source: mainline/uspace/lib/gpt/libgpt.c@ dc76f4a

/*
 * Copyright (c) 2011, 2012, 2013 Dominik Taborsky
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * - Redistributions of source code must retain the above copyright
 *   notice, this list of conditions and the following disclaimer.
 * - Redistributions in binary form must reproduce the above copyright
 *   notice, this list of conditions and the following disclaimer in the
 *   documentation and/or other materials provided with the distribution.
 * - The name of the author may not be used to endorse or promote products
 *   derived from this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

/** @addtogroup libgpt
 * @{
 */
/** @file
 */

/* TODO:
 * This implementation only supports fixed size partition entries. Specification
 * requires otherwise, though. Use void * array and casting to achieve that.
 */

#include <ipc/bd.h>
#include <async.h>
#include <stdio.h>
#include <block.h>
#include <errno.h>
#include <stdlib.h>
#include <assert.h>
#include <byteorder.h>
#include <checksum.h>
#include <mem.h>

#include "libgpt.h"

static int load_and_check_header(service_id_t, aoff64_t, size_t, gpt_header_t *);
static gpt_partitions_t * alloc_part_array(uint32_t);
static int extend_part_array(gpt_partitions_t *);
static int reduce_part_array(gpt_partitions_t *);
//static long long nearest_larger_int(double);
static uint8_t get_byte(const char *);
static bool check_overlap(gpt_part_t *, gpt_part_t *);

/** Allocate memory for gpt label */
gpt_label_t * gpt_alloc_label(void)
{
        gpt_label_t *label = malloc(sizeof(gpt_label_t));
        if (label == NULL)
                return NULL;
        
        /* This is necessary so that gpt_part_foreach does not segfault */
        label->parts = gpt_alloc_partitions();
        if (label == NULL) {
                free(label);
                return NULL;
        }
        
        label->gpt = NULL;
        
        label->device = 0;
        
        return label;
}

/** Free gpt_label_t structure */
void gpt_free_label(gpt_label_t *label)
{
        if (label->gpt != NULL)
                gpt_free_gpt(label->gpt);
        
        if (label->parts != NULL)
                gpt_free_partitions(label->parts);
        
        free(label);
}

/** Allocate memory for gpt header */
gpt_t * gpt_alloc_header(size_t size)
{
        gpt_t *gpt = malloc(sizeof(gpt_t));
        if (gpt == NULL)
                return NULL;
        
        /* 
         * We might need only sizeof(gpt_header_t), but we should follow 
         * specs and have zeroes through all the rest of the block
         */
        size_t final_size = size > sizeof(gpt_header_t) ? size : sizeof(gpt_header_t);
        gpt->header = malloc(final_size);
        if (gpt->header == NULL) {
                free(gpt);
                return NULL;
        }
        
        memset(gpt->header, 0, final_size);
        
        return gpt;
}

/** free() GPT header including gpt->header_lba */
void gpt_free_gpt(gpt_t *gpt)
{
        free(gpt->header);
        free(gpt);
}

/** Read GPT from specific device
 * @param label        label structure to fill
 * @param dev_handle   device to read GPT from
 *
 * @return             EOK on success, errorcode on error
 */
int gpt_read_header(gpt_label_t *label, service_id_t dev_handle)
{
        int rc;
        size_t b_size;
        
        rc = block_init(EXCHANGE_ATOMIC, dev_handle, 512);
        if (rc != EOK)
                goto fail;
        
        rc = block_get_bsize(dev_handle, &b_size);
        if (rc != EOK)
                goto fini_fail;
        
        if (label->gpt == NULL) {
                label->gpt = gpt_alloc_header(b_size);
                if (label->gpt == NULL) {
                        rc = ENOMEM;
                        goto fini_fail;
                }
        }
        
        rc = load_and_check_header(dev_handle, GPT_HDR_BA, b_size, label->gpt->header);
        if (rc == EBADCHECKSUM || rc == EINVAL) {
                aoff64_t n_blocks;
                rc = block_get_nblocks(dev_handle, &n_blocks);
                if (rc != EOK)
                        goto free_fail;

                rc = load_and_check_header(dev_handle, n_blocks - 1, b_size, label->gpt->header);
                if (rc == EBADCHECKSUM || rc == EINVAL)
                        goto free_fail;
        }
        
        label->device = dev_handle;
        block_fini(dev_handle);
        return EOK;
        
free_fail:
        gpt_free_gpt(label->gpt);
        label->gpt = NULL;
fini_fail:
        block_fini(dev_handle);
fail:
        return rc;
}

/** Write GPT header to device
 * @param label        GPT label header to be written
 * @param dev_handle   device handle to write the data to
 *
 * @return             EOK on success, libblock error code otherwise
 *
 * Note: Firstly write partitions (if modified), then gpt header.
 */
int gpt_write_header(gpt_label_t *label, service_id_t dev_handle)
{
        int rc;
        size_t b_size;
        
        /* The comm_size argument (the last one) is ignored */
        rc = block_init(EXCHANGE_ATOMIC, dev_handle, 4096);
        if (rc != EOK && rc != EEXIST)
                return rc;
        
        rc = block_get_bsize(dev_handle, &b_size);
        if (rc != EOK)
                return rc;
        
        aoff64_t n_blocks;
        rc = block_get_nblocks(dev_handle, &n_blocks);
        if (rc != EOK) {
                block_fini(dev_handle);
                return rc;
        }
        
        uint64_t tmp;
        
        /* Prepare the backup header */
        label->gpt->header->alternate_lba = label->gpt->header->my_lba;
        label->gpt->header->my_lba = host2uint64_t_le(n_blocks - 1);
        
        tmp = label->gpt->header->entry_lba;
        label->gpt->header->entry_lba = host2uint64_t_le(n_blocks - 
            (uint32_t_le2host(label->gpt->header->fillries) * sizeof(gpt_entry_t)) 
            / b_size - 1);
        
        label->gpt->header->header_crc32 = 0;
        label->gpt->header->header_crc32 = host2uint32_t_le( 
            compute_crc32((uint8_t *) label->gpt->header,
                uint32_t_le2host(label->gpt->header->header_size)));
        
        /* Write to backup GPT header location */
        rc = block_write_direct(dev_handle, n_blocks - 1, GPT_HDR_BS, label->gpt->header);
        if (rc != EOK) {
                block_fini(dev_handle);
                return rc;
        }
        
        
        /* Prepare the main header */
        label->gpt->header->entry_lba = tmp;
        
        tmp = label->gpt->header->alternate_lba;
        label->gpt->header->alternate_lba = label->gpt->header->my_lba;
        label->gpt->header->my_lba = tmp;
        
        label->gpt->header->header_crc32 = 0;
        label->gpt->header->header_crc32 = host2uint32_t_le( 
            compute_crc32((uint8_t *) label->gpt->header,
                uint32_t_le2host(label->gpt->header->header_size)));
        
        /* Write to main GPT header location */
        rc = block_write_direct(dev_handle, GPT_HDR_BA, GPT_HDR_BS, label->gpt->header);
        block_fini(dev_handle);
        if (rc != EOK)
                return rc;
        
        
        return 0;
}

/** Alloc partition array */
gpt_partitions_t * gpt_alloc_partitions()
{
        return alloc_part_array(GPT_MIN_PART_NUM);
}

/** Parse partitions from GPT
 * @param label   GPT label to be parsed
 *
 * @return        EOK on success, errorcode otherwise
 */
int gpt_read_partitions(gpt_label_t *label)
{
        int rc;
        unsigned int i;
        uint32_t fillries = uint32_t_le2host(label->gpt->header->fillries);
        uint32_t ent_size = uint32_t_le2host(label->gpt->header->entry_size);
        uint64_t ent_lba = uint64_t_le2host(label->gpt->header->entry_lba);
        
        if (label->parts == NULL) {
                label->parts = alloc_part_array(fillries);
                if (label->parts == NULL) {
                        return ENOMEM;
                }
        }

        /* comm_size is ignored */
        rc = block_init(EXCHANGE_SERIALIZE, label->device, sizeof(gpt_entry_t));
        if (rc != EOK)
                goto fail;

        size_t block_size;
        rc = block_get_bsize(label->device, &block_size);
        if (rc != EOK)
                goto fini_fail;

        //size_t bufpos = 0;
        //size_t buflen = 0;
        aoff64_t pos = ent_lba * block_size;

        /* 
         * Now we read just sizeof(gpt_entry_t) bytes for each entry from the device.
         * Hopefully, this does not bypass cache (no mention in libblock.c),
         * and also allows us to have variable partition entry size (but we
         * will always read just sizeof(gpt_entry_t) bytes - hopefully they
         * don't break backward compatibility) 
         */
        for (i = 0; i < fillries; ++i) {
                /*FIXME: this does bypass cache... */
                rc = block_read_bytes_direct(label->device, pos, sizeof(gpt_entry_t), label->parts->part_array + i);
                /* 
                 * FIXME: but seqread() is just too complex...
                 * rc = block_seqread(gpt->device, &bufpos, &buflen, &pos, res->part_array[i], sizeof(gpt_entry_t));
                 */
                pos += ent_size;

                if (rc != EOK)
                        goto fini_fail;
        }

        /*
         * FIXME: so far my boasting about variable partition entry size
         * will not work. The CRC32 checksums will be different.
         * This can't be fixed easily - we'd have to run the checksum
         * on all of the partition entry array.
         */
        uint32_t crc = compute_crc32((uint8_t *) label->parts->part_array, 
                           fillries * sizeof(gpt_entry_t));

        if(uint32_t_le2host(label->gpt->header->pe_array_crc32) != crc)
        {
                rc = EBADCHECKSUM;
                goto fini_fail;
        }
        
        block_fini(label->device);
        return EOK;
        
fini_fail:
        block_fini(label->device);
        
fail:
        gpt_free_partitions(label->parts);
        label->parts = NULL;
        return rc;
}

/** Write GPT and partitions to device
 * Note: also writes the header.
 * @param label        label to write
 * @param dev_handle   device to write the data to
 *
 * @return             returns EOK on succes, errorcode otherwise
 */
int gpt_write_partitions(gpt_label_t *label, service_id_t dev_handle)
{
        int rc;
        size_t b_size;
        uint32_t e_size = uint32_t_le2host(label->gpt->header->entry_size);
        size_t fillries = label->parts->fill > GPT_MIN_PART_NUM ? label->parts->fill : GPT_MIN_PART_NUM;
        
        label->gpt->header->fillries = host2uint32_t_le(fillries);
        label->gpt->header->pe_array_crc32 = host2uint32_t_le(compute_crc32(
                                       (uint8_t *) label->parts->part_array,
                                       fillries * e_size));
        
        /* comm_size of 4096 is ignored */
        rc = block_init(EXCHANGE_ATOMIC, dev_handle, 4096);
        if (rc != EOK && rc != EEXIST)
                return rc;
        
        rc = block_get_bsize(dev_handle, &b_size);
        if (rc != EOK)
                goto fail;
        
        aoff64_t n_blocks;
        rc = block_get_nblocks(dev_handle, &n_blocks);
        if (rc != EOK)
                goto fail;
        
        uint64_t arr_blocks = (fillries * sizeof(gpt_entry_t)) / b_size;
        label->gpt->header->first_usable_lba = host2uint64_t_le(arr_blocks + 1);
        label->gpt->header->last_usable_lba = host2uint64_t_le(n_blocks - arr_blocks - 2);
        
        
        /* Write to backup GPT partition array location */
        rc = block_write_direct(dev_handle, n_blocks - arr_blocks - 1, 
                 arr_blocks, label->parts->part_array);
        if (rc != EOK)
                goto fail;
        
        /* Write to main GPT partition array location */
        rc = block_write_direct(dev_handle, uint64_t_le2host(label->gpt->header->entry_lba),
                 arr_blocks, label->parts->part_array);
        if (rc != EOK)
                goto fail;
        
        return gpt_write_header(label, dev_handle);
        
fail:
        block_fini(dev_handle);
        return rc;
}

/** Alloc new partition
 *
 * @return        returns pointer to the new partition or NULL
 *
 * Note: use either gpt_alloc_partition or gpt_get_partition.
 * This returns a memory block (zero-filled) and needs gpt_add_partition()
 * to be called to insert it into a partition array.
 * Requires you to call gpt_free_partition afterwards.
 */
gpt_part_t * gpt_alloc_partition(void)
{
        gpt_part_t *p = malloc(sizeof(gpt_part_t));
        if (p == NULL)
                return NULL;
        
        memset(p, 0, sizeof(gpt_part_t));
        
        return p;
}

/** Alloc new partition already inside the label
 *
 * @param label   label to carry new partition
 *
 * @return        returns pointer to the new partition or NULL on ENOMEM
 *
 * Note: use either gpt_alloc_partition or gpt_get_partition.
 * This one returns a pointer to the first empty structure already
 * inside the array, so don't call gpt_add_partition() afterwards.
 * This is the one you will usually want.
 */
gpt_part_t * gpt_get_partition(gpt_label_t *label)
{
        gpt_part_t *p;
        
        
        /* Find the first empty entry */
        do {
                if (label->parts->fill == label->parts->arr_size) {
                        if (extend_part_array(label->parts) == -1)
                                return NULL;
                }
                
                p = label->parts->part_array + label->parts->fill++;
                
        } while (gpt_get_part_type(p) != GPT_PTE_UNUSED);
        
        return p;
}

/** Get partition already inside the label
 *
 * @param label   label to carrying the partition
 * @param idx     index of the partition
 *
 * @return        returns pointer to the partition
 *                or NULL when out of range
 *
 * Note: For new partitions use either gpt_alloc_partition or
 * gpt_get_partition unless you want a partition at a specific place.
 * This returns a pointer to a structure already inside the array,
 * so don't call gpt_add_partition() afterwards.
 * This function is handy when you want to change already existing
 * partition or to simply write somewhere in the middle. This works only
 * for indexes smaller than either 128 or the actual number of filled
 * entries.
 */
gpt_part_t * gpt_get_partition_at(gpt_label_t *label, size_t idx)
{
        return NULL;
        
        if (idx >= GPT_MIN_PART_NUM && idx >= label->parts->fill)
                return NULL;
        
        return label->parts->part_array + idx;
}

/** Copy partition into partition array
 *
 * @param parts                 target label
 * @param partition             source partition to copy
 *
 * @return                              -1 on error, 0 otherwise
 *
 * Note: for use with gpt_alloc_partition() only. You will get
 * duplicates with gpt_get_partition().
 * Note: does not call gpt_free_partition()!
 */
int gpt_add_partition(gpt_label_t *label, gpt_part_t *partition)
{
        /* FIXME: Check dimensions! */
        gpt_part_foreach(label, p) {
                if (gpt_get_part_type(p) != GPT_PTE_UNUSED) {
                        if (check_overlap(partition, p))
                                return EINVAL;
                }
        }
        
        gpt_part_t *p;
        /* Find the first empty entry */
        do {
                if (label->parts->fill == label->parts->arr_size) {
                        if (extend_part_array(label->parts) == -1)
                                return ENOMEM;
                }
                
                p = label->parts->part_array + label->parts->fill++;
                
        } while (gpt_get_part_type(p) != GPT_PTE_UNUSED);
        
        
        memcpy(p, partition, sizeof(gpt_entry_t));
        
        
        return EOK;
}

/** Remove partition from array
 * @param label   label to remove from
 * @param idx     index of the partition to remove
 *
 * @return        EOK on success, ENOMEM on array reduction failure
 *
 * Note: even if it fails, the partition still gets removed. Only
 * reducing the array failed.
 */
int gpt_remove_partition(gpt_label_t *label, size_t idx)
{
        if (idx >= label->parts->arr_size)
                return EINVAL;
        
        /* 
         * FIXME! 
         * If we allow blank spots, we break the array. If we have more than
         * 128 partitions in the array and then remove something from
         * the first 128 partitions, we would forget to write the last one.
         */
        memset(label->parts->part_array + idx, 0, sizeof(gpt_entry_t));
        
        if (label->parts->fill > idx)
                label->parts->fill = idx;
        
        /* 
         * FIXME! HOPEFULLY FIXED.
         * We cannot reduce the array so simply. We may have some partitions
         * there since we allow blank spots. 
         */
        gpt_part_t * p;
        
        if (label->parts->fill > GPT_MIN_PART_NUM &&
            label->parts->fill < (label->parts->arr_size / 2) - GPT_IGNORE_FILL_NUM) {
                for (p = gpt_get_partition_at(label, label->parts->arr_size / 2); 
                     p < label->parts->part_array + label->parts->arr_size; ++p) {
                                if (gpt_get_part_type(p) != GPT_PTE_UNUSED)
                                        return EOK;
                }
                
                if (reduce_part_array(label->parts) == ENOMEM)
                        return ENOMEM;
        }

        return EOK;
}

/** Free partition list
 *
 * @param parts         partition list to be freed
 */
void gpt_free_partitions(gpt_partitions_t * parts)
{
        free(parts->part_array);
        free(parts);
}

/** Get partition type by linear search
 * (hopefully this doesn't get slow)
 */
size_t gpt_get_part_type(gpt_part_t * p)
{
        size_t i;
        
        for (i = 0; gpt_ptypes[i].guid != NULL; i++) {
                if (p->part_type[3] == get_byte(gpt_ptypes[i].guid +0) &&
                        p->part_type[2] == get_byte(gpt_ptypes[i].guid +2) &&
                        p->part_type[1] == get_byte(gpt_ptypes[i].guid +4) &&
                        p->part_type[0] == get_byte(gpt_ptypes[i].guid +6) &&
                        
                        p->part_type[5] == get_byte(gpt_ptypes[i].guid +8) &&
                        p->part_type[4] == get_byte(gpt_ptypes[i].guid +10) &&
                        
                        p->part_type[7] == get_byte(gpt_ptypes[i].guid +12) &&
                        p->part_type[6] == get_byte(gpt_ptypes[i].guid +14) &&
                        
                        p->part_type[8] == get_byte(gpt_ptypes[i].guid +16) &&
                        p->part_type[9] == get_byte(gpt_ptypes[i].guid +18) &&
                        p->part_type[10] == get_byte(gpt_ptypes[i].guid +20) &&
                        p->part_type[11] == get_byte(gpt_ptypes[i].guid +22) &&
                        p->part_type[12] == get_byte(gpt_ptypes[i].guid +24) &&
                        p->part_type[13] == get_byte(gpt_ptypes[i].guid +26) &&
                        p->part_type[14] == get_byte(gpt_ptypes[i].guid +28) &&
                        p->part_type[15] == get_byte(gpt_ptypes[i].guid +30))
                                break;
        }
        
        return i;
}

/** Set partition type
 * @param p                     partition to be set
 * @param type          partition type to set
 *                                      - see our fine selection at gpt_ptypes to choose from
 */
void gpt_set_part_type(gpt_part_t * p, size_t type)
{
        /* Beware: first 3 blocks are byteswapped! */
        p->part_type[3] = gpt_ptypes[type].guid[0];
        p->part_type[2] = gpt_ptypes[type].guid[1];
        p->part_type[1] = gpt_ptypes[type].guid[2];
        p->part_type[0] = gpt_ptypes[type].guid[3];

        p->part_type[5] = gpt_ptypes[type].guid[4];
        p->part_type[4] = gpt_ptypes[type].guid[5];

        p->part_type[7] = gpt_ptypes[type].guid[6];
        p->part_type[6] = gpt_ptypes[type].guid[7];

        p->part_type[8] = gpt_ptypes[type].guid[8];
        p->part_type[9] = gpt_ptypes[type].guid[9];
        p->part_type[10] = gpt_ptypes[type].guid[10];
        p->part_type[11] = gpt_ptypes[type].guid[11];
        p->part_type[12] = gpt_ptypes[type].guid[12];
        p->part_type[13] = gpt_ptypes[type].guid[13];
        p->part_type[14] = gpt_ptypes[type].guid[14];
        p->part_type[15] = gpt_ptypes[type].guid[15];
}

/** Get partition starting LBA */
uint64_t gpt_get_start_lba(gpt_part_t * p)
{
        return uint64_t_le2host(p->start_lba);
}

/** Set partition starting LBA */
void gpt_set_start_lba(gpt_part_t * p, uint64_t start)
{
        p->start_lba = host2uint64_t_le(start);
}

/** Get partition ending LBA */
uint64_t gpt_get_end_lba(gpt_part_t * p)
{
        return uint64_t_le2host(p->end_lba);
}

/** Set partition ending LBA */
void gpt_set_end_lba(gpt_part_t * p, uint64_t end)
{
        p->end_lba = host2uint64_t_le(end);
}

/** Get partition name */
unsigned char * gpt_get_part_name(gpt_part_t * p)
{
        return p->part_name;
}

/** Copy partition name */
void gpt_set_part_name(gpt_part_t *p, char *name, size_t length)
{
        if (length >= 72)
                length = 71;

        memcpy(p->part_name, name, length);
        p->part_name[length] = '\0';
}

/** Get partition attribute */
bool gpt_get_flag(gpt_part_t * p, GPT_ATTR flag)
{
        return (p->attributes & (((uint64_t) 1) << flag)) ? 1 : 0;
}

/** Set partition attribute */
void gpt_set_flag(gpt_part_t * p, GPT_ATTR flag, bool value)
{
        uint64_t attr = p->attributes;

        if (value)
                attr = attr | (((uint64_t) 1) << flag);
        else
                attr = attr ^ (attr & (((uint64_t) 1) << flag));

        p->attributes = attr;
}

/** Generate a new pseudo-random UUID
 * @param uuid Pointer to the UUID to overwrite.
 */
void gpt_set_random_uuid(uint8_t * uuid)
{
        srandom((unsigned int) uuid);
        
        unsigned int i;
        for (i = 0; i < 16/sizeof(long int); ++i)
                ((long int *)uuid)[i] = random();
        
}

/** Get next aligned address */
uint64_t gpt_get_next_aligned(uint64_t addr, unsigned int alignment)
{
        uint64_t div = addr / alignment;
        return (div + 1) * alignment;
}

/* Internal functions follow */

static int load_and_check_header(service_id_t dev_handle, aoff64_t addr, size_t b_size, gpt_header_t * header)
{
        int rc;

        rc = block_read_direct(dev_handle, addr, GPT_HDR_BS, header);
        if (rc != EOK)
                return rc;

        unsigned int i;
        /* Check the EFI signature */
        for (i = 0; i < 8; ++i) {
                if (header->efi_signature[i] != efi_signature[i])
                        return EINVAL;
        }

        /* Check the CRC32 of the header */
        uint32_t crc = header->header_crc32;
        header->header_crc32 = 0;
        if (crc != compute_crc32((uint8_t *) header, header->header_size))
                return EBADCHECKSUM;
        else
                header->header_crc32 = crc;

        /* Check for zeroes in the rest of the block */
        for (i = sizeof(gpt_header_t); i < b_size; ++i) {
                if (((uint8_t *) header)[i] != 0)
                        return EINVAL;
        }

        return EOK;
}

static gpt_partitions_t * alloc_part_array(uint32_t num)
{
        gpt_partitions_t * res = malloc(sizeof(gpt_partitions_t));
        if (res == NULL) {
                errno = ENOMEM;
                return NULL;
        }
        
        uint32_t size = num > GPT_BASE_PART_NUM ? num : GPT_BASE_PART_NUM;
        res->part_array = malloc(size * sizeof(gpt_entry_t));
        if (res->part_array == NULL) {
                free(res);
                errno = ENOMEM;
                return NULL;
        }
        
        memset(res->part_array, 0, size * sizeof(gpt_entry_t));
        
        res->fill = 0;
        res->arr_size = num;

        return res;
}

static int extend_part_array(gpt_partitions_t * p)
{
        size_t nsize = p->arr_size * 2;
        gpt_entry_t * tmp = malloc(nsize * sizeof(gpt_entry_t));
        if(tmp == NULL) {
                errno = ENOMEM;
                return -1;
        }
        
        memcpy(tmp, p->part_array, p->fill * sizeof(gpt_entry_t));
        free(p->part_array);
        p->part_array = tmp;
        p->arr_size = nsize;

        return 0;
}

static int reduce_part_array(gpt_partitions_t * p)
{
        if(p->arr_size > GPT_MIN_PART_NUM) {
                unsigned int nsize = p->arr_size / 2;
                nsize = nsize > GPT_MIN_PART_NUM ? nsize : GPT_MIN_PART_NUM;
                gpt_entry_t * tmp = malloc(nsize * sizeof(gpt_entry_t));
                if(tmp == NULL)
                        return ENOMEM;

                memcpy(tmp, p->part_array, p->fill < nsize ? p->fill : nsize);
                free(p->part_array);
                p->part_array = tmp;
                p->arr_size = nsize;
        }

        return 0;
}

/*static long long nearest_larger_int(double a)
{
        if ((long long) a == a) {
                return (long long) a;
        }

        return ((long long) a) + 1;
}*/

/* Parse a byte from a string in hexadecimal 
 * i.e., "FF" => 255 
 */
static uint8_t get_byte(const char * c)
{
        uint8_t val = 0;
        char hex[3] = {*c, *(c+1), 0};
        
        errno = str_uint8_t(hex, NULL, 16, false, &val);
        return val;
}

static bool check_overlap(gpt_part_t * p1, gpt_part_t * p2)
{
        if (gpt_get_start_lba(p1) < gpt_get_start_lba(p2) && gpt_get_end_lba(p1) <= gpt_get_start_lba(p2)) {
                return false;
        } else if (gpt_get_start_lba(p1) > gpt_get_start_lba(p2) && gpt_get_end_lba(p2) <= gpt_get_start_lba(p1)) {
                return false;
        }

        return true;
}