part.s2.c 18.1 KB raw

#include <stddef.h>
#include <stdint.h>
#include <lib/part.h>
#include <drivers/disk.h>
#if defined (BIOS)
#  include <lib/real.h>
#endif
#include <lib/libc.h>
#include <lib/misc.h>
#include <lib/print.h>
#include <mm/pmm.h>
#include <fs/file.h>
​
enum {
    CACHE_NOT_READY = 0,
    CACHE_READY
};
​
static bool cache_block(struct volume *volume, uint64_t block) {
    if (volume->cache_status == CACHE_READY && block == volume->cached_block)
        return true;
​
    volume->cache_status = CACHE_NOT_READY;
​
    if (volume->cache == NULL)
        volume->cache =
            ext_mem_alloc(CHECKED_MUL((uint64_t)volume->fastest_xfer_size, (uint64_t)volume->sector_size,
                panic(false, "cache_block: block size overflow")));
​
    if (volume->first_sect % (volume->sector_size / 512)) {
        return false;
    }
​
    uint64_t first_sect = volume->first_sect / (volume->sector_size / 512);
​
    uint64_t xfer_size = volume->fastest_xfer_size;
​
    uint64_t block_offset = CHECKED_MUL(block, (uint64_t)volume->fastest_xfer_size, return false);
    uint64_t read_sector = CHECKED_ADD(first_sect, block_offset, return false);
​
    // Clamp xfer_size to remaining sectors in volume
    if (volume->sect_count != (uint64_t)-1) {
        uint64_t volume_sectors = volume->sect_count / (volume->sector_size / 512);
        uint64_t end_sector;
        if (__builtin_add_overflow(first_sect, volume_sectors, &end_sector)) {
            end_sector = UINT64_MAX;
        }
        if (read_sector >= end_sector) {
            return false;
        }
        uint64_t remaining = end_sector - read_sector;
        if (xfer_size > remaining) {
            xfer_size = remaining;
        }
    }
​
    int ret = disk_read_sectors(volume, volume->cache, read_sector, xfer_size);
    if (ret != DISK_SUCCESS) {
        return false;
    }
​
    volume->cache_status = CACHE_READY;
    volume->cached_block = block;
​
    return true;
}
​
bool volume_read(struct volume *volume, void *buffer, uint64_t loc, uint64_t count) {
    if (volume->pxe) {
        panic(false, "Attempted volume_read() on pxe");
    }
​
    if (volume->sect_count != (uint64_t)-1) {
        // sect_count is always in 512-byte sectors for both whole disks and partitions
        uint64_t part_size = CHECKED_MUL(volume->sect_count, 512, return false);
        if (loc >= part_size || count > part_size - loc) {
            return false;
        }
    }
​
    uint64_t block_size = volume->fastest_xfer_size * volume->sector_size;
​
    uint64_t progress = 0;
    while (progress < count) {
        uint64_t block = (loc + progress) / block_size;
​
        if (!cache_block(volume, block))
            return false;
​
        uint64_t chunk = count - progress;
        uint64_t offset = (loc + progress) % block_size;
        if (chunk > block_size - offset)
            chunk = block_size - offset;
​
        memcpy(buffer + progress, &volume->cache[offset], chunk);
        progress += chunk;
    }
​
    return true;
}
​
static bool partition_range_valid(struct volume *volume,
                                  uint64_t first_sect, uint64_t sect_count) {
    if (sect_count == 0) {
        return false;
    }
​
    uint64_t end_sect = CHECKED_ADD(first_sect, sect_count, return false);
​
    if (volume->sect_count != (uint64_t)-1 && end_sect > volume->sect_count) {
        return false;
    }
​
    return true;
}
​
struct gpt_table_header {
    // the head
    char     signature[8];
    uint32_t revision;
    uint32_t header_size;
    uint32_t crc32;
    uint32_t _reserved0;
​
    // the partitioning info
    uint64_t my_lba;
    uint64_t alternate_lba;
    uint64_t first_usable_lba;
    uint64_t last_usable_lba;
​
    // the guid
    struct guid disk_guid;
​
    // entries related
    uint64_t partition_entry_lba;
    uint32_t number_of_partition_entries;
    uint32_t size_of_partition_entry;
    uint32_t partition_entry_array_crc32;
} __attribute__((packed));
​
struct gpt_entry {
    struct guid partition_type_guid;
​
    struct guid unique_partition_guid;
​
    uint64_t starting_lba;
    uint64_t ending_lba;
​
    uint64_t attributes;
​
    uint16_t partition_name[36];
} __attribute__((packed));
​
bool gpt_get_guid(struct guid *guid, struct volume *volume) {
    struct gpt_table_header header = {0};
​
    int lb_guesses[] = {
        512,
        4096
    };
    int lb_size = -1;
​
    for (size_t i = 0; i < SIZEOF_ARRAY(lb_guesses); i++) {
        // read header, located after the first block
        if (!volume_read(volume, &header, lb_guesses[i] * 1, sizeof(header)))
            continue;
​
        // check the header
        // 'EFI PART'
        if (strncmp(header.signature, "EFI PART", 8))
            continue;
​
        lb_size = lb_guesses[i];
        break;
    }
​
    if (lb_size == -1) {
        return false;
    }
​
    if (header.revision != 0x00010000)
        return false;
​
    *guid = header.disk_guid;
​
    return true;
}
​
static int gpt_get_part(struct volume *ret, struct volume *volume, int partition) {
    struct gpt_table_header header = {0};
​
    int lb_guesses[] = {
        512,
        4096
    };
    int lb_size = -1;
​
    for (size_t i = 0; i < SIZEOF_ARRAY(lb_guesses); i++) {
        // read header, located after the first block
        if (!volume_read(volume, &header, lb_guesses[i] * 1, sizeof(header)))
            continue;
​
        // check the header
        // 'EFI PART'
        if (strncmp(header.signature, "EFI PART", 8))
            continue;
​
        lb_size = lb_guesses[i];
        break;
    }
​
    if (lb_size == -1) {
        return INVALID_TABLE;
    }
​
    if (header.revision != 0x00010000)
        return INVALID_TABLE;
​
    // parse the entries if reached here
    if ((uint32_t)partition >= header.number_of_partition_entries)
        return END_OF_TABLE;
​
    // Validate partition entry size (must be at least as large as our struct)
    uint32_t entry_size = header.size_of_partition_entry;
    if (entry_size < sizeof(struct gpt_entry)) {
        return INVALID_TABLE;
    }
​
    uint64_t entry_offset = CHECKED_MUL(header.partition_entry_lba, lb_size, return INVALID_TABLE);
    // Use actual entry size from header for offset calculation
    uint64_t partition_offset = (uint64_t)partition * entry_size;
    entry_offset = CHECKED_ADD(entry_offset, partition_offset, return INVALID_TABLE);
​
    struct gpt_entry entry = {0};
    if (!volume_read(volume, &entry, entry_offset, sizeof(entry))) {
        return END_OF_TABLE;
    }
​
    struct guid empty_guid = {0};
    if (!memcmp(&entry.unique_partition_guid, &empty_guid, sizeof(struct guid)))
        return NO_PARTITION;
​
    // Validate that ending_lba >= starting_lba to prevent underflow
    if (entry.ending_lba < entry.starting_lba) {
        return NO_PARTITION;  // Invalid partition geometry
    }
​
    // Calculate sector multiplier for lb_size conversion
    uint64_t sect_multiplier = lb_size / 512;
​
    uint64_t first_sect_result = CHECKED_MUL(entry.starting_lba, sect_multiplier, return NO_PARTITION);
​
    // Check for overflow in sect_count calculation
    // First compute partition size in logical blocks
    // Check if +1 would overflow (ending_lba == UINT64_MAX)
    uint64_t partition_size = entry.ending_lba - entry.starting_lba;
    if (partition_size == UINT64_MAX) {
        return NO_PARTITION;  // Partition size +1 would overflow
    }
    uint64_t partition_blocks = partition_size + 1;
    uint64_t sect_count_result = CHECKED_MUL(partition_blocks, sect_multiplier, return NO_PARTITION);
​
    if (!partition_range_valid(volume, first_sect_result, sect_count_result)) {
        return NO_PARTITION;
    }
​
#if defined (UEFI)
    ret->efi_handle  = volume->efi_handle;
    ret->block_io    = volume->block_io;
#elif defined (BIOS)
    ret->drive       = volume->drive;
#endif
    ret->fastest_xfer_size = volume->fastest_xfer_size;
    ret->index       = volume->index;
    ret->is_optical  = volume->is_optical;
    ret->partition   = partition + 1;
    ret->sector_size = volume->sector_size;
    ret->first_sect  = first_sect_result;
    ret->sect_count  = sect_count_result;
    ret->backing_dev = volume;
​
    struct guid guid;
    if (!fs_get_guid(&guid, ret)) {
        ret->guid_valid = false;
    } else {
        ret->guid_valid = true;
        ret->guid = guid;
    }
​
    char *fslabel = fs_get_label(ret);
    if (fslabel == NULL) {
        ret->fslabel_valid = false;
    } else {
        ret->fslabel_valid = true;
        ret->fslabel = fslabel;
    }
​
    ret->part_guid_valid = true;
    ret->part_guid = entry.unique_partition_guid;
​
    return 0;
}
​
struct mbr_entry {
	uint8_t status;
	uint8_t chs_first_sect[3];
	uint8_t type;
	uint8_t chs_last_sect[3];
	uint32_t first_sect;
	uint32_t sect_count;
} __attribute__((packed));
​
bool is_valid_mbr(struct volume *volume) {
    // Check if actually valid mbr
    uint16_t hint = 0;
​
    if (!volume_read(volume, &hint, 446, sizeof(uint8_t)))
        return false;
    if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
        return false;
    if (!volume_read(volume, &hint, 462, sizeof(uint8_t)))
        return false;
    if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
        return false;
    if (!volume_read(volume, &hint, 478, sizeof(uint8_t)))
        return false;
    if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
        return false;
    if (!volume_read(volume, &hint, 494, sizeof(uint8_t)))
        return false;
    if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
        return false;
​
    char hintc[64];
    if (!volume_read(volume, hintc, 3, 4))
        return false;
    if (memcmp(hintc, "NTFS", 4) == 0)
        return false;
    if (!volume_read(volume, hintc, 54, 3))
        return false;
    if (memcmp(hintc, "FAT", 3) == 0)
        return false;
    if (!volume_read(volume, hintc, 82, 3))
        return false;
    if (memcmp(hintc, "FAT", 3) == 0)
        return false;
    if (!volume_read(volume, hintc, 3, 5))
        return false;
    if (memcmp(hintc, "FAT32", 5) == 0)
        return false;
    if (!volume_read(volume, &hint, 1080, sizeof(uint16_t)))
        return false;
    if (hint == 0xef53)
        return false;
​
    return true;
}
​
uint32_t mbr_get_id(struct volume *volume) {
    if (!is_valid_mbr(volume)) {
        return 0;
    }
​
    uint32_t ret;
    if (!volume_read(volume, &ret, 0x1b8, sizeof(uint32_t))) {
        return 0;
    }
​
    return ret;
}
​
// Maximum number of logical partitions to prevent infinite loops from circular EBR chains
#define MAX_LOGICAL_PARTITIONS 256
​
static int mbr_get_logical_part(struct volume *ret, struct volume *extended_part,
                                int partition) {
    struct mbr_entry entry;
​
    // Limit partition index to prevent excessive iteration
    if (partition >= MAX_LOGICAL_PARTITIONS) {
        return END_OF_TABLE;
    }
​
    uint64_t ebr_sector = 0;
    uint64_t prev_ebr_sector = 0;
​
    for (int i = 0; i < partition; i++) {
        uint64_t entry_offset = ebr_sector * 512 + 0x1ce;
​
        if (!volume_read(extended_part, &entry, entry_offset, sizeof(struct mbr_entry))) {
            return END_OF_TABLE;
        }
​
        if (entry.type != 0x0f && entry.type != 0x05) {
            return END_OF_TABLE;
        }
​
        prev_ebr_sector = ebr_sector;
        ebr_sector = entry.first_sect;
​
        // Detect circular chain: if new sector points to 0 or backwards, it's invalid
        // (EBR sectors should always increase within the extended partition)
        if (ebr_sector == 0 || (i > 0 && ebr_sector <= prev_ebr_sector)) {
            return END_OF_TABLE;  // Circular or corrupted EBR chain
        }
​
        // Also check that ebr_sector is within the extended partition bounds
        if (ebr_sector >= extended_part->sect_count) {
            return END_OF_TABLE;  // EBR points outside extended partition
        }
    }
​
    uint64_t entry_offset = ebr_sector * 512 + 0x1be;
​
    if (!volume_read(extended_part, &entry, entry_offset, sizeof(struct mbr_entry))) {
        return END_OF_TABLE;
    }
​
    if (entry.type == 0)
        return NO_PARTITION;
​
    // Validate sect_count is non-zero
    if (entry.sect_count == 0) {
        return NO_PARTITION;
    }
​
    uint64_t logical_rel_first = CHECKED_ADD(ebr_sector, entry.first_sect, return NO_PARTITION);
    if (!partition_range_valid(extended_part, logical_rel_first, entry.sect_count)) {
        return NO_PARTITION;
    }
​
    uint64_t first_sect_64 = CHECKED_ADD(extended_part->first_sect, logical_rel_first, return NO_PARTITION);
    if (!partition_range_valid(extended_part->backing_dev, first_sect_64, entry.sect_count)) {
        return NO_PARTITION;
    }
​
#if defined (UEFI)
    ret->efi_handle  = extended_part->efi_handle;
    ret->block_io    = extended_part->block_io;
#elif defined (BIOS)
    ret->drive       = extended_part->drive;
#endif
    ret->fastest_xfer_size = extended_part->fastest_xfer_size;
    ret->index       = extended_part->index;
    ret->is_optical  = extended_part->is_optical;
    ret->partition   = partition + 4 + 1;
    ret->sector_size = extended_part->sector_size;
    ret->first_sect  = first_sect_64;
    ret->sect_count  = entry.sect_count;
    ret->backing_dev = extended_part->backing_dev;
​
    struct guid guid;
    if (!fs_get_guid(&guid, ret)) {
        ret->guid_valid = false;
    } else {
        ret->guid_valid = true;
        ret->guid = guid;
    }
​
    char *fslabel = fs_get_label(ret);
    if (fslabel == NULL) {
        ret->fslabel_valid = false;
    } else {
        ret->fslabel_valid = true;
        ret->fslabel = fslabel;
    }
​
    ret->part_guid_valid = false;
​
    return 0;
}
​
static int mbr_get_part(struct volume *ret, struct volume *volume, int partition) {
    if (!is_valid_mbr(volume)) {
        return INVALID_TABLE;
    }
​
    struct mbr_entry entry;
​
    if (partition > 3) {
        for (int i = 0; i < 4; i++) {
            uint64_t entry_offset = 0x1be + sizeof(struct mbr_entry) * i;
​
            if (!volume_read(volume, &entry, entry_offset, sizeof(struct mbr_entry))) {
                continue;
            }
​
            if (entry.type != 0x0f && entry.type != 0x05)
                continue;
​
            // Validate extended partition has non-zero size
            if (entry.sect_count == 0) {
                continue;
            }
​
            if (!partition_range_valid(volume, entry.first_sect, entry.sect_count)) {
                continue;
            }
​
            struct volume extended_part = {0};
​
#if defined (UEFI)
            extended_part.efi_handle  = volume->efi_handle;
            extended_part.block_io    = volume->block_io;
#elif defined (BIOS)
            extended_part.drive       = volume->drive;
#endif
            extended_part.fastest_xfer_size = volume->fastest_xfer_size;
            extended_part.index       = volume->index;
            extended_part.is_optical  = volume->is_optical;
            extended_part.partition   = i + 1;
            extended_part.sector_size = volume->sector_size;
            extended_part.first_sect  = entry.first_sect;
            extended_part.sect_count  = entry.sect_count;
            extended_part.backing_dev = volume;
​
            return mbr_get_logical_part(ret, &extended_part, partition - 4);
        }
​
        return END_OF_TABLE;
    }
​
    uint64_t entry_offset = 0x1be + sizeof(struct mbr_entry) * partition;
​
    if (!volume_read(volume, &entry, entry_offset, sizeof(struct mbr_entry))) {
        return END_OF_TABLE;
    }
​
    if (entry.type == 0)
        return NO_PARTITION;
​
    // Validate sect_count is non-zero
    if (entry.sect_count == 0) {
        return NO_PARTITION;
    }
​
    if (!partition_range_valid(volume, entry.first_sect, entry.sect_count)) {
        return NO_PARTITION;
    }
​
#if defined (UEFI)
    ret->efi_handle  = volume->efi_handle;
    ret->block_io    = volume->block_io;
#elif defined (BIOS)
    ret->drive       = volume->drive;
#endif
    ret->fastest_xfer_size = volume->fastest_xfer_size;
    ret->index       = volume->index;
    ret->is_optical  = volume->is_optical;
    ret->partition   = partition + 1;
    ret->sector_size = volume->sector_size;
    ret->first_sect  = entry.first_sect;
    ret->sect_count  = entry.sect_count;
    ret->backing_dev = volume;
​
    struct guid guid;
    if (!fs_get_guid(&guid, ret)) {
        ret->guid_valid = false;
    } else {
        ret->guid_valid = true;
        ret->guid = guid;
    }
​
    char *fslabel = fs_get_label(ret);
    if (fslabel == NULL) {
        ret->fslabel_valid = false;
    } else {
        ret->fslabel_valid = true;
        ret->fslabel = fslabel;
    }
​
    ret->part_guid_valid = false;
​
    return 0;
}
​
int part_get(struct volume *part, struct volume *volume, int partition) {
    int ret;
​
    // Validate partition index is non-negative
    if (partition < 0) {
        return NO_PARTITION;
    }
​
    ret = gpt_get_part(part, volume, partition);
    if (ret != INVALID_TABLE)
        return ret;
​
    ret = mbr_get_part(part, volume, partition);
    if (ret != INVALID_TABLE)
        return ret;
​
    return INVALID_TABLE;
}
​
struct volume **volume_index = NULL;
size_t volume_index_i = 0;
​
struct volume *volume_get_by_guid(struct guid *guid) {
    for (size_t i = 0; i < volume_index_i; i++) {
        if (volume_index[i]->guid_valid
         && memcmp(&volume_index[i]->guid, guid, 16) == 0) {
            return volume_index[i];
        }
        if (volume_index[i]->part_guid_valid
         && memcmp(&volume_index[i]->part_guid, guid, 16) == 0) {
            return volume_index[i];
        }
    }
​
    return NULL;
}
​
struct volume *volume_get_by_fslabel(char *fslabel) {
    for (size_t i = 0; i < volume_index_i; i++) {
        if (volume_index[i]->fslabel_valid
         && strcmp(volume_index[i]->fslabel, fslabel) == 0) {
            return volume_index[i];
        }
    }
​
    return NULL;
}
​
struct volume *volume_get_by_coord(bool optical, int drive, int partition) {
    for (size_t i = 0; i < volume_index_i; i++) {
        if (volume_index[i]->index == drive
         && volume_index[i]->is_optical == optical
         && volume_index[i]->partition == partition) {
            return volume_index[i];
        }
    }
​
    return NULL;
}
​
#if defined (BIOS)
struct volume *volume_get_by_bios_drive(int drive) {
    for (size_t i = 0; i < volume_index_i; i++) {
        if (volume_index[i]->drive == drive) {
            return volume_index[i];
        }
    }
​
    return NULL;
}
#endif

tab: 2 4 8 wrap: off on

1	#include <stddef.h>
2	#include <stdint.h>
3	#include <lib/part.h>
4	#include <drivers/disk.h>
5	#if defined (BIOS)
6	# include <lib/real.h>
7	#endif
8	#include <lib/libc.h>
9	#include <lib/misc.h>
10	#include <lib/print.h>
11	#include <mm/pmm.h>
12	#include <fs/file.h>
13
14	enum {
15	CACHE_NOT_READY = 0,
16	CACHE_READY
17	};
18
19	static bool cache_block(struct volume *volume, uint64_t block) {
20	if (volume->cache_status == CACHE_READY && block == volume->cached_block)
21	return true;
22
23	volume->cache_status = CACHE_NOT_READY;
24
25	if (volume->cache == NULL)
26	volume->cache =
27	ext_mem_alloc(CHECKED_MUL((uint64_t)volume->fastest_xfer_size, (uint64_t)volume->sector_size,
28	panic(false, "cache_block: block size overflow")));
29
30	if (volume->first_sect % (volume->sector_size / 512)) {
31	return false;
32	}
33
34	uint64_t first_sect = volume->first_sect / (volume->sector_size / 512);
35
36	uint64_t xfer_size = volume->fastest_xfer_size;
37
38	uint64_t block_offset = CHECKED_MUL(block, (uint64_t)volume->fastest_xfer_size, return false);
39	uint64_t read_sector = CHECKED_ADD(first_sect, block_offset, return false);
40
41	// Clamp xfer_size to remaining sectors in volume
42	if (volume->sect_count != (uint64_t)-1) {
43	uint64_t volume_sectors = volume->sect_count / (volume->sector_size / 512);
44	uint64_t end_sector;
45	if (__builtin_add_overflow(first_sect, volume_sectors, &end_sector)) {
46	end_sector = UINT64_MAX;
47	}
48	if (read_sector >= end_sector) {
49	return false;
50	}
51	uint64_t remaining = end_sector - read_sector;
52	if (xfer_size > remaining) {
53	xfer_size = remaining;
54	}
55	}
56
57	int ret = disk_read_sectors(volume, volume->cache, read_sector, xfer_size);
58	if (ret != DISK_SUCCESS) {
59	return false;
60	}
61
62	volume->cache_status = CACHE_READY;
63	volume->cached_block = block;
64
65	return true;
66	}
67
68	bool volume_read(struct volume volume, void buffer, uint64_t loc, uint64_t count) {
69	if (volume->pxe) {
70	panic(false, "Attempted volume_read() on pxe");
71	}
72
73	if (volume->sect_count != (uint64_t)-1) {
74	// sect_count is always in 512-byte sectors for both whole disks and partitions
75	uint64_t part_size = CHECKED_MUL(volume->sect_count, 512, return false);
76	if (loc >= part_size \|\| count > part_size - loc) {
77	return false;
78	}
79	}
80
81	uint64_t block_size = volume->fastest_xfer_size * volume->sector_size;
82
83	uint64_t progress = 0;
84	while (progress < count) {
85	uint64_t block = (loc + progress) / block_size;
86
87	if (!cache_block(volume, block))
88	return false;
89
90	uint64_t chunk = count - progress;
91	uint64_t offset = (loc + progress) % block_size;
92	if (chunk > block_size - offset)
93	chunk = block_size - offset;
94
95	memcpy(buffer + progress, &volume->cache[offset], chunk);
96	progress += chunk;
97	}
98
99	return true;
100	}
101
102	static bool partition_range_valid(struct volume *volume,
103	uint64_t first_sect, uint64_t sect_count) {
104	if (sect_count == 0) {
105	return false;
106	}
107
108	uint64_t end_sect = CHECKED_ADD(first_sect, sect_count, return false);
109
110	if (volume->sect_count != (uint64_t)-1 && end_sect > volume->sect_count) {
111	return false;
112	}
113
114	return true;
115	}
116
117	struct gpt_table_header {
118	// the head
119	char signature[8];
120	uint32_t revision;
121	uint32_t header_size;
122	uint32_t crc32;
123	uint32_t _reserved0;
124
125	// the partitioning info
126	uint64_t my_lba;
127	uint64_t alternate_lba;
128	uint64_t first_usable_lba;
129	uint64_t last_usable_lba;
130
131	// the guid
132	struct guid disk_guid;
133
134	// entries related
135	uint64_t partition_entry_lba;
136	uint32_t number_of_partition_entries;
137	uint32_t size_of_partition_entry;
138	uint32_t partition_entry_array_crc32;
139	} __attribute__((packed));
140
141	struct gpt_entry {
142	struct guid partition_type_guid;
143
144	struct guid unique_partition_guid;
145
146	uint64_t starting_lba;
147	uint64_t ending_lba;
148
149	uint64_t attributes;
150
151	uint16_t partition_name[36];
152	} __attribute__((packed));
153
154	bool gpt_get_guid(struct guid guid, struct volume volume) {
155	struct gpt_table_header header = {0};
156
157	int lb_guesses[] = {
158	512,
159	4096
160	};
161	int lb_size = -1;
162
163	for (size_t i = 0; i < SIZEOF_ARRAY(lb_guesses); i++) {
164	// read header, located after the first block
165	if (!volume_read(volume, &header, lb_guesses[i] * 1, sizeof(header)))
166	continue;
167
168	// check the header
169	// 'EFI PART'
170	if (strncmp(header.signature, "EFI PART", 8))
171	continue;
172
173	lb_size = lb_guesses[i];
174	break;
175	}
176
177	if (lb_size == -1) {
178	return false;
179	}
180
181	if (header.revision != 0x00010000)
182	return false;
183
184	*guid = header.disk_guid;
185
186	return true;
187	}
188
189	static int gpt_get_part(struct volume ret, struct volume volume, int partition) {
190	struct gpt_table_header header = {0};
191
192	int lb_guesses[] = {
193	512,
194	4096
195	};
196	int lb_size = -1;
197
198	for (size_t i = 0; i < SIZEOF_ARRAY(lb_guesses); i++) {
199	// read header, located after the first block
200	if (!volume_read(volume, &header, lb_guesses[i] * 1, sizeof(header)))
201	continue;
202
203	// check the header
204	// 'EFI PART'
205	if (strncmp(header.signature, "EFI PART", 8))
206	continue;
207
208	lb_size = lb_guesses[i];
209	break;
210	}
211
212	if (lb_size == -1) {
213	return INVALID_TABLE;
214	}
215
216	if (header.revision != 0x00010000)
217	return INVALID_TABLE;
218
219	// parse the entries if reached here
220	if ((uint32_t)partition >= header.number_of_partition_entries)
221	return END_OF_TABLE;
222
223	// Validate partition entry size (must be at least as large as our struct)
224	uint32_t entry_size = header.size_of_partition_entry;
225	if (entry_size < sizeof(struct gpt_entry)) {
226	return INVALID_TABLE;
227	}
228
229	uint64_t entry_offset = CHECKED_MUL(header.partition_entry_lba, lb_size, return INVALID_TABLE);
230	// Use actual entry size from header for offset calculation
231	uint64_t partition_offset = (uint64_t)partition * entry_size;
232	entry_offset = CHECKED_ADD(entry_offset, partition_offset, return INVALID_TABLE);
233
234	struct gpt_entry entry = {0};
235	if (!volume_read(volume, &entry, entry_offset, sizeof(entry))) {
236	return END_OF_TABLE;
237	}
238
239	struct guid empty_guid = {0};
240	if (!memcmp(&entry.unique_partition_guid, &empty_guid, sizeof(struct guid)))
241	return NO_PARTITION;
242
243	// Validate that ending_lba >= starting_lba to prevent underflow
244	if (entry.ending_lba < entry.starting_lba) {
245	return NO_PARTITION; // Invalid partition geometry
246	}
247
248	// Calculate sector multiplier for lb_size conversion
249	uint64_t sect_multiplier = lb_size / 512;
250
251	uint64_t first_sect_result = CHECKED_MUL(entry.starting_lba, sect_multiplier, return NO_PARTITION);
252
253	// Check for overflow in sect_count calculation
254	// First compute partition size in logical blocks
255	// Check if +1 would overflow (ending_lba == UINT64_MAX)
256	uint64_t partition_size = entry.ending_lba - entry.starting_lba;
257	if (partition_size == UINT64_MAX) {
258	return NO_PARTITION; // Partition size +1 would overflow
259	}
260	uint64_t partition_blocks = partition_size + 1;
261	uint64_t sect_count_result = CHECKED_MUL(partition_blocks, sect_multiplier, return NO_PARTITION);
262
263	if (!partition_range_valid(volume, first_sect_result, sect_count_result)) {
264	return NO_PARTITION;
265	}
266
267	#if defined (UEFI)
268	ret->efi_handle = volume->efi_handle;
269	ret->block_io = volume->block_io;
270	#elif defined (BIOS)
271	ret->drive = volume->drive;
272	#endif
273	ret->fastest_xfer_size = volume->fastest_xfer_size;
274	ret->index = volume->index;
275	ret->is_optical = volume->is_optical;
276	ret->partition = partition + 1;
277	ret->sector_size = volume->sector_size;
278	ret->first_sect = first_sect_result;
279	ret->sect_count = sect_count_result;
280	ret->backing_dev = volume;
281
282	struct guid guid;
283	if (!fs_get_guid(&guid, ret)) {
284	ret->guid_valid = false;
285	} else {
286	ret->guid_valid = true;
287	ret->guid = guid;
288	}
289
290	char *fslabel = fs_get_label(ret);
291	if (fslabel == NULL) {
292	ret->fslabel_valid = false;
293	} else {
294	ret->fslabel_valid = true;
295	ret->fslabel = fslabel;
296	}
297
298	ret->part_guid_valid = true;
299	ret->part_guid = entry.unique_partition_guid;
300
301	return 0;
302	}
303
304	struct mbr_entry {
305	uint8_t status;
306	uint8_t chs_first_sect[3];
307	uint8_t type;
308	uint8_t chs_last_sect[3];
309	uint32_t first_sect;
310	uint32_t sect_count;
311	} __attribute__((packed));
312
313	bool is_valid_mbr(struct volume *volume) {
314	// Check if actually valid mbr
315	uint16_t hint = 0;
316
317	if (!volume_read(volume, &hint, 446, sizeof(uint8_t)))
318	return false;
319	if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
320	return false;
321	if (!volume_read(volume, &hint, 462, sizeof(uint8_t)))
322	return false;
323	if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
324	return false;
325	if (!volume_read(volume, &hint, 478, sizeof(uint8_t)))
326	return false;
327	if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
328	return false;
329	if (!volume_read(volume, &hint, 494, sizeof(uint8_t)))
330	return false;
331	if ((uint8_t)hint != 0x00 && (uint8_t)hint != 0x80)
332	return false;
333
334	char hintc[64];
335	if (!volume_read(volume, hintc, 3, 4))
336	return false;
337	if (memcmp(hintc, "NTFS", 4) == 0)
338	return false;
339	if (!volume_read(volume, hintc, 54, 3))
340	return false;
341	if (memcmp(hintc, "FAT", 3) == 0)
342	return false;
343	if (!volume_read(volume, hintc, 82, 3))
344	return false;
345	if (memcmp(hintc, "FAT", 3) == 0)
346	return false;
347	if (!volume_read(volume, hintc, 3, 5))
348	return false;
349	if (memcmp(hintc, "FAT32", 5) == 0)
350	return false;
351	if (!volume_read(volume, &hint, 1080, sizeof(uint16_t)))
352	return false;
353	if (hint == 0xef53)
354	return false;
355
356	return true;
357	}
358
359	uint32_t mbr_get_id(struct volume *volume) {
360	if (!is_valid_mbr(volume)) {
361	return 0;
362	}
363
364	uint32_t ret;
365	if (!volume_read(volume, &ret, 0x1b8, sizeof(uint32_t))) {
366	return 0;
367	}
368
369	return ret;
370	}
371
372	// Maximum number of logical partitions to prevent infinite loops from circular EBR chains
373	#define MAX_LOGICAL_PARTITIONS 256
374
375	static int mbr_get_logical_part(struct volume ret, struct volume extended_part,
376	int partition) {
377	struct mbr_entry entry;
378
379	// Limit partition index to prevent excessive iteration
380	if (partition >= MAX_LOGICAL_PARTITIONS) {
381	return END_OF_TABLE;
382	}
383
384	uint64_t ebr_sector = 0;
385	uint64_t prev_ebr_sector = 0;
386
387	for (int i = 0; i < partition; i++) {
388	uint64_t entry_offset = ebr_sector * 512 + 0x1ce;
389
390	if (!volume_read(extended_part, &entry, entry_offset, sizeof(struct mbr_entry))) {
391	return END_OF_TABLE;
392	}
393
394	if (entry.type != 0x0f && entry.type != 0x05) {
395	return END_OF_TABLE;
396	}
397
398	prev_ebr_sector = ebr_sector;
399	ebr_sector = entry.first_sect;
400
401	// Detect circular chain: if new sector points to 0 or backwards, it's invalid
402	// (EBR sectors should always increase within the extended partition)
403	if (ebr_sector == 0 \|\| (i > 0 && ebr_sector <= prev_ebr_sector)) {
404	return END_OF_TABLE; // Circular or corrupted EBR chain
405	}
406
407	// Also check that ebr_sector is within the extended partition bounds
408	if (ebr_sector >= extended_part->sect_count) {
409	return END_OF_TABLE; // EBR points outside extended partition
410	}
411	}
412
413	uint64_t entry_offset = ebr_sector * 512 + 0x1be;
414
415	if (!volume_read(extended_part, &entry, entry_offset, sizeof(struct mbr_entry))) {
416	return END_OF_TABLE;
417	}
418
419	if (entry.type == 0)
420	return NO_PARTITION;
421
422	// Validate sect_count is non-zero
423	if (entry.sect_count == 0) {
424	return NO_PARTITION;
425	}
426
427	uint64_t logical_rel_first = CHECKED_ADD(ebr_sector, entry.first_sect, return NO_PARTITION);
428	if (!partition_range_valid(extended_part, logical_rel_first, entry.sect_count)) {
429	return NO_PARTITION;
430	}
431
432	uint64_t first_sect_64 = CHECKED_ADD(extended_part->first_sect, logical_rel_first, return NO_PARTITION);
433	if (!partition_range_valid(extended_part->backing_dev, first_sect_64, entry.sect_count)) {
434	return NO_PARTITION;
435	}
436
437	#if defined (UEFI)
438	ret->efi_handle = extended_part->efi_handle;
439	ret->block_io = extended_part->block_io;
440	#elif defined (BIOS)
441	ret->drive = extended_part->drive;
442	#endif
443	ret->fastest_xfer_size = extended_part->fastest_xfer_size;
444	ret->index = extended_part->index;
445	ret->is_optical = extended_part->is_optical;
446	ret->partition = partition + 4 + 1;
447	ret->sector_size = extended_part->sector_size;
448	ret->first_sect = first_sect_64;
449	ret->sect_count = entry.sect_count;
450	ret->backing_dev = extended_part->backing_dev;
451
452	struct guid guid;
453	if (!fs_get_guid(&guid, ret)) {
454	ret->guid_valid = false;
455	} else {
456	ret->guid_valid = true;
457	ret->guid = guid;
458	}
459
460	char *fslabel = fs_get_label(ret);
461	if (fslabel == NULL) {
462	ret->fslabel_valid = false;
463	} else {
464	ret->fslabel_valid = true;
465	ret->fslabel = fslabel;
466	}
467
468	ret->part_guid_valid = false;
469
470	return 0;
471	}
472
473	static int mbr_get_part(struct volume ret, struct volume volume, int partition) {
474	if (!is_valid_mbr(volume)) {
475	return INVALID_TABLE;
476	}
477
478	struct mbr_entry entry;
479
480	if (partition > 3) {
481	for (int i = 0; i < 4; i++) {
482	uint64_t entry_offset = 0x1be + sizeof(struct mbr_entry) * i;
483
484	if (!volume_read(volume, &entry, entry_offset, sizeof(struct mbr_entry))) {
485	continue;
486	}
487
488	if (entry.type != 0x0f && entry.type != 0x05)
489	continue;
490
491	// Validate extended partition has non-zero size
492	if (entry.sect_count == 0) {
493	continue;
494	}
495
496	if (!partition_range_valid(volume, entry.first_sect, entry.sect_count)) {
497	continue;
498	}
499
500	struct volume extended_part = {0};
501
502	#if defined (UEFI)
503	extended_part.efi_handle = volume->efi_handle;
504	extended_part.block_io = volume->block_io;
505	#elif defined (BIOS)
506	extended_part.drive = volume->drive;
507	#endif
508	extended_part.fastest_xfer_size = volume->fastest_xfer_size;
509	extended_part.index = volume->index;
510	extended_part.is_optical = volume->is_optical;
511	extended_part.partition = i + 1;
512	extended_part.sector_size = volume->sector_size;
513	extended_part.first_sect = entry.first_sect;
514	extended_part.sect_count = entry.sect_count;
515	extended_part.backing_dev = volume;
516
517	return mbr_get_logical_part(ret, &extended_part, partition - 4);
518	}
519
520	return END_OF_TABLE;
521	}
522
523	uint64_t entry_offset = 0x1be + sizeof(struct mbr_entry) * partition;
524
525	if (!volume_read(volume, &entry, entry_offset, sizeof(struct mbr_entry))) {
526	return END_OF_TABLE;
527	}
528
529	if (entry.type == 0)
530	return NO_PARTITION;
531
532	// Validate sect_count is non-zero
533	if (entry.sect_count == 0) {
534	return NO_PARTITION;
535	}
536
537	if (!partition_range_valid(volume, entry.first_sect, entry.sect_count)) {
538	return NO_PARTITION;
539	}
540
541	#if defined (UEFI)
542	ret->efi_handle = volume->efi_handle;
543	ret->block_io = volume->block_io;
544	#elif defined (BIOS)
545	ret->drive = volume->drive;
546	#endif
547	ret->fastest_xfer_size = volume->fastest_xfer_size;
548	ret->index = volume->index;
549	ret->is_optical = volume->is_optical;
550	ret->partition = partition + 1;
551	ret->sector_size = volume->sector_size;
552	ret->first_sect = entry.first_sect;
553	ret->sect_count = entry.sect_count;
554	ret->backing_dev = volume;
555
556	struct guid guid;
557	if (!fs_get_guid(&guid, ret)) {
558	ret->guid_valid = false;
559	} else {
560	ret->guid_valid = true;
561	ret->guid = guid;
562	}
563
564	char *fslabel = fs_get_label(ret);
565	if (fslabel == NULL) {
566	ret->fslabel_valid = false;
567	} else {
568	ret->fslabel_valid = true;
569	ret->fslabel = fslabel;
570	}
571
572	ret->part_guid_valid = false;
573
574	return 0;
575	}
576
577	int part_get(struct volume part, struct volume volume, int partition) {
578	int ret;
579
580	// Validate partition index is non-negative
581	if (partition < 0) {
582	return NO_PARTITION;
583	}
584
585	ret = gpt_get_part(part, volume, partition);
586	if (ret != INVALID_TABLE)
587	return ret;
588
589	ret = mbr_get_part(part, volume, partition);
590	if (ret != INVALID_TABLE)
591	return ret;
592
593	return INVALID_TABLE;
594	}
595
596	struct volume **volume_index = NULL;
597	size_t volume_index_i = 0;
598
599	struct volume volume_get_by_guid(struct guid guid) {
600	for (size_t i = 0; i < volume_index_i; i++) {
601	if (volume_index[i]->guid_valid
602	&& memcmp(&volume_index[i]->guid, guid, 16) == 0) {
603	return volume_index[i];
604	}
605	if (volume_index[i]->part_guid_valid
606	&& memcmp(&volume_index[i]->part_guid, guid, 16) == 0) {
607	return volume_index[i];
608	}
609	}
610
611	return NULL;
612	}
613
614	struct volume volume_get_by_fslabel(char fslabel) {
615	for (size_t i = 0; i < volume_index_i; i++) {
616	if (volume_index[i]->fslabel_valid
617	&& strcmp(volume_index[i]->fslabel, fslabel) == 0) {
618	return volume_index[i];
619	}
620	}
621
622	return NULL;
623	}
624
625	struct volume *volume_get_by_coord(bool optical, int drive, int partition) {
626	for (size_t i = 0; i < volume_index_i; i++) {
627	if (volume_index[i]->index == drive
628	&& volume_index[i]->is_optical == optical
629	&& volume_index[i]->partition == partition) {
630	return volume_index[i];
631	}
632	}
633
634	return NULL;
635	}
636
637	#if defined (BIOS)
638	struct volume *volume_get_by_bios_drive(int drive) {
639	for (size_t i = 0; i < volume_index_i; i++) {
640	if (volume_index[i]->drive == drive) {
641	return volume_index[i];
642	}
643	}
644
645	return NULL;
646	}
647	#endif