rulimine/common/drivers/disk.s2.c

#include <stdint.h>
#include <stddef.h>
#include <stdalign.h>
#include <drivers/disk.h>
#include <lib/libc.h>
#if bios == 1
#  include <lib/real.h>
#elif uefi == 1
#  include <efi.h>
#endif
#include <lib/blib.h>
#include <lib/print.h>
#include <lib/rand.h>
#include <mm/pmm.h>
#include <sys/cpu.h>

#define DEFAULT_FASTEST_XFER_SIZE 64
#define MAX_FASTEST_XFER_SIZE 512

#define MAX_VOLUMES 64

#if bios == 1

struct bios_drive_params {
    uint16_t buf_size;
    uint16_t info_flags;
    uint32_t cyl;
    uint32_t heads;
    uint32_t sects;
    uint64_t lba_count;
    uint16_t bytes_per_sect;
    uint32_t edd;
} __attribute__((packed));

struct dap {
    uint16_t size;
    uint16_t count;
    uint16_t offset;
    uint16_t segment;
    uint64_t lba;
};

#define XFER_BUF_SIZE (xfer_sizes[SIZEOF_ARRAY(xfer_sizes) - 1] * 512)
static const size_t xfer_sizes[] = { 1, 2, 4, 8, 16, 24, 32, 48, 64 };
static void *xfer_buf = NULL;

static size_t fastest_xfer_size(struct volume *volume) {
    struct dap dap = {0};

    if (xfer_buf == NULL)
        xfer_buf = conv_mem_alloc(XFER_BUF_SIZE);

    size_t fastest_size = 1;
    uint64_t last_speed = (uint64_t)-1;

    for (size_t i = 0; i < SIZEOF_ARRAY(xfer_sizes); i++) {
        if (xfer_sizes[i] * volume->sector_size > XFER_BUF_SIZE) {
            break;
        }

        dap.size    = 16;
        dap.count   = xfer_sizes[i];
        dap.segment = rm_seg(xfer_buf);
        dap.offset  = rm_off(xfer_buf);
        dap.lba     = 0;

        uint64_t start_timestamp = rdtsc();
        for (size_t j = 0; j < XFER_BUF_SIZE / 512; j += xfer_sizes[i]) {
            struct rm_regs r = {0};
            r.eax = 0x4200;
            r.edx = volume->drive;
            r.esi = (uint32_t)rm_off(&dap);
            r.ds  = rm_seg(&dap);
            rm_int(0x13, &r, &r);
            if (r.eflags & EFLAGS_CF) {
                int ah = (r.eax >> 8) & 0xff;
                print("Disk error %x. Drive %x", ah, volume->drive);
                return 8;
            }
            dap.lba += xfer_sizes[i];
        }
        uint64_t end_timestamp = rdtsc();

        uint64_t speed = end_timestamp - start_timestamp;

        if (speed < last_speed) {
            last_speed = speed;
            fastest_size = xfer_sizes[i];
        }
    }

    return fastest_size;
}

int disk_read_sectors(struct volume *volume, void *buf, uint64_t block, size_t count) {
    struct dap dap = {0};

    if (count * volume->sector_size > XFER_BUF_SIZE)
        panic(false, "XFER");

    if (xfer_buf == NULL)
        xfer_buf = conv_mem_alloc(XFER_BUF_SIZE);

    dap.size    = 16;
    dap.count   = count;
    dap.segment = rm_seg(xfer_buf);
    dap.offset  = rm_off(xfer_buf);
    dap.lba     = block;

    struct rm_regs r = {0};
    r.eax = 0x4200;
    r.edx = volume->drive;
    r.esi = (uint32_t)rm_off(&dap);
    r.ds  = rm_seg(&dap);

    rm_int(0x13, &r, &r);

    if (r.eflags & EFLAGS_CF) {
        return DISK_FAILURE;
    }

    if (buf != NULL)
        memcpy(buf, xfer_buf, count * volume->sector_size);

    return DISK_SUCCESS;
}

void disk_create_index(void) {
    volume_index = ext_mem_alloc(sizeof(struct volume) * MAX_VOLUMES);

    int optical_indices = 1, hdd_indices = 1;

    for (uint8_t drive = 0x80; drive < 0xf0; drive++) {
        if (volume_index_i == MAX_VOLUMES) {
            print("WARNING: TOO MANY VOLUMES!");
            break;
        }

        struct rm_regs r = {0};
        struct bios_drive_params drive_params;

        r.eax = 0x4800;
        r.edx = drive;
        r.ds  = rm_seg(&drive_params);
        r.esi = rm_off(&drive_params);

        drive_params.buf_size = sizeof(struct bios_drive_params);

        rm_int(0x13, &r, &r);

        if (r.eflags & EFLAGS_CF)
            continue;

        if (drive_params.bytes_per_sect == 0)
            continue;

        struct volume *block = ext_mem_alloc(sizeof(struct volume));

        block->drive = drive;
        block->partition = 0;
        block->sector_size = drive_params.bytes_per_sect;
        block->first_sect = 0;
        block->sect_count = drive_params.lba_count;
        block->max_partition = -1;

        if (drive_params.info_flags & (1 << 2) && drive > 0x8f) {
            // The medium could not be present (e.g.: CD-ROMs)
            // Do a test run to see if we can actually read it
            if (disk_read_sectors(block, NULL, 0, 1) != DISK_SUCCESS) {
                continue;
            }
            block->index = optical_indices++;
            block->is_optical = true;
        } else {
            block->index = hdd_indices++;
        }

        block->fastest_xfer_size = fastest_xfer_size(block);

        if (gpt_get_guid(&block->guid, block)) {
            block->guid_valid = true;
        }

        volume_index[volume_index_i++] = block;

        for (int part = 0; ; part++) {
            struct volume *p = ext_mem_alloc(sizeof(struct volume));
            int ret = part_get(p, block, part);

            if (ret == END_OF_TABLE || ret == INVALID_TABLE)
                break;
            if (ret == NO_PARTITION)
                continue;

            volume_index[volume_index_i++] = p;

            block->max_partition++;
        }
    }
}

#endif

#if uefi == 1

int disk_read_sectors(struct volume *volume, void *buf, uint64_t block, size_t count) {
    EFI_STATUS status;

    status = volume->block_io->ReadBlocks(volume->block_io,
                               volume->block_io->Media->MediaId,
                               block, count * volume->sector_size, buf);

    switch (status) {
        case EFI_SUCCESS: return DISK_SUCCESS;
        case EFI_NO_MEDIA: return DISK_NO_MEDIA;
        default: return DISK_FAILURE;
    }
}

static alignas(4096) uint8_t unique_sector_pool[4096];

struct volume *disk_volume_from_efi_handle(EFI_HANDLE efi_handle) {
    EFI_STATUS status;

    EFI_GUID block_io_guid = BLOCK_IO_PROTOCOL;
    EFI_BLOCK_IO *block_io = NULL;

    status = gBS->HandleProtocol(efi_handle, &block_io_guid, (void **)&block_io);
    if (status) {
        return NULL;
    }

    for (size_t i = 0; i < volume_index_i; i++) {
        if (volume_index[i]->unique_sector_valid == false) {
            continue;
        }

        if (volume_index[i]->unique_sector % block_io->Media->BlockSize) {
            continue;
        }

        size_t unique_sector = volume_index[i]->unique_sector / block_io->Media->BlockSize;

        status = block_io->ReadBlocks(block_io, block_io->Media->MediaId,
                                      unique_sector,
                                      4096,
                                      unique_sector_pool);
        if (status != 0) {
            continue;
        }

        uint32_t crc32 = get_crc32(unique_sector_pool, 4096);

        if (crc32 == volume_index[i]->unique_sector_crc32) {
            return volume_index[i];
        }
    }

    // Fallback to read-back method

    EFI_GUID disk_io_guid = DISK_IO_PROTOCOL;
    EFI_DISK_IO *disk_io = NULL;

    status = gBS->HandleProtocol(efi_handle, &disk_io_guid, (void **)&disk_io);
    if (status)
        return NULL;

    uint64_t signature = rand64();
    uint64_t new_signature;
    do { new_signature = rand64(); } while (new_signature == signature);
    uint64_t orig;

    status = disk_io->ReadDisk(disk_io, block_io->Media->MediaId, 0, sizeof(uint64_t), &orig);
    if (status) {
        return NULL;
    }

    status = disk_io->WriteDisk(disk_io, block_io->Media->MediaId, 0, sizeof(uint64_t), &signature);
    if (status) {
        return NULL;
    }

    struct volume *ret = NULL;
    for (size_t i = 0; i < volume_index_i; i++) {
        uint64_t compare;

        EFI_DISK_IO *cur_disk_io = NULL;

        gBS->HandleProtocol(volume_index[i]->efi_handle,
                          &disk_io_guid, (void **)&cur_disk_io);

        cur_disk_io->ReadDisk(cur_disk_io,
                          volume_index[i]->block_io->Media->MediaId,
                          0 + volume_index[i]->first_sect * 512,
                          sizeof(uint64_t), &compare);

        if (compare == signature) {
            // Double check
            status = disk_io->WriteDisk(disk_io, block_io->Media->MediaId, 0, sizeof(uint64_t), &new_signature);

            cur_disk_io->ReadDisk(cur_disk_io,
                          volume_index[i]->block_io->Media->MediaId,
                          0 + volume_index[i]->first_sect * 512,
                          sizeof(uint64_t), &compare);

            if (compare == new_signature) {
                ret = volume_index[i];
                break;
            }

            status = disk_io->WriteDisk(disk_io, block_io->Media->MediaId, 0, sizeof(uint64_t), &signature);
        }
    }

    status = disk_io->WriteDisk(disk_io, block_io->Media->MediaId, 0, sizeof(uint64_t), &orig);
    if (status) {
        return NULL;
    }

    if (ret != NULL) {
        return ret;
    }

    return NULL;
}

static struct volume *volume_by_unique_sector(uint64_t sect, uint32_t crc32) {
    for (size_t i = 0; i < volume_index_i; i++) {
        if (volume_index[i]->unique_sector_valid == false) {
            continue;
        }

        if (volume_index[i]->unique_sector == sect
         && volume_index[i]->unique_sector_crc32 == crc32) {
            return volume_index[i];
        }
    }

    return NULL;
}

#define UNIQUE_SECT_MAX_SEARCH_RANGE 0x1000

static void find_unique_sectors(void) {
    EFI_STATUS status;

    for (size_t i = 0; i < volume_index_i; i++) {
        for (size_t j = 0; j < UNIQUE_SECT_MAX_SEARCH_RANGE; j++) {
            if ((volume_index[i]->first_sect * 512) % volume_index[i]->block_io->Media->BlockSize) {
                break;
            }

            size_t first_sect = (volume_index[i]->first_sect * 512) / volume_index[i]->block_io->Media->BlockSize;

            status = volume_index[i]->block_io->ReadBlocks(
                                volume_index[i]->block_io,
                                volume_index[i]->block_io->Media->MediaId,
                                first_sect + j,
                                4096,
                                unique_sector_pool);
            if (status != 0) {
                break;
            }

            uint32_t crc32 = get_crc32(unique_sector_pool, 4096);

            uint64_t uniq = (uint64_t)j * volume_index[i]->block_io->Media->BlockSize;

            if (volume_by_unique_sector(uniq, crc32) == NULL) {
                volume_index[i]->unique_sector_valid = true;
                volume_index[i]->unique_sector = uniq;
                volume_index[i]->unique_sector_crc32 = crc32;
                break;
            }
        }
    }
}

static void find_part_handles(EFI_HANDLE *handles, size_t handle_count) {
    for (size_t i = 0; i < handle_count; i++) {
        struct volume *vol = disk_volume_from_efi_handle(handles[i]);
        if (vol == NULL) {
            continue;
        }
        vol->efi_part_handle = handles[i];
    }
}

void disk_create_index(void) {
    EFI_STATUS status;

    EFI_GUID block_io_guid = BLOCK_IO_PROTOCOL;
    EFI_HANDLE *handles = NULL;
    UINTN handles_size = 0;

    gBS->LocateHandle(ByProtocol, &block_io_guid, NULL, &handles_size, handles);

    handles = ext_mem_alloc(handles_size);

    gBS->LocateHandle(ByProtocol, &block_io_guid, NULL, &handles_size, handles);

    volume_index = ext_mem_alloc(sizeof(struct volume) * MAX_VOLUMES);

    int optical_indices = 1, hdd_indices = 1;

    size_t handle_count = handles_size / sizeof(EFI_HANDLE);

    for (size_t i = 0; i < handle_count; i++) {
        if (volume_index_i == MAX_VOLUMES) {
            print("WARNING: TOO MANY VOLUMES!");
            break;
        }

        EFI_GUID disk_io_guid = DISK_IO_PROTOCOL;
        EFI_DISK_IO *disk_io = NULL;

        gBS->HandleProtocol(handles[i], &disk_io_guid, (void **)&disk_io);

        EFI_BLOCK_IO *drive = NULL;

        status = gBS->HandleProtocol(handles[i], &block_io_guid, (void **)&drive);

        if (status != 0 || drive == NULL || drive->Media->LastBlock == 0)
            continue;

        if (drive->Media->LogicalPartition)
            continue;

        uint64_t orig;
        disk_io->ReadDisk(disk_io, drive->Media->MediaId, 0, sizeof(uint64_t), &orig);
        status = disk_io->WriteDisk(disk_io, drive->Media->MediaId, 0, sizeof(uint64_t), &orig);

        struct volume *block = ext_mem_alloc(sizeof(struct volume));

        if (status) {
            block->index = optical_indices++;
            block->is_optical = true;
        } else {
            block->index = hdd_indices++;
        }

        block->efi_handle = handles[i];
        block->block_io = drive;
        block->partition = 0;
        block->sector_size = drive->Media->BlockSize;
        block->first_sect = 0;
        block->sect_count = drive->Media->LastBlock + 1;
        block->max_partition = -1;

        if (drive->Revision >= EFI_BLOCK_IO_PROTOCOL_REVISION3) {
            block->fastest_xfer_size = drive->Media->OptimalTransferLengthGranularity;
        }

        if (block->fastest_xfer_size == 0) {
            block->fastest_xfer_size = DEFAULT_FASTEST_XFER_SIZE;
        } else if (block->fastest_xfer_size >= MAX_FASTEST_XFER_SIZE) {
            block->fastest_xfer_size = MAX_FASTEST_XFER_SIZE;
        }

        if (gpt_get_guid(&block->guid, block)) {
            block->guid_valid = true;
        }

        volume_index[volume_index_i++] = block;

        for (int part = 0; ; part++) {
            struct volume *p = ext_mem_alloc(sizeof(struct volume));
            int ret = part_get(p, block, part);

            if (ret == END_OF_TABLE || ret == INVALID_TABLE)
                break;
            if (ret == NO_PARTITION)
                continue;

            volume_index[volume_index_i++] = p;

            block->max_partition++;
        }
    }

    find_unique_sectors();
    find_part_handles(handles, handle_count);

    pmm_free(handles, handles_size);
}

#endif