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cos / mirrors / cros / chromiumos / platform / vboot_reference / refs/heads/firmware-gandof-6301.155.B / . / tests / cgptlib_test.c
blob: 21334a57c52485ccc5f3c8f51abeffdb95dc8079 [file] [log] [blame]
/* Copyright (c) 2013 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include <errno.h>
#include <string.h>
#include "../cgpt/cgpt.h"
#include "../cgpt/flash_ts.h"
#include "cgptlib_internal.h"
#include "cgptlib_test.h"
#include "crc32.h"
#include "crc32_test.h"
#include "gpt.h"
#include "mtdlib.h"
#include "mtdlib_unused.h"
#include "test_common.h"
#define _STUB_IMPLEMENTATION_
#include "utility.h"
/*
* Testing partition layout (sector_bytes=512)
*
* LBA Size Usage
* ---------------------------------------------------------
* 0 1 PMBR
* 1 1 primary partition header
* 2 32 primary partition entries (128B * 128)
* 34 100 kernel A (index: 0)
* 134 100 root A (index: 1)
* 234 100 root B (index: 2)
* 334 100 kernel B (index: 3)
* 434 32 secondary partition entries
* 466 1 secondary partition header
* 467
*/
#define KERNEL_A 0
#define KERNEL_B 1
#define ROOTFS_A 2
#define ROOTFS_B 3
#define KERNEL_X 2 /* Overload ROOTFS_A, for some GetNext tests */
#define KERNEL_Y 3 /* Overload ROOTFS_B, for some GetNext tests */
#define DEFAULT_SECTOR_SIZE 512
#define MAX_SECTOR_SIZE 4096
#define DEFAULT_DRIVE_SECTORS 467
#define PARTITION_ENTRIES_SIZE TOTAL_ENTRIES_SIZE /* 16384 */
static const Guid guid_zero = {{{0, 0, 0, 0, 0, {0, 0, 0, 0, 0, 0}}}};
static const Guid guid_kernel = GPT_ENT_TYPE_CHROMEOS_KERNEL;
static const Guid guid_rootfs = GPT_ENT_TYPE_CHROMEOS_ROOTFS;
// cgpt_common.c requires these be defined if linked in.
const char *progname = "CGPT-TEST";
const char *command = "TEST";
// Ramdisk for flash ts testing.
static uint8_t *nand_drive = NULL;
static uint32_t nand_drive_sz;
static uint8_t *nand_bad_block_map = NULL;
/*
* Copy a random-for-this-program-only Guid into the dest. The num parameter
* completely determines the Guid.
*/
static void SetGuid(void *dest, uint32_t num)
{
Guid g = {{{num,0xd450,0x44bc,0xa6,0x93,
{0xb8,0xac,0x75,0x5f,0xcd,0x48}}}};
Memcpy(dest, &g, sizeof(Guid));
}
/*
* Given a GptData pointer, first re-calculate entries CRC32 value, then reset
* header CRC32 value to 0, and calculate header CRC32 value. Both primary and
* secondary are updated.
*/
static void RefreshCrc32(GptData *gpt)
{
GptHeader *header, *header2;
GptEntry *entries, *entries2;
header = (GptHeader *)gpt->primary_header;
entries = (GptEntry *)gpt->primary_entries;
header2 = (GptHeader *)gpt->secondary_header;
entries2 = (GptEntry *)gpt->secondary_entries;
header->entries_crc32 =
Crc32((uint8_t *)entries,
header->number_of_entries * header->size_of_entry);
header->header_crc32 = 0;
header->header_crc32 = Crc32((uint8_t *)header, header->size);
header2->entries_crc32 =
Crc32((uint8_t *)entries2,
header2->number_of_entries * header2->size_of_entry);
header2->header_crc32 = 0;
header2->header_crc32 = Crc32((uint8_t *)header2, header2->size);
}
static void ZeroHeaders(GptData *gpt)
{
Memset(gpt->primary_header, 0, MAX_SECTOR_SIZE);
Memset(gpt->secondary_header, 0, MAX_SECTOR_SIZE);
}
static void ZeroEntries(GptData *gpt)
{
Memset(gpt->primary_entries, 0, PARTITION_ENTRIES_SIZE);
Memset(gpt->secondary_entries, 0, PARTITION_ENTRIES_SIZE);
}
static void ZeroHeadersEntries(GptData *gpt)
{
ZeroHeaders(gpt);
ZeroEntries(gpt);
}
/*
* Return a pointer to a static GptData instance (no free is required).
* All fields are zero except 4 pointers linking to header and entries.
* All content of headers and entries are zero.
*/
static GptData *GetEmptyGptData(void)
{
static GptData gpt;
static uint8_t primary_header[MAX_SECTOR_SIZE];
static uint8_t primary_entries[PARTITION_ENTRIES_SIZE];
static uint8_t secondary_header[MAX_SECTOR_SIZE];
static uint8_t secondary_entries[PARTITION_ENTRIES_SIZE];
Memset(&gpt, 0, sizeof(gpt));
gpt.primary_header = primary_header;
gpt.primary_entries = primary_entries;
gpt.secondary_header = secondary_header;
gpt.secondary_entries = secondary_entries;
ZeroHeadersEntries(&gpt);
/* Initialize GptData internal states. */
gpt.current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
return &gpt;
}
static MtdData *GetEmptyMtdData() {
static MtdData mtd;
Memset(&mtd, 0, sizeof(mtd));
mtd.current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
return &mtd;
}
/*
* Fill in most of fields and creates the layout described in the top of this
* file. Before calling this function, primary/secondary header/entries must
* have been pointed to the buffer, say, a gpt returned from GetEmptyGptData().
* This function returns a good (valid) copy of GPT layout described in top of
* this file.
*/
static void BuildTestGptData(GptData *gpt)
{
GptHeader *header, *header2;
GptEntry *entries, *entries2;
Guid chromeos_kernel = GPT_ENT_TYPE_CHROMEOS_KERNEL;
Guid chromeos_rootfs = GPT_ENT_TYPE_CHROMEOS_ROOTFS;
gpt->sector_bytes = DEFAULT_SECTOR_SIZE;
gpt->drive_sectors = DEFAULT_DRIVE_SECTORS;
gpt->current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
gpt->valid_headers = MASK_BOTH;
gpt->valid_entries = MASK_BOTH;
gpt->modified = 0;
/* Build primary */
header = (GptHeader *)gpt->primary_header;
entries = (GptEntry *)gpt->primary_entries;
Memcpy(header->signature, GPT_HEADER_SIGNATURE,
sizeof(GPT_HEADER_SIGNATURE));
header->revision = GPT_HEADER_REVISION;
header->size = sizeof(GptHeader);
header->reserved_zero = 0;
header->my_lba = 1;
header->alternate_lba = DEFAULT_DRIVE_SECTORS - 1;
header->first_usable_lba = 34;
header->last_usable_lba = DEFAULT_DRIVE_SECTORS - 1 - 32 - 1; /* 433 */
header->entries_lba = 2;
/* 512B / 128B * 32sectors = 128 entries */
header->number_of_entries = 128;
header->size_of_entry = 128; /* bytes */
Memcpy(&entries[0].type, &chromeos_kernel, sizeof(chromeos_kernel));
SetGuid(&entries[0].unique, 0);
entries[0].starting_lba = 34;
entries[0].ending_lba = 133;
Memcpy(&entries[1].type, &chromeos_rootfs, sizeof(chromeos_rootfs));
SetGuid(&entries[1].unique, 1);
entries[1].starting_lba = 134;
entries[1].ending_lba = 232;
Memcpy(&entries[2].type, &chromeos_rootfs, sizeof(chromeos_rootfs));
SetGuid(&entries[2].unique, 2);
entries[2].starting_lba = 234;
entries[2].ending_lba = 331;
Memcpy(&entries[3].type, &chromeos_kernel, sizeof(chromeos_kernel));
SetGuid(&entries[3].unique, 3);
entries[3].starting_lba = 334;
entries[3].ending_lba = 430;
/* Build secondary */
header2 = (GptHeader *)gpt->secondary_header;
entries2 = (GptEntry *)gpt->secondary_entries;
Memcpy(header2, header, sizeof(GptHeader));
Memcpy(entries2, entries, PARTITION_ENTRIES_SIZE);
header2->my_lba = DEFAULT_DRIVE_SECTORS - 1; /* 466 */
header2->alternate_lba = 1;
header2->entries_lba = DEFAULT_DRIVE_SECTORS - 1 - 32; /* 434 */
RefreshCrc32(gpt);
}
static void BuildTestMtdData(MtdData *mtd) {
MtdDiskPartition *partitions;
mtd->sector_bytes = DEFAULT_SECTOR_SIZE;
mtd->drive_sectors = DEFAULT_DRIVE_SECTORS;
mtd->current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
mtd->modified = 0;
Memset(&mtd->primary, 0, sizeof(mtd->primary));
Memcpy(mtd->primary.signature, MTD_DRIVE_SIGNATURE,
sizeof(mtd->primary.signature));
mtd->primary.first_offset = 32 * DEFAULT_SECTOR_SIZE;
mtd->primary.last_offset = DEFAULT_DRIVE_SECTORS * DEFAULT_SECTOR_SIZE - 1;
mtd->primary.size = MTD_DRIVE_V1_SIZE;
/* These values are not used directly by the library, but they are checked */
mtd->flash_page_bytes = mtd->sector_bytes * 8;
mtd->flash_block_bytes = mtd->flash_page_bytes * 8;
mtd->fts_block_offset = 1;
mtd->fts_block_size = 1;
partitions = &mtd->primary.partitions[0];
partitions[0].starting_offset = 34 * DEFAULT_SECTOR_SIZE;
partitions[0].ending_offset = 134 * DEFAULT_SECTOR_SIZE - 1;
partitions[0].flags =
MTD_PARTITION_TYPE_CHROMEOS_KERNEL << MTD_ATTRIBUTE_TYPE_OFFSET;
partitions[1].starting_offset = 134 * DEFAULT_SECTOR_SIZE;
partitions[1].ending_offset = 233 * DEFAULT_SECTOR_SIZE - 1;
partitions[1].flags =
MTD_PARTITION_TYPE_CHROMEOS_ROOTFS << MTD_ATTRIBUTE_TYPE_OFFSET;
partitions[2].starting_offset = 234 * DEFAULT_SECTOR_SIZE;
partitions[2].ending_offset = 332 * DEFAULT_SECTOR_SIZE - 1;
partitions[2].flags =
MTD_PARTITION_TYPE_CHROMEOS_KERNEL << MTD_ATTRIBUTE_TYPE_OFFSET;
partitions[3].starting_offset = 334 * DEFAULT_SECTOR_SIZE;
partitions[3].ending_offset = 431 * DEFAULT_SECTOR_SIZE - 1;
partitions[3].flags =
MTD_PARTITION_TYPE_CHROMEOS_ROOTFS << MTD_ATTRIBUTE_TYPE_OFFSET;
mtd->primary.crc32 = 0;
mtd->primary.crc32 = Crc32(&mtd->primary, MTD_DRIVE_V1_SIZE);
}
/*
* Test if the structures are the expected size; if this fails, struct packing
* is not working properly.
*/
static int StructSizeTest(void)
{
EXPECT(GUID_EXPECTED_SIZE == sizeof(Guid));
EXPECT(GPTHEADER_EXPECTED_SIZE == sizeof(GptHeader));
EXPECT(GPTENTRY_EXPECTED_SIZE == sizeof(GptEntry));
EXPECT(MTDENTRY_EXPECTED_SIZE == sizeof(MtdDiskPartition));
EXPECT(MTDLAYOUT_EXPECTED_SIZE == sizeof(MtdDiskLayout));
return TEST_OK;
}
/* Test if the default structure returned by BuildTestGptData() is good. */
static int TestBuildTestGptData(void)
{
GptData *gpt;
gpt = GetEmptyGptData();
BuildTestGptData(gpt);
EXPECT(GPT_SUCCESS == GptInit(gpt));
gpt->sector_bytes = 0;
EXPECT(GPT_ERROR_INVALID_SECTOR_SIZE == GptInit(gpt));
return TEST_OK;
}
static int TestBuildTestMtdData() {
MtdData *mtd = GetEmptyMtdData();
BuildTestMtdData(mtd);
EXPECT(GPT_SUCCESS == MtdInit(mtd));
return TEST_OK;
}
/*
* Test if wrong sector_bytes or drive_sectors is detected by GptInit().
* Currently we only support 512 bytes per sector. In the future, we may
* support other sizes. A too small drive_sectors should be rejected by
* GptInit().
* For MtdInit(), additionally test various flash geometries to verify
* that only valid ones are accepted.
*/
static int ParameterTests(void)
{
GptData *gpt;
MtdData *mtd;
struct {
uint32_t sector_bytes;
uint64_t drive_sectors;
int expected_retval;
} cases[] = {
{512, DEFAULT_DRIVE_SECTORS, GPT_SUCCESS},
{520, DEFAULT_DRIVE_SECTORS, GPT_ERROR_INVALID_SECTOR_SIZE},
{512, 0, GPT_ERROR_INVALID_SECTOR_NUMBER},
{512, 66, GPT_ERROR_INVALID_SECTOR_NUMBER},
{512, GPT_PMBR_SECTORS + GPT_HEADER_SECTORS * 2 +
GPT_ENTRIES_SECTORS * 2, GPT_SUCCESS},
{4096, DEFAULT_DRIVE_SECTORS, GPT_ERROR_INVALID_SECTOR_SIZE},
};
struct {
uint32_t sector_bytes;
uint32_t drive_sectors;
uint32_t flash_page_bytes;
uint32_t flash_block_bytes;
int expected_retval;
} mtdcases[] = {
{512, DEFAULT_DRIVE_SECTORS, 8*512,
8*512, GPT_SUCCESS},
{510, DEFAULT_DRIVE_SECTORS, 8*512,
8*512, GPT_ERROR_INVALID_SECTOR_SIZE},
{512, DEFAULT_DRIVE_SECTORS, 8*512,
8*512, GPT_SUCCESS},
{512, DEFAULT_DRIVE_SECTORS, 512,
8*512, GPT_SUCCESS},
{512, DEFAULT_DRIVE_SECTORS, 8*512,
10*512, GPT_ERROR_INVALID_FLASH_GEOMETRY},
{512, DEFAULT_DRIVE_SECTORS, 3*512,
9*512, GPT_SUCCESS},
{512, DEFAULT_DRIVE_SECTORS, 8*512,
6*512, GPT_ERROR_INVALID_FLASH_GEOMETRY},
{512, DEFAULT_DRIVE_SECTORS, 256,
6*512, GPT_ERROR_INVALID_FLASH_GEOMETRY},
{512, DEFAULT_DRIVE_SECTORS, 512,
6*512 + 256, GPT_ERROR_INVALID_FLASH_GEOMETRY},
};
int i;
gpt = GetEmptyGptData();
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
gpt->sector_bytes = cases[i].sector_bytes;
gpt->drive_sectors = cases[i].drive_sectors;
EXPECT(cases[i].expected_retval == CheckParameters(gpt));
}
mtd = GetEmptyMtdData();
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestMtdData(mtd);
mtd->sector_bytes = mtdcases[i].sector_bytes;
mtd->drive_sectors = mtdcases[i].drive_sectors;
mtd->flash_block_bytes = mtdcases[i].flash_block_bytes;
mtd->flash_page_bytes = mtdcases[i].flash_page_bytes;
if(mtdcases[i].expected_retval != MtdCheckParameters(mtd)) {
printf("i=%d\n",i);
}
EXPECT(mtdcases[i].expected_retval == MtdCheckParameters(mtd));
}
return TEST_OK;
}
/* Test if header CRC in two copies are calculated. */
static int HeaderCrcTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
BuildTestGptData(gpt);
EXPECT(HeaderCrc(h1) == h1->header_crc32);
/* CRC covers first byte of header */
BuildTestGptData(gpt);
gpt->primary_header[0] ^= 0xa5;
EXPECT(HeaderCrc(h1) != h1->header_crc32);
/* CRC covers last byte of header */
BuildTestGptData(gpt);
gpt->primary_header[h1->size - 1] ^= 0x5a;
EXPECT(HeaderCrc(h1) != h1->header_crc32);
/* CRC only covers header */
BuildTestGptData(gpt);
gpt->primary_header[h1->size] ^= 0x5a;
EXPECT(HeaderCrc(h1) == h1->header_crc32);
return TEST_OK;
}
/* Test if header-same comparison works. */
static int HeaderSameTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
GptHeader h3;
EXPECT(0 == HeaderFieldsSame(h1, h2));
Memcpy(&h3, h2, sizeof(h3));
h3.signature[0] ^= 0xba;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.revision++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.size++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.reserved_zero++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.first_usable_lba++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.last_usable_lba++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.disk_uuid.u.raw[0] ^= 0xba;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.number_of_entries++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.size_of_entry++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
Memcpy(&h3, h2, sizeof(h3));
h3.entries_crc32++;
EXPECT(1 == HeaderFieldsSame(h1, &h3));
return TEST_OK;
}
/* Test if signature ("EFI PART") is checked. */
static int SignatureTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
int i;
EXPECT(1 == CheckHeader(NULL, 0, gpt->drive_sectors));
for (i = 0; i < 8; ++i) {
BuildTestGptData(gpt);
h1->signature[i] ^= 0xff;
h2->signature[i] ^= 0xff;
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
}
return TEST_OK;
}
/*
* The revision we currently support is GPT_HEADER_REVISION. If the revision
* in header is not that, we expect the header is invalid.
*/
static int RevisionTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
int i;
struct {
uint32_t value_to_test;
int expect_rv;
} cases[] = {
{0x01000000, 1},
{0x00010000, 0}, /* GPT_HEADER_REVISION */
{0x00000100, 1},
{0x00000001, 1},
{0x23010456, 1},
};
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
h1->revision = cases[i].value_to_test;
h2->revision = cases[i].value_to_test;
RefreshCrc32(gpt);
EXPECT(CheckHeader(h1, 0, gpt->drive_sectors) ==
cases[i].expect_rv);
EXPECT(CheckHeader(h2, 1, gpt->drive_sectors) ==
cases[i].expect_rv);
}
return TEST_OK;
}
static int SizeTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
int i;
struct {
uint32_t value_to_test;
int expect_rv;
} cases[] = {
{91, 1},
{92, 0},
{93, 0},
{511, 0},
{512, 0},
{513, 1},
};
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
h1->size = cases[i].value_to_test;
h2->size = cases[i].value_to_test;
RefreshCrc32(gpt);
EXPECT(CheckHeader(h1, 0, gpt->drive_sectors) ==
cases[i].expect_rv);
EXPECT(CheckHeader(h2, 1, gpt->drive_sectors) ==
cases[i].expect_rv);
}
return TEST_OK;
}
/* Test if CRC is checked. */
static int CrcFieldTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
BuildTestGptData(gpt);
/* Modify a field that the header verification doesn't care about */
h1->entries_crc32++;
h2->entries_crc32++;
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
/* Refresh the CRC; should pass now */
RefreshCrc32(gpt);
EXPECT(0 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(0 == CheckHeader(h2, 1, gpt->drive_sectors));
return TEST_OK;
}
/* Test if reserved fields are checked. We'll try non-zero values to test. */
static int ReservedFieldsTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
BuildTestGptData(gpt);
h1->reserved_zero ^= 0x12345678; /* whatever random */
h2->reserved_zero ^= 0x12345678; /* whatever random */
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
#ifdef PADDING_CHECKED
/* TODO: padding check is currently disabled */
BuildTestGptData(gpt);
h1->padding[12] ^= 0x34; /* whatever random */
h2->padding[56] ^= 0x78; /* whatever random */
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
#endif
return TEST_OK;
}
/*
* Technically, any size which is 2^N where N > 6 should work, but our
* library only supports one size.
*/
static int SizeOfPartitionEntryTest(void) {
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
int i;
struct {
uint32_t value_to_test;
int expect_rv;
} cases[] = {
{127, 1},
{128, 0},
{129, 1},
{256, 1},
{512, 1},
};
/* Check size of entryes */
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
h1->size_of_entry = cases[i].value_to_test;
h2->size_of_entry = cases[i].value_to_test;
h1->number_of_entries = TOTAL_ENTRIES_SIZE /
cases[i].value_to_test;
h2->number_of_entries = TOTAL_ENTRIES_SIZE /
cases[i].value_to_test;
RefreshCrc32(gpt);
EXPECT(CheckHeader(h1, 0, gpt->drive_sectors) ==
cases[i].expect_rv);
EXPECT(CheckHeader(h2, 1, gpt->drive_sectors) ==
cases[i].expect_rv);
}
return TEST_OK;
}
/*
* Technically, any size which is 2^N where N > 6 should work, but our library
* only supports one size.
*/
static int NumberOfPartitionEntriesTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
BuildTestGptData(gpt);
h1->number_of_entries--;
h2->number_of_entries /= 2;
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
return TEST_OK;
}
/* Test if myLBA field is checked (1 for primary, last for secondary). */
static int MyLbaTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
/* myLBA depends on primary vs secondary flag */
BuildTestGptData(gpt);
EXPECT(1 == CheckHeader(h1, 1, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 0, gpt->drive_sectors));
BuildTestGptData(gpt);
h1->my_lba--;
h2->my_lba--;
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
BuildTestGptData(gpt);
h1->my_lba = 2;
h2->my_lba--;
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
/* We should ignore the alternate_lba field entirely */
BuildTestGptData(gpt);
h1->alternate_lba++;
h2->alternate_lba++;
RefreshCrc32(gpt);
EXPECT(0 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(0 == CheckHeader(h2, 1, gpt->drive_sectors));
BuildTestGptData(gpt);
h1->alternate_lba--;
h2->alternate_lba--;
RefreshCrc32(gpt);
EXPECT(0 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(0 == CheckHeader(h2, 1, gpt->drive_sectors));
BuildTestGptData(gpt);
h1->entries_lba++;
h2->entries_lba++;
RefreshCrc32(gpt);
/*
* We support a padding between primary GPT header and its entries. So
* this still passes.
*/
EXPECT(0 == CheckHeader(h1, 0, gpt->drive_sectors));
/*
* But the secondary table should fail because it would overlap the
* header, which is now lying after its entry array.
*/
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
BuildTestGptData(gpt);
h1->entries_lba--;
h2->entries_lba--;
RefreshCrc32(gpt);
EXPECT(1 == CheckHeader(h1, 0, gpt->drive_sectors));
EXPECT(1 == CheckHeader(h2, 1, gpt->drive_sectors));
return TEST_OK;
}
/* Test if FirstUsableLBA and LastUsableLBA are checked.
* FirstUsableLBA must be after the end of the primary GPT table array.
* LastUsableLBA must be before the start of the secondary GPT table array.
* FirstUsableLBA <= LastUsableLBA. */
static int FirstUsableLbaAndLastUsableLbaTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptHeader *h2 = (GptHeader *)gpt->secondary_header;
int i;
struct {
uint64_t primary_entries_lba;
uint64_t primary_first_usable_lba;
uint64_t primary_last_usable_lba;
uint64_t secondary_first_usable_lba;
uint64_t secondary_last_usable_lba;
uint64_t secondary_entries_lba;
int primary_rv;
int secondary_rv;
} cases[] = {
{2, 34, 433, 34, 433, 434, 0, 0},
{2, 34, 432, 34, 430, 434, 0, 0},
{2, 33, 433, 33, 433, 434, 1, 1},
{2, 34, 434, 34, 433, 434, 1, 0},
{2, 34, 433, 34, 434, 434, 0, 1},
{2, 35, 433, 35, 433, 434, 0, 0},
{2, 433, 433, 433, 433, 434, 0, 0},
{2, 434, 433, 434, 434, 434, 1, 1},
{2, 433, 34, 34, 433, 434, 1, 0},
{2, 34, 433, 433, 34, 434, 0, 1},
};
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
h1->entries_lba = cases[i].primary_entries_lba;
h1->first_usable_lba = cases[i].primary_first_usable_lba;
h1->last_usable_lba = cases[i].primary_last_usable_lba;
h2->entries_lba = cases[i].secondary_entries_lba;
h2->first_usable_lba = cases[i].secondary_first_usable_lba;
h2->last_usable_lba = cases[i].secondary_last_usable_lba;
RefreshCrc32(gpt);
EXPECT(CheckHeader(h1, 0, gpt->drive_sectors) ==
cases[i].primary_rv);
EXPECT(CheckHeader(h2, 1, gpt->drive_sectors) ==
cases[i].secondary_rv);
}
return TEST_OK;
}
/*
* Test if PartitionEntryArrayCRC32 is checked. PartitionEntryArrayCRC32 must
* be calculated over SizeOfPartitionEntry * NumberOfPartitionEntries bytes.
*/
static int EntriesCrcTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptEntry *e1 = (GptEntry *)(gpt->primary_entries);
GptEntry *e2 = (GptEntry *)(gpt->secondary_entries);
/* Modify first byte of primary entries, and expect the CRC is wrong. */
BuildTestGptData(gpt);
EXPECT(0 == CheckEntries(e1, h1));
EXPECT(0 == CheckEntries(e2, h1));
gpt->primary_entries[0] ^= 0xa5; /* just XOR a non-zero value */
gpt->secondary_entries[TOTAL_ENTRIES_SIZE-1] ^= 0x5a;
EXPECT(GPT_ERROR_CRC_CORRUPTED == CheckEntries(e1, h1));
EXPECT(GPT_ERROR_CRC_CORRUPTED == CheckEntries(e2, h1));
return TEST_OK;
}
/*
* Test if partition geometry is checked.
* All active (non-zero PartitionTypeGUID) partition entries should have:
* entry.StartingLBA >= header.FirstUsableLBA
* entry.EndingLBA <= header.LastUsableLBA
* entry.StartingLBA <= entry.EndingLBA
*/
static int ValidEntryTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptEntry *e1 = (GptEntry *)(gpt->primary_entries);
MtdData *mtd = GetEmptyMtdData();
MtdDiskLayout *mh = &mtd->primary;
MtdDiskPartition *me = mh->partitions;
/* error case: entry.StartingLBA < header.FirstUsableLBA */
BuildTestGptData(gpt);
e1[0].starting_lba = h1->first_usable_lba - 1;
RefreshCrc32(gpt);
EXPECT(GPT_ERROR_OUT_OF_REGION == CheckEntries(e1, h1));
BuildTestMtdData(mtd);
if (mh->first_offset > 0) {
me[0].starting_offset = mh->first_offset - 1;
mh->crc32 = MtdHeaderCrc(mh);
EXPECT(GPT_ERROR_OUT_OF_REGION == MtdCheckEntries(me, mh));
}
/* error case: entry.EndingLBA > header.LastUsableLBA */
BuildTestGptData(gpt);
e1[2].ending_lba = h1->last_usable_lba + 1;
RefreshCrc32(gpt);
EXPECT(GPT_ERROR_OUT_OF_REGION == CheckEntries(e1, h1));
BuildTestMtdData(mtd);
me[0].ending_offset = mh->last_offset + 1;
mh->crc32 = MtdHeaderCrc(mh);
EXPECT(GPT_ERROR_OUT_OF_REGION == MtdCheckEntries(me, mh));
/* error case: entry.StartingLBA > entry.EndingLBA */
BuildTestGptData(gpt);
e1[3].starting_lba = e1[3].ending_lba + 1;
RefreshCrc32(gpt);
EXPECT(GPT_ERROR_OUT_OF_REGION == CheckEntries(e1, h1));
BuildTestMtdData(mtd);
me[0].starting_offset = me[0].ending_offset + 1;
mh->crc32 = MtdHeaderCrc(mh);
EXPECT(GPT_ERROR_OUT_OF_REGION == MtdCheckEntries(me, mh));
/* case: non active entry should be ignored. */
BuildTestGptData(gpt);
Memset(&e1[1].type, 0, sizeof(e1[1].type));
e1[1].starting_lba = e1[1].ending_lba + 1;
RefreshCrc32(gpt);
EXPECT(0 == CheckEntries(e1, h1));
BuildTestMtdData(mtd);
me[0].flags = 0;
me[0].starting_offset = me[0].ending_offset + 1;
mh->crc32 = MtdHeaderCrc(mh);
EXPECT(GPT_SUCCESS == MtdCheckEntries(me, mh));
return TEST_OK;
}
/* Test if overlapped partition tables can be detected. */
static int OverlappedPartitionTest(void) {
GptData *gpt = GetEmptyGptData();
GptHeader *h = (GptHeader *)gpt->primary_header;
GptEntry *e = (GptEntry *)gpt->primary_entries;
MtdData *mtd = GetEmptyMtdData();
MtdDiskLayout *mh = &mtd->primary;
MtdDiskPartition *me = mh->partitions;
int i, j;
struct {
int overlapped;
struct {
int active;
uint64_t starting_lba;
uint64_t ending_lba;
} entries[16]; /* enough for testing. */
} cases[] = {
{GPT_SUCCESS, {{0, 100, 199}}},
{GPT_SUCCESS, {{1, 100, 199}}},
{GPT_SUCCESS, {{1, 100, 150}, {1, 200, 250}, {1, 300, 350}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{1, 200, 299}, {1, 100, 199}, {1, 100, 100}}},
{GPT_ERROR_END_LBA_OVERLAP,
{{1, 200, 299}, {1, 100, 199}, {1, 299, 299}}},
{GPT_SUCCESS, {{1, 300, 399}, {1, 200, 299}, {1, 100, 199}}},
{GPT_ERROR_END_LBA_OVERLAP,
{{1, 100, 199}, {1, 199, 299}, {1, 299, 399}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{1, 100, 199}, {1, 200, 299}, {1, 75, 399}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{1, 100, 199}, {1, 75, 250}, {1, 200, 299}}},
{GPT_ERROR_END_LBA_OVERLAP,
{{1, 75, 150}, {1, 100, 199}, {1, 200, 299}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{1, 200, 299}, {1, 100, 199}, {1, 300, 399}, {1, 100, 399}}},
{GPT_SUCCESS,
{{1, 200, 299}, {1, 100, 199}, {1, 300, 399}, {0, 100, 399}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{1, 200, 300}, {1, 100, 200}, {1, 100, 400}, {1, 300, 400}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{0, 200, 300}, {1, 100, 200}, {1, 100, 400}, {1, 300, 400}}},
{GPT_SUCCESS,
{{1, 200, 300}, {1, 100, 199}, {0, 100, 400}, {0, 300, 400}}},
{GPT_ERROR_END_LBA_OVERLAP,
{{1, 200, 299}, {1, 100, 199}, {1, 199, 199}}},
{GPT_SUCCESS, {{1, 200, 299}, {0, 100, 199}, {1, 199, 199}}},
{GPT_SUCCESS, {{1, 200, 299}, {1, 100, 199}, {0, 199, 199}}},
{GPT_ERROR_START_LBA_OVERLAP,
{{1, 199, 199}, {1, 200, 200}, {1, 201, 201}, {1, 202, 202},
{1, 203, 203}, {1, 204, 204}, {1, 205, 205}, {1, 206, 206},
{1, 207, 207}, {1, 208, 208}, {1, 199, 199}}},
{GPT_SUCCESS,
{{1, 199, 199}, {1, 200, 200}, {1, 201, 201}, {1, 202, 202},
{1, 203, 203}, {1, 204, 204}, {1, 205, 205}, {1, 206, 206},
{1, 207, 207}, {1, 208, 208}, {0, 199, 199}}},
};
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
BuildTestMtdData(mtd);
Memset(mh->partitions, 0, sizeof(mh->partitions));
ZeroEntries(gpt);
for(j = 0; j < ARRAY_SIZE(cases[0].entries); ++j) {
if (!cases[i].entries[j].starting_lba)
break;
if (cases[i].entries[j].active) {
Memcpy(&e[j].type, &guid_kernel, sizeof(Guid));
me[j].flags =
MTD_PARTITION_TYPE_CHROMEOS_KERNEL << MTD_ATTRIBUTE_TYPE_OFFSET;
}
SetGuid(&e[j].unique, j);
e[j].starting_lba = cases[i].entries[j].starting_lba;
e[j].ending_lba = cases[i].entries[j].ending_lba;
me[j].starting_offset = cases[i].entries[j].starting_lba *
DEFAULT_SECTOR_SIZE;
me[j].ending_offset = cases[i].entries[j].ending_lba *
DEFAULT_SECTOR_SIZE;
}
RefreshCrc32(gpt);
EXPECT(cases[i].overlapped == CheckEntries(e, h));
EXPECT(cases[i].overlapped == MtdCheckEntries(me, mh));
}
return TEST_OK;
}
/* Test both sanity checking and repair. */
static int SanityCheckTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h1 = (GptHeader *)gpt->primary_header;
GptEntry *e1 = (GptEntry *)gpt->primary_entries;
uint8_t *tempptr;
/* Unmodified test data is completely sane */
BuildTestGptData(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
/* Repair doesn't damage it */
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT(0 == gpt->modified);
/* Invalid sector size should fail */
BuildTestGptData(gpt);
gpt->sector_bytes = 1024;
EXPECT(GPT_ERROR_INVALID_SECTOR_SIZE == GptSanityCheck(gpt));
/* Modify headers */
BuildTestGptData(gpt);
gpt->primary_header[0]++;
gpt->secondary_header[0]++;
EXPECT(GPT_ERROR_INVALID_HEADERS == GptSanityCheck(gpt));
EXPECT(0 == gpt->valid_headers);
EXPECT(0 == gpt->valid_entries);
/* Repair can't fix completely busted headers */
GptRepair(gpt);
EXPECT(GPT_ERROR_INVALID_HEADERS == GptSanityCheck(gpt));
EXPECT(0 == gpt->valid_headers);
EXPECT(0 == gpt->valid_entries);
EXPECT(0 == gpt->modified);
BuildTestGptData(gpt);
gpt->primary_header[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_SECONDARY == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT(GPT_MODIFIED_HEADER1 == gpt->modified);
BuildTestGptData(gpt);
gpt->secondary_header[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_PRIMARY == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT(GPT_MODIFIED_HEADER2 == gpt->modified);
/*
* Modify header1 and update its CRC. Since header2 is now different
* than header1, it'll be the one considered invalid.
*/
BuildTestGptData(gpt);
h1->size++;
RefreshCrc32(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_PRIMARY == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT(GPT_MODIFIED_HEADER2 == gpt->modified);
/* Modify entries */
BuildTestGptData(gpt);
gpt->primary_entries[0]++;
gpt->secondary_entries[0]++;
EXPECT(GPT_ERROR_INVALID_ENTRIES == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_NONE == gpt->valid_entries);
/* Repair can't fix both copies of entries being bad, either. */
GptRepair(gpt);
EXPECT(GPT_ERROR_INVALID_ENTRIES == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_NONE == gpt->valid_entries);
EXPECT(0 == gpt->modified);
BuildTestGptData(gpt);
gpt->primary_entries[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_SECONDARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT(GPT_MODIFIED_ENTRIES1 == gpt->modified);
BuildTestGptData(gpt);
gpt->secondary_entries[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_PRIMARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT(GPT_MODIFIED_ENTRIES2 == gpt->modified);
/*
* Modify entries and recompute CRCs, then make both primary and
* secondary entry pointers use the secondary data. The primary
* header will have the wrong entries CRC, so we should fall back
* to the secondary header.
*/
BuildTestGptData(gpt);
e1->starting_lba++;
RefreshCrc32(gpt);
tempptr = gpt->primary_entries;
gpt->primary_entries = gpt->secondary_entries;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_SECONDARY == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
gpt->primary_entries = tempptr;
/* Modify both header and entries */
BuildTestGptData(gpt);
gpt->primary_header[0]++;
gpt->primary_entries[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_SECONDARY == gpt->valid_headers);
EXPECT(MASK_SECONDARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT((GPT_MODIFIED_HEADER1 | GPT_MODIFIED_ENTRIES1) == gpt->modified);
BuildTestGptData(gpt);
gpt->secondary_header[0]++;
gpt->secondary_entries[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_PRIMARY == gpt->valid_headers);
EXPECT(MASK_PRIMARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT((GPT_MODIFIED_HEADER2 | GPT_MODIFIED_ENTRIES2) == gpt->modified);
/* Test cross-correction (h1+e2, h2+e1) */
BuildTestGptData(gpt);
gpt->primary_header[0]++;
gpt->secondary_entries[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_SECONDARY == gpt->valid_headers);
EXPECT(MASK_PRIMARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT((GPT_MODIFIED_HEADER1 | GPT_MODIFIED_ENTRIES2) == gpt->modified);
BuildTestGptData(gpt);
gpt->secondary_header[0]++;
gpt->primary_entries[0]++;
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_PRIMARY == gpt->valid_headers);
EXPECT(MASK_SECONDARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT((GPT_MODIFIED_HEADER2 | GPT_MODIFIED_ENTRIES1) == gpt->modified);
/*
* Test mismatched pairs (h1+e1 valid, h2+e2 valid but different. This
* simulates a partial update of the drive.
*/
BuildTestGptData(gpt);
gpt->secondary_entries[0]++;
RefreshCrc32(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_PRIMARY == gpt->valid_headers);
EXPECT(MASK_PRIMARY == gpt->valid_entries);
GptRepair(gpt);
EXPECT(GPT_SUCCESS == GptSanityCheck(gpt));
EXPECT(MASK_BOTH == gpt->valid_headers);
EXPECT(MASK_BOTH == gpt->valid_entries);
EXPECT((GPT_MODIFIED_HEADER2 | GPT_MODIFIED_ENTRIES2) == gpt->modified);
return TEST_OK;
}
static int EntryAttributeGetSetTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e = (GptEntry *)(gpt->primary_entries);
MtdData *mtd = GetEmptyMtdData();
MtdDiskPartition *m = &mtd->primary.partitions[0];
e->attrs.whole = 0x0000000000000000ULL;
SetEntrySuccessful(e, 1);
EXPECT(0x0100000000000000ULL == e->attrs.whole);
EXPECT(1 == GetEntrySuccessful(e));
e->attrs.whole = 0xFFFFFFFFFFFFFFFFULL;
SetEntrySuccessful(e, 0);
EXPECT(0xFEFFFFFFFFFFFFFFULL == e->attrs.whole);
EXPECT(0 == GetEntrySuccessful(e));
m->flags = 0;
MtdSetEntrySuccessful(m, 1);
EXPECT(0x00000100 == m->flags);
EXPECT(1 == MtdGetEntrySuccessful(m));
m->flags = ~0;
MtdSetEntrySuccessful(m, 0);
EXPECT(0xFFFFFEFF == m->flags);
EXPECT(0 == MtdGetEntrySuccessful(m));
e->attrs.whole = 0x0000000000000000ULL;
SetEntryTries(e, 15);
EXPECT(15 == GetEntryTries(e));
EXPECT(0x00F0000000000000ULL == e->attrs.whole);
e->attrs.whole = 0xFFFFFFFFFFFFFFFFULL;
SetEntryTries(e, 0);
EXPECT(0xFF0FFFFFFFFFFFFFULL == e->attrs.whole);
EXPECT(0 == GetEntryTries(e));
m->flags = 0;
MtdSetEntryTries(m, 15);
EXPECT(0x000000F0 == m->flags);
EXPECT(15 == MtdGetEntryTries(m));
m->flags = ~0;
MtdSetEntryTries(m, 0);
EXPECT(0xFFFFFF0F == m->flags);
EXPECT(0 == MtdGetEntryTries(m));
e->attrs.whole = 0x0000000000000000ULL;
SetEntryPriority(e, 15);
EXPECT(0x000F000000000000ULL == e->attrs.whole);
EXPECT(15 == GetEntryPriority(e));
e->attrs.whole = 0xFFFFFFFFFFFFFFFFULL;
SetEntryPriority(e, 0);
EXPECT(0xFFF0FFFFFFFFFFFFULL == e->attrs.whole);
EXPECT(0 == GetEntryPriority(e));
m->flags = 0;
MtdSetEntryPriority(m, 15);
EXPECT(0x0000000F == m->flags);
EXPECT(15 == MtdGetEntryPriority(m));
m->flags = ~0;
MtdSetEntryPriority(m, 0);
EXPECT(0xFFFFFFF0 == m->flags);
EXPECT(0 == MtdGetEntryPriority(m));
e->attrs.whole = 0xFFFFFFFFFFFFFFFFULL;
EXPECT(1 == GetEntrySuccessful(e));
EXPECT(15 == GetEntryPriority(e));
EXPECT(15 == GetEntryTries(e));
e->attrs.whole = 0x0123000000000000ULL;
EXPECT(1 == GetEntrySuccessful(e));
EXPECT(2 == GetEntryTries(e));
EXPECT(3 == GetEntryPriority(e));
return TEST_OK;
}
static int EntryTypeTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e = (GptEntry *)(gpt->primary_entries);
Memcpy(&e->type, &guid_zero, sizeof(Guid));
EXPECT(1 == IsUnusedEntry(e));
EXPECT(0 == IsKernelEntry(e));
Memcpy(&e->type, &guid_kernel, sizeof(Guid));
EXPECT(0 == IsUnusedEntry(e));
EXPECT(1 == IsKernelEntry(e));
Memcpy(&e->type, &guid_rootfs, sizeof(Guid));
EXPECT(0 == IsUnusedEntry(e));
EXPECT(0 == IsKernelEntry(e));
return TEST_OK;
}
/* Make an entry unused by clearing its type. */
static void FreeEntry(GptEntry *e)
{
Memset(&e->type, 0, sizeof(Guid));
}
static void MtdFreeEntry(MtdDiskPartition *e)
{
MtdSetEntryType(e, MTD_PARTITION_TYPE_UNUSED);
}
/* Set up an entry. */
static void FillEntry(GptEntry *e, int is_kernel,
int priority, int successful, int tries)
{
Memcpy(&e->type, (is_kernel ? &guid_kernel : &guid_zero), sizeof(Guid));
SetEntryPriority(e, priority);
SetEntrySuccessful(e, successful);
SetEntryTries(e, tries);
}
static void MtdFillEntry(MtdDiskPartition *e, int is_kernel,
int priority, int successful, int tries)
{
MtdSetEntryType(e, is_kernel ? MTD_PARTITION_TYPE_CHROMEOS_KERNEL :
MTD_PARTITION_TYPE_CHROMEOS_FIRMWARE);
MtdSetEntryPriority(e, priority);
MtdSetEntrySuccessful(e, successful);
MtdSetEntryTries(e, tries);
}
/*
* Invalidate all kernel entries and expect GptNextKernelEntry() cannot find
* any usable kernel entry.
*/
static int NoValidKernelEntryTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e1 = (GptEntry *)(gpt->primary_entries);
BuildTestGptData(gpt);
SetEntryPriority(e1 + KERNEL_A, 0);
FreeEntry(e1 + KERNEL_B);
RefreshCrc32(gpt);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
GptNextKernelEntry(gpt, NULL, NULL));
return TEST_OK;
}
static int MtdNoValidKernelEntryTest(void)
{
MtdData *mtd = GetEmptyMtdData();
MtdDiskPartition *e1 = mtd->primary.partitions;
BuildTestMtdData(mtd);
MtdSetEntryPriority(e1 + KERNEL_A, 0);
MtdFreeEntry(e1 + KERNEL_B);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
MtdNextKernelEntry(mtd, NULL, NULL));
return TEST_OK;
}
static int GetNextNormalTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e1 = (GptEntry *)(gpt->primary_entries);
uint64_t start, size;
/* Normal case - both kernels successful */
BuildTestGptData(gpt);
FillEntry(e1 + KERNEL_A, 1, 2, 1, 0);
FillEntry(e1 + KERNEL_B, 1, 2, 1, 0);
RefreshCrc32(gpt);
GptInit(gpt);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_A == gpt->current_kernel);
EXPECT(34 == start);
EXPECT(100 == size);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_B == gpt->current_kernel);
EXPECT(134 == start);
EXPECT(99 == size);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
GptNextKernelEntry(gpt, &start, &size));
EXPECT(-1 == gpt->current_kernel);
/* Call as many times as you want; you won't get another kernel... */
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
GptNextKernelEntry(gpt, &start, &size));
EXPECT(-1 == gpt->current_kernel);
return TEST_OK;
}
static int GetNextPrioTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e1 = (GptEntry *)(gpt->primary_entries);
uint64_t start, size;
/* Priority 3, 4, 0, 4 - should boot order B, Y, A */
BuildTestGptData(gpt);
FillEntry(e1 + KERNEL_A, 1, 3, 1, 0);
FillEntry(e1 + KERNEL_B, 1, 4, 1, 0);
FillEntry(e1 + KERNEL_X, 1, 0, 1, 0);
FillEntry(e1 + KERNEL_Y, 1, 4, 1, 0);
RefreshCrc32(gpt);
GptInit(gpt);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_B == gpt->current_kernel);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_Y == gpt->current_kernel);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_A == gpt->current_kernel);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
GptNextKernelEntry(gpt, &start, &size));
return TEST_OK;
}
static int GetNextTriesTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e1 = (GptEntry *)(gpt->primary_entries);
uint64_t start, size;
/* Tries=nonzero is attempted just like success, but tries=0 isn't */
BuildTestGptData(gpt);
FillEntry(e1 + KERNEL_A, 1, 2, 1, 0);
FillEntry(e1 + KERNEL_B, 1, 3, 0, 0);
FillEntry(e1 + KERNEL_X, 1, 4, 0, 1);
FillEntry(e1 + KERNEL_Y, 1, 0, 0, 5);
RefreshCrc32(gpt);
GptInit(gpt);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_X == gpt->current_kernel);
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_A == gpt->current_kernel);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
GptNextKernelEntry(gpt, &start, &size));
return TEST_OK;
}
static int MtdGetNextNormalTest(void)
{
MtdData *mtd = GetEmptyMtdData();
MtdDiskPartition *e1 = mtd->primary.partitions;
uint64_t start, size;
/* Normal case - both kernels successful */
BuildTestMtdData(mtd);
MtdFillEntry(e1 + KERNEL_A, 1, 2, 1, 0);
MtdFillEntry(e1 + KERNEL_B, 1, 2, 1, 0);
mtd->primary.crc32 = MtdHeaderCrc(&mtd->primary);
MtdInit(mtd);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_A == mtd->current_kernel);
EXPECT(34 == start);
EXPECT(100 == size);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_B == mtd->current_kernel);
EXPECT(134 == start);
EXPECT(99 == size);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
MtdNextKernelEntry(mtd, &start, &size));
EXPECT(-1 == mtd->current_kernel);
/* Call as many times as you want; you won't get another kernel... */
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
MtdNextKernelEntry(mtd, &start, &size));
EXPECT(-1 == mtd->current_kernel);
return TEST_OK;
}
static int MtdGetNextPrioTest(void)
{
MtdData *mtd = GetEmptyMtdData();
MtdDiskPartition *e1 = mtd->primary.partitions;
uint64_t start, size;
/* Priority 3, 4, 0, 4 - should boot order B, Y, A */
BuildTestMtdData(mtd);
MtdFillEntry(e1 + KERNEL_A, 1, 3, 1, 0);
MtdFillEntry(e1 + KERNEL_B, 1, 4, 1, 0);
MtdFillEntry(e1 + KERNEL_X, 1, 0, 1, 0);
MtdFillEntry(e1 + KERNEL_Y, 1, 4, 1, 0);
mtd->primary.crc32 = MtdHeaderCrc(&mtd->primary);
MtdInit(mtd);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_B == mtd->current_kernel);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_Y == mtd->current_kernel);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_A == mtd->current_kernel);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
MtdNextKernelEntry(mtd, &start, &size));
return TEST_OK;
}
static int MtdGetNextTriesTest(void)
{
MtdData *mtd = GetEmptyMtdData();
MtdDiskPartition *e1 = mtd->primary.partitions;
uint64_t start, size;
/* Tries=nonzero is attempted just like success, but tries=0 isn't */
BuildTestMtdData(mtd);
MtdFillEntry(e1 + KERNEL_A, 1, 2, 1, 0);
MtdFillEntry(e1 + KERNEL_B, 1, 3, 0, 0);
MtdFillEntry(e1 + KERNEL_X, 1, 4, 0, 1);
MtdFillEntry(e1 + KERNEL_Y, 1, 0, 0, 5);
mtd->primary.crc32 = MtdHeaderCrc(&mtd->primary);
MtdInit(mtd);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_X == mtd->current_kernel);
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_A == mtd->current_kernel);
EXPECT(GPT_ERROR_NO_VALID_KERNEL ==
MtdNextKernelEntry(mtd, &start, &size));
return TEST_OK;
}
static int MtdUpdateTest() {
MtdData *mtd = GetEmptyMtdData();
MtdDiskPartition *e = &mtd->primary.partitions[0];
uint64_t start, size;
BuildTestMtdData(mtd);
/* Tries=nonzero is attempted just like success, but tries=0 isn't */
MtdFillEntry(e + KERNEL_A, 1, 4, 1, 0);
MtdFillEntry(e + KERNEL_B, 1, 3, 0, 2);
MtdFillEntry(e + KERNEL_X, 1, 2, 0, 2);
mtd->primary.crc32 = MtdHeaderCrc(&mtd->primary);
mtd->modified = 0;
EXPECT(GPT_SUCCESS == MtdInit(mtd));
/* Successful kernel */
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_A == mtd->current_kernel);
EXPECT(1 == MtdGetEntrySuccessful(e + KERNEL_A));
EXPECT(4 == MtdGetEntryPriority(e + KERNEL_A));
EXPECT(0 == MtdGetEntryTries(e + KERNEL_A));
/* Trying successful kernel changes nothing */
EXPECT(GPT_SUCCESS == MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_TRY));
EXPECT(1 == MtdGetEntrySuccessful(e + KERNEL_A));
EXPECT(4 == MtdGetEntryPriority(e + KERNEL_A));
EXPECT(0 == MtdGetEntryTries(e + KERNEL_A));
EXPECT(0 == mtd->modified);
/* Marking it bad also does not update it. */
EXPECT(GPT_SUCCESS == MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_BAD));
EXPECT(1 == MtdGetEntrySuccessful(e + KERNEL_A));
EXPECT(4 == MtdGetEntryPriority(e + KERNEL_A));
EXPECT(0 == MtdGetEntryTries(e + KERNEL_A));
EXPECT(0 == mtd->modified);
/* Kernel with tries */
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_B == mtd->current_kernel);
EXPECT(0 == MtdGetEntrySuccessful(e + KERNEL_B));
EXPECT(3 == MtdGetEntryPriority(e + KERNEL_B));
EXPECT(2 == MtdGetEntryTries(e + KERNEL_B));
/* Marking it bad clears it */
EXPECT(GPT_SUCCESS == MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_BAD));
EXPECT(0 == MtdGetEntrySuccessful(e + KERNEL_B));
EXPECT(0 == MtdGetEntryPriority(e + KERNEL_B));
EXPECT(0 == MtdGetEntryTries(e + KERNEL_B));
/* And that's caused the mtd to need updating */
EXPECT(1 == mtd->modified);
/* Another kernel with tries */
EXPECT(GPT_SUCCESS == MtdNextKernelEntry(mtd, &start, &size));
EXPECT(KERNEL_X == mtd->current_kernel);
EXPECT(0 == MtdGetEntrySuccessful(e + KERNEL_X));
EXPECT(2 == MtdGetEntryPriority(e + KERNEL_X));
EXPECT(2 == MtdGetEntryTries(e + KERNEL_X));
/* Trying it uses up a try */
EXPECT(GPT_SUCCESS == MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_TRY));
EXPECT(0 == MtdGetEntrySuccessful(e + KERNEL_X));
EXPECT(2 == MtdGetEntryPriority(e + KERNEL_X));
EXPECT(1 == MtdGetEntryTries(e + KERNEL_X));
/* Trying it again marks it inactive */
EXPECT(GPT_SUCCESS == MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_TRY));
EXPECT(0 == MtdGetEntrySuccessful(e + KERNEL_X));
EXPECT(0 == MtdGetEntryPriority(e + KERNEL_X));
EXPECT(0 == MtdGetEntryTries(e + KERNEL_X));
/* Can't update if entry isn't a kernel, or there isn't an entry */
MtdSetEntryType(e + KERNEL_X, MTD_PARTITION_TYPE_UNUSED);
EXPECT(GPT_ERROR_INVALID_UPDATE_TYPE ==
MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_BAD));
mtd->current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
EXPECT(GPT_ERROR_INVALID_UPDATE_TYPE ==
MtdUpdateKernelEntry(mtd, GPT_UPDATE_ENTRY_BAD));
return TEST_OK;
}
static int GptUpdateTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e = (GptEntry *)(gpt->primary_entries);
GptEntry *e2 = (GptEntry *)(gpt->secondary_entries);
uint64_t start, size;
/* Tries=nonzero is attempted just like success, but tries=0 isn't */
BuildTestGptData(gpt);
FillEntry(e + KERNEL_A, 1, 4, 1, 0);
FillEntry(e + KERNEL_B, 1, 3, 0, 2);
FillEntry(e + KERNEL_X, 1, 2, 0, 2);
RefreshCrc32(gpt);
GptInit(gpt);
gpt->modified = 0; /* Nothing modified yet */
/* Successful kernel */
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_A == gpt->current_kernel);
EXPECT(1 == GetEntrySuccessful(e + KERNEL_A));
EXPECT(4 == GetEntryPriority(e + KERNEL_A));
EXPECT(0 == GetEntryTries(e + KERNEL_A));
EXPECT(1 == GetEntrySuccessful(e2 + KERNEL_A));
EXPECT(4 == GetEntryPriority(e2 + KERNEL_A));
EXPECT(0 == GetEntryTries(e2 + KERNEL_A));
/* Trying successful kernel changes nothing */
EXPECT(GPT_SUCCESS == GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_TRY));
EXPECT(1 == GetEntrySuccessful(e + KERNEL_A));
EXPECT(4 == GetEntryPriority(e + KERNEL_A));
EXPECT(0 == GetEntryTries(e + KERNEL_A));
EXPECT(0 == gpt->modified);
/* Marking it bad also does not update it. */
EXPECT(GPT_SUCCESS == GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_BAD));
EXPECT(1 == GetEntrySuccessful(e + KERNEL_A));
EXPECT(4 == GetEntryPriority(e + KERNEL_A));
EXPECT(0 == GetEntryTries(e + KERNEL_A));
EXPECT(0 == gpt->modified);
/* Kernel with tries */
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_B == gpt->current_kernel);
EXPECT(0 == GetEntrySuccessful(e + KERNEL_B));
EXPECT(3 == GetEntryPriority(e + KERNEL_B));
EXPECT(2 == GetEntryTries(e + KERNEL_B));
/* Marking it bad clears it */
EXPECT(GPT_SUCCESS == GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_BAD));
EXPECT(0 == GetEntrySuccessful(e + KERNEL_B));
EXPECT(0 == GetEntryPriority(e + KERNEL_B));
EXPECT(0 == GetEntryTries(e + KERNEL_B));
/* Which affects both copies of the partition entries */
EXPECT(0 == GetEntrySuccessful(e2 + KERNEL_B));
EXPECT(0 == GetEntryPriority(e2 + KERNEL_B));
EXPECT(0 == GetEntryTries(e2 + KERNEL_B));
/* And that's caused the GPT to need updating */
EXPECT(0x0F == gpt->modified);
/* Another kernel with tries */
EXPECT(GPT_SUCCESS == GptNextKernelEntry(gpt, &start, &size));
EXPECT(KERNEL_X == gpt->current_kernel);
EXPECT(0 == GetEntrySuccessful(e + KERNEL_X));
EXPECT(2 == GetEntryPriority(e + KERNEL_X));
EXPECT(2 == GetEntryTries(e + KERNEL_X));
/* Trying it uses up a try */
EXPECT(GPT_SUCCESS == GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_TRY));
EXPECT(0 == GetEntrySuccessful(e + KERNEL_X));
EXPECT(2 == GetEntryPriority(e + KERNEL_X));
EXPECT(1 == GetEntryTries(e + KERNEL_X));
EXPECT(0 == GetEntrySuccessful(e2 + KERNEL_X));
EXPECT(2 == GetEntryPriority(e2 + KERNEL_X));
EXPECT(1 == GetEntryTries(e2 + KERNEL_X));
/* Trying it again marks it inactive */
EXPECT(GPT_SUCCESS == GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_TRY));
EXPECT(0 == GetEntrySuccessful(e + KERNEL_X));
EXPECT(0 == GetEntryPriority(e + KERNEL_X));
EXPECT(0 == GetEntryTries(e + KERNEL_X));
/* Can't update if entry isn't a kernel, or there isn't an entry */
Memcpy(&e[KERNEL_X].type, &guid_rootfs, sizeof(guid_rootfs));
EXPECT(GPT_ERROR_INVALID_UPDATE_TYPE ==
GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_BAD));
gpt->current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
EXPECT(GPT_ERROR_INVALID_UPDATE_TYPE ==
GptUpdateKernelEntry(gpt, GPT_UPDATE_ENTRY_BAD));
return TEST_OK;
}
/*
* Give an invalid kernel type, and expect GptUpdateKernelEntry() returns
* GPT_ERROR_INVALID_UPDATE_TYPE.
*/
static int UpdateInvalidKernelTypeTest(void)
{
GptData *gpt = GetEmptyGptData();
BuildTestGptData(gpt);
/* anything, but not CGPT_KERNEL_ENTRY_NOT_FOUND */
gpt->current_kernel = 0;
/* any invalid update_type value */
EXPECT(GPT_ERROR_INVALID_UPDATE_TYPE ==
GptUpdateKernelEntry(gpt, 99));
return TEST_OK;
}
static int MtdUpdateInvalidKernelTypeTest(void)
{
MtdData *mtd = GetEmptyMtdData();
BuildTestMtdData(mtd);
/* anything, but not CGPT_KERNEL_ENTRY_NOT_FOUND */
mtd->current_kernel = 0;
/* any invalid update_type value */
EXPECT(GPT_ERROR_INVALID_UPDATE_TYPE ==
MtdUpdateKernelEntry(mtd, 99));
return TEST_OK;
}
/* Test duplicate UniqueGuids can be detected. */
static int DuplicateUniqueGuidTest(void)
{
GptData *gpt = GetEmptyGptData();
GptHeader *h = (GptHeader *)gpt->primary_header;
GptEntry *e = (GptEntry *)gpt->primary_entries;
int i, j;
struct {
int duplicate;
struct {
uint64_t starting_lba;
uint64_t ending_lba;
uint32_t type_guid;
uint32_t unique_guid;
} entries[16]; /* enough for testing. */
} cases[] = {
{GPT_SUCCESS, {{100, 109, 1, 1},
{110, 119, 2, 2},
{120, 129, 3, 3},
{130, 139, 4, 4},
}},
{GPT_SUCCESS, {{100, 109, 1, 1},
{110, 119, 1, 2},
{120, 129, 2, 3},
{130, 139, 2, 4},
}},
{GPT_ERROR_DUP_GUID, {{100, 109, 1, 1},
{110, 119, 2, 2},
{120, 129, 3, 1},
{130, 139, 4, 4},
}},
{GPT_ERROR_DUP_GUID, {{100, 109, 1, 1},
{110, 119, 1, 2},
{120, 129, 2, 3},
{130, 139, 2, 2},
}},
};
for (i = 0; i < ARRAY_SIZE(cases); ++i) {
BuildTestGptData(gpt);
ZeroEntries(gpt);
for(j = 0; j < ARRAY_SIZE(cases[0].entries); ++j) {
if (!cases[i].entries[j].starting_lba)
break;
e[j].starting_lba = cases[i].entries[j].starting_lba;
e[j].ending_lba = cases[i].entries[j].ending_lba;
SetGuid(&e[j].type, cases[i].entries[j].type_guid);
SetGuid(&e[j].unique, cases[i].entries[j].unique_guid);
}
RefreshCrc32(gpt);
EXPECT(cases[i].duplicate == CheckEntries(e, h));
}
return TEST_OK;
}
/* Test getting the current kernel GUID */
static int GetKernelGuidTest(void)
{
GptData *gpt = GetEmptyGptData();
GptEntry *e = (GptEntry *)gpt->primary_entries;
Guid g;
BuildTestGptData(gpt);
gpt->current_kernel = 0;
GetCurrentKernelUniqueGuid(gpt, &g);
EXPECT(!Memcmp(&g, &e[0].unique, sizeof(Guid)));
gpt->current_kernel = 1;
GetCurrentKernelUniqueGuid(gpt, &g);
EXPECT(!Memcmp(&g, &e[1].unique, sizeof(Guid)));
return TEST_OK;
}
/* Test getting GPT error text strings */
static int ErrorTextTest(void)
{
int i;
/* Known errors are not unknown */
for (i = 0; i < GPT_ERROR_COUNT; i++) {
EXPECT(GptErrorText(i));
EXPECT(strcmp(GptErrorText(i), "Unknown"));
}
/* But other error values are */
EXPECT(!strcmp(GptErrorText(GPT_ERROR_COUNT), "Unknown"));
return TEST_OK;
}
int nand_read_page(const nand_geom *nand, int page, void *buf, int size) {
uint32_t ofs = page * nand->szofpg;
uint32_t sz = size;
if (ofs + sz > nand_drive_sz) {
return -1;
}
Memcpy(buf, nand_drive + ofs, sz);
return 0;
}
int nand_write_page(const nand_geom *nand, int page,
const void *buf, int size) {
uint32_t ofs = page * nand->szofpg;
uint32_t sz = size;
uint32_t i;
if (ofs + sz > nand_drive_sz) {
return -1;
}
for (i = 0; i < sz; i++) {
if (nand_drive[ofs + i] != 0xff) {
return -1;
}
}
Memcpy(nand_drive + ofs, buf, sz);
return 0;
}
int nand_erase_block(const nand_geom *nand, int block) {
uint32_t ofs = block * nand->szofblk;
uint32_t sz = nand->szofblk;
if (ofs + sz > nand_drive_sz) {
return -1;
}
if (!--nand_bad_block_map[block]) {
return -1;
}
Memset(nand_drive + ofs, 0xFF, sz);
return 0;
}
int nand_is_bad_block(const nand_geom *nand, int block) {
return nand_bad_block_map[block] == 0;
}
static void nand_make_ramdisk() {
if (nand_drive) {
free(nand_drive);
}
if (nand_bad_block_map) {
free(nand_bad_block_map);
}
nand_drive_sz = 1024 * 1024 * 16;
nand_drive = (uint8_t *)malloc(nand_drive_sz);
nand_bad_block_map = (uint8_t *)malloc(nand_drive_sz / 512);
Memset(nand_drive, 0xff, nand_drive_sz);
Memset(nand_bad_block_map, 0xff, nand_drive_sz / 512);
}
static int MtdFtsTest() {
int MtdLoad(struct drive *drive, int sector_bytes);
int MtdSave(struct drive *drive);
int FlashGet(const char *key, uint8_t *data, uint32_t *bufsz);
int FlashSet(const char *key, const uint8_t *data, uint32_t bufsz);
int i, j, err;
struct {
int result;
unsigned int offset, size, block_size_bytes, page_size_bytes;
} cases[] = {
{ 0, 1, 2, 1024 * 1024, 1024 * 4 },
{ 0, 1, 2, 1024 * 1024, 1024 * 16 },
/* Failure cases, non-power-of-2 */
{ -ENODEV, 1, 2, 5000000, 1024 * 16 },
{ -ENODEV, 1, 2, 1024 * 1024, 65535 },
/* Page > block */
{ -ENODEV, 1, 2, 1024 * 16, 1024 * 1024 },
};
/* Check if the FTS store works */
for (i = 0; i < ARRAY_SIZE(cases); i++) {
nand_make_ramdisk();
EXPECT(cases[i].result == flash_ts_init(cases[i].offset, cases[i].size,
cases[i].page_size_bytes,
cases[i].block_size_bytes, 512, 0));
if (cases[i].result == 0) {
/* We should have a working FTS store now */
char buffer[64];
uint8_t blob[256], blob_read[256];
uint32_t sz = sizeof(blob_read);
struct drive drive;
/* Test the low level API */
EXPECT(0 == flash_ts_set("some_key", "some value"));
flash_ts_get("some_key", buffer, sizeof(buffer));
EXPECT(0 == strcmp(buffer, "some value"));
/* Check overwrite */
EXPECT(0 == flash_ts_set("some_key", "some other value"));
flash_ts_get("some_key", buffer, sizeof(buffer));
EXPECT(0 == strcmp(buffer, "some other value"));
/* Check delete */
EXPECT(0 == flash_ts_set("some_key", ""));
/* Verify that re-initialization pulls the right record. */
flash_ts_init(cases[i].offset, cases[i].size, cases[i].page_size_bytes,
cases[i].block_size_bytes, 512, 0);
flash_ts_get("some_key", buffer, sizeof(buffer));
EXPECT(0 == strcmp(buffer, ""));
/* Fill up the disk, eating all erase cycles */
for (j = 0; j < nand_drive_sz / 512; j++) {
nand_bad_block_map[j] = 2;
}
for (j = 0; j < 999999; j++) {
char str[32];
sprintf(str, "%d", j);
err = flash_ts_set("some_new_key", str);
if (err) {
EXPECT(err == -ENOMEM);
break;
}
/* Make sure we can figure out where the latest is. */
flash_ts_init(cases[i].offset, cases[i].size, cases[i].page_size_bytes,
cases[i].block_size_bytes, 512, 0);
flash_ts_get("some_new_key", buffer, sizeof(buffer));
EXPECT(0 == strcmp(buffer, str));
}
EXPECT(j < 999999);
/* We need our drive back. */
nand_make_ramdisk();
flash_ts_init(cases[i].offset, cases[i].size, cases[i].page_size_bytes,
cases[i].block_size_bytes, 512, 0);
for (j = 0; j < 256; j++) {
blob[j] = j;
}
/* Hex conversion / blob storage */
EXPECT(0 == FlashSet("some_blob", blob, sizeof(blob)));
EXPECT(0 == FlashGet("some_blob", blob_read, &sz));
EXPECT(sz == sizeof(blob_read));
EXPECT(0 == Memcmp(blob, blob_read, sizeof(blob)));
BuildTestMtdData(&drive.mtd);
drive.mtd.flash_block_bytes = cases[i].block_size_bytes;
drive.mtd.flash_page_bytes = cases[i].page_size_bytes;
drive.mtd.fts_block_offset = cases[i].offset;
drive.mtd.fts_block_size = cases[i].size;
drive.mtd.sector_bytes = 512;
drive.mtd.drive_sectors = nand_drive_sz / 512;
/* MTD-level API */
EXPECT(0 == MtdSave(&drive));
Memset(&drive.mtd.primary, 0, sizeof(drive.mtd.primary));
EXPECT(0 == MtdLoad(&drive, 512));
}
}
return TEST_OK;
}
int main(int argc, char *argv[])
{
int i;
int error_count = 0;
struct {
char *name;
test_func fp;
int retval;
} test_cases[] = {
{ TEST_CASE(StructSizeTest), },
{ TEST_CASE(TestBuildTestGptData), },
{ TEST_CASE(TestBuildTestMtdData), },
{ TEST_CASE(ParameterTests), },
{ TEST_CASE(HeaderCrcTest), },
{ TEST_CASE(HeaderSameTest), },
{ TEST_CASE(SignatureTest), },
{ TEST_CASE(RevisionTest), },
{ TEST_CASE(SizeTest), },
{ TEST_CASE(CrcFieldTest), },
{ TEST_CASE(ReservedFieldsTest), },
{ TEST_CASE(SizeOfPartitionEntryTest), },
{ TEST_CASE(NumberOfPartitionEntriesTest), },
{ TEST_CASE(MyLbaTest), },
{ TEST_CASE(FirstUsableLbaAndLastUsableLbaTest), },
{ TEST_CASE(EntriesCrcTest), },
{ TEST_CASE(ValidEntryTest), },
{ TEST_CASE(OverlappedPartitionTest), },
{ TEST_CASE(SanityCheckTest), },
{ TEST_CASE(NoValidKernelEntryTest), },
{ TEST_CASE(MtdNoValidKernelEntryTest), },
{ TEST_CASE(EntryAttributeGetSetTest), },
{ TEST_CASE(EntryTypeTest), },
{ TEST_CASE(GetNextNormalTest), },
{ TEST_CASE(GetNextPrioTest), },
{ TEST_CASE(GetNextTriesTest), },
{ TEST_CASE(MtdGetNextNormalTest), },
{ TEST_CASE(MtdGetNextPrioTest), },
{ TEST_CASE(MtdGetNextTriesTest), },
{ TEST_CASE(GptUpdateTest), },
{ TEST_CASE(MtdUpdateTest), },
{ TEST_CASE(UpdateInvalidKernelTypeTest), },
{ TEST_CASE(MtdUpdateInvalidKernelTypeTest), },
{ TEST_CASE(DuplicateUniqueGuidTest), },
{ TEST_CASE(TestCrc32TestVectors), },
{ TEST_CASE(GetKernelGuidTest), },
{ TEST_CASE(ErrorTextTest), },
{ TEST_CASE(MtdFtsTest), },
};
for (i = 0; i < sizeof(test_cases)/sizeof(test_cases[0]); ++i) {
printf("Running %s() ...\n", test_cases[i].name);
test_cases[i].retval = test_cases[i].fp();
if (test_cases[i].retval) {
printf(COL_RED "[ERROR]\n\n" COL_STOP);
++error_count;
} else {
printf(COL_GREEN "[PASS]\n\n" COL_STOP);
}
}
if (error_count) {
printf("\n------------------------------------------------\n");
printf(COL_RED "The following %d test cases are failed:\n"
COL_STOP, error_count);
for (i = 0; i < sizeof(test_cases)/sizeof(test_cases[0]); ++i) {
if (test_cases[i].retval)
printf(" %s()\n", test_cases[i].name);
}
}
return error_count ? 1 : 0;
}