc_type == 0) {
                printf("MX28 NAND: Unsupported NAND geometry\n");
                goto err;
        }

        fcb->boot_patch =                       0;
        fcb->patch_sectors =                    0;

        fcb->badblock_marker_byte =     mx28_nand_mark_byte_offset();
        fcb->badblock_marker_start_bit = mx28_nand_mark_bit_offset();
        fcb->bb_marker_physical_offset = nand_writesize;

        stride_size_bytes = STRIDE_PAGES * nand_writesize;
        bcb_size_bytes = stride_size_bytes * STRIDE_COUNT;

        bootstream_size_pages = (size + (nand_writesize - 1)) /
                                        nand_writesize;

        fw1_start_page = 2 * bcb_size_bytes / nand_writesize;
        fw2_start_page = (2 * bcb_size_bytes + MAX_BOOTSTREAM_SIZE) /
                                nand_writesize;

        fcb->firmware1_starting_sector =        fw1_start_page;
        fcb->firmware2_starting_sector =        fw2_start_page;
        fcb->sectors_in_firmware1 =             bootstream_size_pages;
        fcb->sectors_in_firmware2 =             bootstream_size_pages;

        fcb->dbbt_search_area_start_address =   STRIDE_PAGES * STRIDE_COUNT;

        return fcb;

err:
        free(fcb);
        return NULL;
}

static struct mx28_nand_dbbt *mx28_nand_get_dbbt(void)
{
        struct mx28_nand_dbbt *dbbt;

        dbbt = malloc(nand_writesize);
        if (!dbbt) {
                printf("MX28 NAND: Unable to allocate DBBT\n");
                return NULL;
        }

        memset(dbbt, 0, nand_writesize);

        dbbt->fingerprint       = 0x54424244;
        dbbt->version           = 0x1;

        return dbbt;
}

static inline uint8_t mx28_nand_parity_13_8(const uint8_t b)
{
        uint32_t parity = 0, tmp;

        tmp = ((b >> 6) ^ (b >> 5) ^ (b >> 3) ^ (b >> 2)) & 1;
        parity |= tmp << 0;

        tmp = ((b >> 7) ^ (b >> 5) ^ (b >> 4) ^ (b >> 2) ^ (b >> 1)) & 1;
        parity |= tmp << 1;

        tmp = ((b >> 7) ^ (b >> 6) ^ (b >> 5) ^ (b >> 1) ^ (b >> 0)) & 1;
        parity |= tmp << 2;

        tmp = ((b >> 7) ^ (b >> 4) ^ (b >> 3) ^ (b >> 0)) & 1;
        parity |= tmp << 3;

        tmp = ((b >> 6) ^ (b >> 4) ^ (b >> 3) ^
                (b >> 2) ^ (b >> 1) ^ (b >> 0)) & 1;
        parity |= tmp << 4;

        return parity;
}

static uint8_t *mx28_nand_fcb_block(struct mx28_nand_fcb *fcb)
{
        uint8_t *block;
        uint8_t *ecc;
        int i;

        block = malloc(nand_writesize + nand_oobsize);
        if (!block) {
                printf("MX28 NAND: Unable to allocate FCB block\n");
                return NULL;
        }

        memset(block, 0, nand_writesize + nand_oobsize);

        /* Update the FCB checksum */
        fcb->checksum = mx28_nand_block_csum(((uint8_t *)fcb) + 4, 508);

        /* Figure 12-11. in iMX28RM, rev. 1, says FCB is at offset 12 */
        memcpy(block + 12, fcb, sizeof(struct mx28_nand_fcb));

        /* ECC is at offset 12 + 512 */
        ecc = block + 12 + 512;

        /* Compute the ECC parity */
        for (i = 0; i < sizeof(struct mx28_nand_fcb); i++)
                ecc[i] = mx28_nand_parity_13_8(block[i + 12]);

        return block;
}

static int mx28_nand_write_fcb(struct mx28_nand_fcb *fcb, uint8_t *buf)
{
        uint32_t offset;
        uint8_t *fcbblock;
        int ret = 0;
        int i;

        fcbblock = mx28_nand_fcb_block(fcb);
        if (!fcbblock)
                return -1;

        for (i = 0; i < STRIDE_PAGES * STRIDE_COUNT; i += STRIDE_PAGES) {
                offset = i * nand_writesize;
                memcpy(buf + offset, fcbblock, nand_writesize + nand_oobsize);
                /* Mark the NAND page is OK. */
                buf[offset + nand_writesize] = 0xff;
        }

        free(fcbblock);
        return ret;
}

static int mx28_nand_write_dbbt(struct mx28_nand_dbbt *dbbt, uint8_t *buf)
{
        uint32_t offset;
        int i = STRIDE_PAGES * STRIDE_COUNT;

        for (; i < 2 * STRIDE_PAGES * STRIDE_COUNT; i += STRIDE_PAGES) {
                offset = i * nand_writesize;
                memcpy(buf + offset, dbbt, sizeof(struct mx28_nand_dbbt));
        }

        return 0;
}

static int mx28_nand_write_firmware(struct mx28_nand_fcb *fcb, int infd,
                                    uint8_t *buf)
{
        int ret;
        off_t size;
        uint32_t offset1, offset2;

        size = lseek(infd, 0, SEEK_END);
        lseek(infd, 0, SEEK_SET);

        offset1 = fcb->firmware1_starting_sector * nand_writesize;
        offset2 = fcb->firmware2_starting_sector * nand_writesize;

        ret = read(infd, buf + offset1, size);
        if (ret != size)
                return -1;

        memcpy(buf + offset2, buf + offset1, size);

        return 0;
}

static void usage(void)
{
        printf(
                "Usage: mxsboot [ops] <type> <infile> <outfile>\n"
                "Augment BootStream file with a proper header for i.MX28 boot\n"
                "\n"
                "  <type>       type of image:\n"
                "                 \"nand\" for NAND image\n"
                "                 \"sd\" for SD image\n"
                "  <infile>     input file, the u-boot.sb bootstream\n"
                "  <outfile>    output file, the bootable image\n"
                "\n");
        printf(
                "For NAND boot, these options are accepted:\n"
                "  -w <size>    NAND page size\n"
                "  -o <size>    NAND OOB size\n"
                "  -e <size>    NAND erase size\n"
                "\n"
                "For SD boot, these options are accepted:\n"
                "  -p <sector>  Sector where the SGTL partition starts\n"
        );
}

static int mx28_create_nand_image(int infd, int outfd)
{
        struct mx28_nand_fcb *fcb;
        struct mx28_nand_dbbt *dbbt;
        int ret = -1;
        uint8_t *buf;
        int size;
        ssize_t wr_size;

        size = nand_writesize * 512 + 2 * MAX_BOOTSTREAM_SIZE;

        buf = malloc(size);
        if (!buf) {
                printf("Can not allocate output buffer of %d bytes\n", size);
                goto err0;
        }

        memset(buf, 0, size);

        fcb = mx28_nand_get_fcb(MAX_BOOTSTREAM_SIZE);
        if (!fcb) {
                printf("Unable to compile FCB\n");
                goto err1;
        }

        dbbt = mx28_nand_get_dbbt();
        if (!dbbt) {
                printf("Unable to compile DBBT\n");
                goto err2;
        }

        ret = mx28_nand_write_fcb(fcb, buf);
        if (ret) {
                printf("Unable to write FCB to buffer\n");
                goto err3;
        }

        ret = mx28_nand_write_dbbt(dbbt, buf);
        if (ret) {
                printf("Unable to write DBBT to buffer\n");
                goto err3;
        }

        ret = mx28_nand_write_firmware(fcb, infd, buf);
        if (ret) {
                printf("Unable to write firmware to buffer\n");
                goto err3;
        }

        wr_size = write(outfd, buf, size);
        if (wr_size != size) {
                ret = -1;
                goto err3;
        }

        ret = 0;

err3:
        free(dbbt);
err2:
        free(fcb);
err1:
        free(buf);
err0:
        return ret;
}

static int mx28_create_sd_image(int infd, int outfd)
{
        int ret = -1;
        uint32_t *buf;
        int size;
        off_t fsize;
        ssize_t wr_size;
        struct mx28_sd_config_block *cb;

        fsize = lseek(infd, 0, SEEK_END);
        lseek(infd, 0, SEEK_SET);
        size = fsize + 4 * 512;

        buf = malloc(size);
        if (!buf) {
                printf("Can not allocate output buffer of %d bytes\n", size);
                goto err0;
        }

        ret = read(infd, (uint8_t *)buf + 4 * 512, fsize);
        if (ret != fsize) {
                ret = -1;
                goto err1;
        }

        cb = (struct mx28_sd_config_block *)buf;

        cb->signature = cpu_to_le32(0x00112233);
        cb->primary_boot_tag = cpu_to_le32(0x1);
        cb->secondary_boot_tag = cpu_to_le32(0x1);
        cb->num_copies = cpu_to_le32(1);
        cb->drv_info[0].chip_num = cpu_to_le32(0x0);
        cb->drv_info[0].drive_type = cpu_to_le32(0x0);
        cb->drv_info[0].tag = cpu_to_le32(0x1);
        cb->drv_info[0].first_sector_number = cpu_to_le32(sd_sector + 4);
        cb->drv_info[0].sector_count = cpu_to_le32((size - 4) / 512);

        wr_size = write(outfd, buf, size);
        if (wr_size != size) {
                ret = -1;
                goto err1;
        }

        ret = 0;

err1:
        free(buf);
err0:
        return ret;
}

static int parse_ops(int argc, char **argv)
{
        int i;
        int tmp;
        char *end;
        enum param {
                PARAM_WRITE,
                PARAM_OOB,
                PARAM_ERASE,
                PARAM_PART,
                PARAM_SD,
                PARAM_NAND
        };
        int type;

        if (argc < 4)
                return -1;

        for (i = 1; i < argc; i++) {
                if (!strncmp(argv[i], "-w", 2))
                        type = PARAM_WRITE;
                else if (!strncmp(argv[i], "-o", 2))
                        type = PARAM_OOB;
                else if (!strncmp(argv[i], "-e", 2))
                        type = PARAM_ERASE;
                else if (!strncmp(argv[i], "-p", 2))
                        type = PARAM_PART;
                else    /* SD/MMC */
                        break;

                tmp = strtol(argv[++i], &end, 10);
                if (tmp % 2)
                        return -1;
                if (tmp <= 0)
                        return -1;

                if (type == PARAM_WRITE)
                        nand_writesize = tmp;
                if (type == PARAM_OOB)
                        nand_oobsize = tmp;
                if (type == PARAM_ERASE)
                        nand_erasesize = tmp;
                if (type == PARAM_PART)
                        sd_sector = tmp;
        }

        if (strcmp(argv[i], "sd") && strcmp(argv[i], "nand"))
                return -1;

        if (i + 3 != argc)
                return -1;

        return i;
}

int main(int argc, char **argv)
{
        int infd, outfd;
        int ret = 0;
        int offset;

        offset = parse_ops(argc, argv);
        if (offset < 0) {
                usage();
                ret = 1;
                goto err1;
        }

        infd = open(argv[offset + 1], O_RDONLY);
        if (infd < 0) {
                printf("Input BootStream file can not be opened\n");
                ret = 2;
                goto err1;
        }

        outfd = open(argv[offset + 2], O_CREAT | O_TRUNC | O_WRONLY,
                                        S_IRUSR | S_IWUSR);
        if (outfd < 0) {
                printf("Output file can not be created\n");
                ret = 3;
                goto err2;
        }

        if (!strcmp(argv[offset], "sd"))
                ret = mx28_create_sd_image(infd, outfd);
        else if (!strcmp(argv[offset], "nand"))
                ret = mx28_create_nand_image(infd, outfd);

        close(outfd);
err2:
        close(infd);
err1:
        return ret;
}