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cos / mirrors / cros / chromiumos / platform / vboot_reference / 4bf68451385566621c4abad81cfc4790d687e82b / . / tests / vboot_kernel_tests.c
blob: 3712d0d3fc4fdae10e4b45a798c6394442d8938f [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.
*
* Tests for vboot_kernel.c
*/
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "cgptlib.h"
#include "cgptlib_internal.h"
#include "gbb_header.h"
#include "gpt.h"
#include "host_common.h"
#include "load_kernel_fw.h"
#include "test_common.h"
#include "vboot_api.h"
#include "vboot_common.h"
#include "vboot_kernel.h"
#include "vboot_nvstorage.h"
#define LOGCALL(fmt, args...) sprintf(call_log + strlen(call_log), fmt, ##args)
#define TEST_CALLS(expect_log) TEST_STR_EQ(call_log, expect_log, " calls")
#define MOCK_SECTOR_SIZE 512
#define MOCK_SECTOR_COUNT 1024
/* Mock kernel partition */
struct mock_part {
uint32_t start;
uint32_t size;
};
/* Partition list; ends with a 0-size partition. */
#define MOCK_PART_COUNT 8
static struct mock_part mock_parts[MOCK_PART_COUNT];
static int mock_part_next;
/* Mock data */
static char call_log[4096];
static uint8_t kernel_buffer[80000];
static int disk_read_to_fail;
static int disk_write_to_fail;
static int gpt_init_fail;
static int key_block_verify_fail; /* 0=ok, 1=sig, 2=hash */
static int preamble_verify_fail;
static int verify_data_fail;
static RSAPublicKey *mock_data_key;
static int mock_data_key_allocated;
static uint8_t gbb_data[sizeof(GoogleBinaryBlockHeader) + 2048];
static GoogleBinaryBlockHeader *gbb = (GoogleBinaryBlockHeader*)gbb_data;
static VbExDiskHandle_t handle;
static VbNvContext vnc;
static uint8_t shared_data[VB_SHARED_DATA_MIN_SIZE];
static VbSharedDataHeader *shared = (VbSharedDataHeader *)shared_data;
static LoadKernelParams lkp;
static VbKeyBlockHeader kbh;
static VbKernelPreambleHeader kph;
static VbCommonParams cparams;
static uint8_t mock_disk[MOCK_SECTOR_SIZE * MOCK_SECTOR_COUNT];
static GptHeader *mock_gpt_primary =
(GptHeader*)&mock_disk[MOCK_SECTOR_SIZE * 1];
static GptHeader *mock_gpt_secondary =
(GptHeader*)&mock_disk[MOCK_SECTOR_SIZE * (MOCK_SECTOR_COUNT - 1)];
/**
* Prepare a valid GPT header that will pass CheckHeader() tests
*/
static void SetupGptHeader(GptHeader *h, int is_secondary)
{
Memset(h, '\0', MOCK_SECTOR_SIZE);
/* "EFI PART" */
memcpy(h->signature, GPT_HEADER_SIGNATURE, GPT_HEADER_SIGNATURE_SIZE);
h->revision = GPT_HEADER_REVISION;
h->size = MIN_SIZE_OF_HEADER;
/* 16KB: 128 entries of 128 bytes */
h->size_of_entry = sizeof(GptEntry);
h->number_of_entries = TOTAL_ENTRIES_SIZE / h->size_of_entry;
/* Set LBA pointers for primary or secondary header */
if (is_secondary) {
h->my_lba = MOCK_SECTOR_COUNT - GPT_HEADER_SECTORS;
h->entries_lba = h->my_lba - GPT_ENTRIES_SECTORS;
} else {
h->my_lba = GPT_PMBR_SECTORS;
h->entries_lba = h->my_lba + 1;
}
h->first_usable_lba = 2 + GPT_ENTRIES_SECTORS;
h->last_usable_lba = MOCK_SECTOR_COUNT - 2 - GPT_ENTRIES_SECTORS;
h->header_crc32 = HeaderCrc(h);
}
static void ResetCallLog(void)
{
*call_log = 0;
}
/**
* Reset mock data (for use before each test)
*/
static void ResetMocks(void)
{
ResetCallLog();
memset(&mock_disk, 0, sizeof(mock_disk));
SetupGptHeader(mock_gpt_primary, 0);
SetupGptHeader(mock_gpt_secondary, 1);
disk_read_to_fail = -1;
disk_write_to_fail = -1;
gpt_init_fail = 0;
key_block_verify_fail = 0;
preamble_verify_fail = 0;
verify_data_fail = 0;
mock_data_key = (RSAPublicKey *)"TestDataKey";
mock_data_key_allocated = 0;
memset(gbb, 0, sizeof(*gbb));
gbb->major_version = GBB_MAJOR_VER;
gbb->minor_version = GBB_MINOR_VER;
gbb->flags = 0;
memset(&cparams, '\0', sizeof(cparams));
cparams.gbb = gbb;
cparams.gbb_data = gbb;
cparams.gbb_size = sizeof(gbb_data);
memset(&vnc, 0, sizeof(vnc));
VbNvSetup(&vnc);
VbNvTeardown(&vnc); /* So CRC gets generated */
memset(&shared_data, 0, sizeof(shared_data));
VbSharedDataInit(shared, sizeof(shared_data));
shared->kernel_version_tpm = 0x20001;
memset(&lkp, 0, sizeof(lkp));
lkp.nv_context = &vnc;
lkp.shared_data_blob = shared;
lkp.gbb_data = gbb;
lkp.gbb_size = sizeof(gbb_data);
lkp.bytes_per_lba = 512;
lkp.ending_lba = 1023;
lkp.kernel_buffer = kernel_buffer;
lkp.kernel_buffer_size = sizeof(kernel_buffer);
memset(&kbh, 0, sizeof(kbh));
kbh.data_key.key_version = 2;
kbh.key_block_flags = -1;
kbh.key_block_size = sizeof(kbh);
memset(&kph, 0, sizeof(kph));
kph.kernel_version = 1;
kph.preamble_size = 4096 - kbh.key_block_size;
kph.body_signature.data_size = 70000;
kph.bootloader_address = 0xbeadd008;
kph.bootloader_size = 0x1234;
memset(mock_parts, 0, sizeof(mock_parts));
mock_parts[0].start = 100;
mock_parts[0].size = 150; /* 75 KB */
mock_part_next = 0;
}
/* Mocks */
VbError_t VbExDiskRead(VbExDiskHandle_t handle, uint64_t lba_start,
uint64_t lba_count, void *buffer)
{
LOGCALL("VbExDiskRead(h, %d, %d)\n", (int)lba_start, (int)lba_count);
if ((int)lba_start == disk_read_to_fail)
return VBERROR_SIMULATED;
memcpy(buffer, &mock_disk[lba_start * MOCK_SECTOR_SIZE],
lba_count * MOCK_SECTOR_SIZE);
return VBERROR_SUCCESS;
}
VbError_t VbExDiskWrite(VbExDiskHandle_t handle, uint64_t lba_start,
uint64_t lba_count, const void *buffer)
{
LOGCALL("VbExDiskWrite(h, %d, %d)\n", (int)lba_start, (int)lba_count);
if ((int)lba_start == disk_write_to_fail)
return VBERROR_SIMULATED;
memcpy(&mock_disk[lba_start * MOCK_SECTOR_SIZE], buffer,
lba_count * MOCK_SECTOR_SIZE);
return VBERROR_SUCCESS;
}
int GptInit(GptData *gpt)
{
return gpt_init_fail;
}
int GptNextKernelEntry(GptData *gpt, uint64_t *start_sector, uint64_t *size)
{
struct mock_part *p = mock_parts + mock_part_next;
if (!p->size)
return GPT_ERROR_NO_VALID_KERNEL;
gpt->current_kernel = mock_part_next;
*start_sector = p->start;
*size = p->size;
mock_part_next++;
return GPT_SUCCESS;
}
void GetCurrentKernelUniqueGuid(GptData *gpt, void *dest)
{
static char fake_guid[] = "FakeGuid";
memcpy(dest, fake_guid, sizeof(fake_guid));
}
int KeyBlockVerify(const VbKeyBlockHeader *block, uint64_t size,
const VbPublicKey *key, int hash_only) {
if (hash_only && key_block_verify_fail >= 2)
return VBERROR_SIMULATED;
else if (!hash_only && key_block_verify_fail >= 1)
return VBERROR_SIMULATED;
/* Use this as an opportunity to override the key block */
memcpy((void *)block, &kbh, sizeof(kbh));
return VBERROR_SUCCESS;
}
RSAPublicKey *PublicKeyToRSA(const VbPublicKey *key)
{
TEST_EQ(mock_data_key_allocated, 0, " mock data key not allocated");
if (mock_data_key)
mock_data_key_allocated++;
return mock_data_key;
}
void RSAPublicKeyFree(RSAPublicKey* key)
{
TEST_EQ(mock_data_key_allocated, 1, " mock data key allocated");
TEST_PTR_EQ(key, mock_data_key, " data key ptr");
mock_data_key_allocated--;
}
int VerifyKernelPreamble(const VbKernelPreambleHeader *preamble,
uint64_t size, const RSAPublicKey *key)
{
if (preamble_verify_fail)
return VBERROR_SIMULATED;
/* Use this as an opportunity to override the preamble */
memcpy((void *)preamble, &kph, sizeof(kph));
return VBERROR_SUCCESS;
}
int VerifyData(const uint8_t *data, uint64_t size, const VbSignature *sig,
const RSAPublicKey *key)
{
if (verify_data_fail)
return VBERROR_SIMULATED;
return VBERROR_SUCCESS;
}
/**
* Test reading/writing GPT
*/
static void ReadWriteGptTest(void)
{
GptData g;
GptHeader *h;
g.sector_bytes = MOCK_SECTOR_SIZE;
g.drive_sectors = MOCK_SECTOR_COUNT;
g.valid_headers = g.valid_entries = MASK_BOTH;
ResetMocks();
TEST_EQ(AllocAndReadGptData(handle, &g), 0, "AllocAndRead");
TEST_CALLS("VbExDiskRead(h, 1, 1)\n"
"VbExDiskRead(h, 2, 32)\n"
"VbExDiskRead(h, 1023, 1)\n"
"VbExDiskRead(h, 991, 32)\n");
ResetCallLog();
/*
* Valgrind complains about access to uninitialized memory here, so
* zero the primary header before each test.
*/
Memset(g.primary_header, '\0', g.sector_bytes);
TEST_EQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree");
TEST_CALLS("");
/*
* Invalidate primary GPT header,
* check that AllocAndReadGptData still succeeds
*/
ResetMocks();
Memset(mock_gpt_primary, '\0', sizeof(*mock_gpt_primary));
TEST_EQ(AllocAndReadGptData(handle, &g), 0,
"AllocAndRead primary invalid");
TEST_EQ(CheckHeader(mock_gpt_primary, 0, g.drive_sectors), 1,
"Primary header is invalid");
TEST_EQ(CheckHeader(mock_gpt_secondary, 1, g.drive_sectors), 0,
"Secondary header is valid");
TEST_CALLS("VbExDiskRead(h, 1, 1)\n"
"VbExDiskRead(h, 1023, 1)\n"
"VbExDiskRead(h, 991, 32)\n");
WriteAndFreeGptData(handle, &g);
/*
* Invalidate secondary GPT header,
* check that AllocAndReadGptData still succeeds
*/
ResetMocks();
Memset(mock_gpt_secondary, '\0', sizeof(*mock_gpt_secondary));
TEST_EQ(AllocAndReadGptData(handle, &g), 0,
"AllocAndRead secondary invalid");
TEST_EQ(CheckHeader(mock_gpt_primary, 0, g.drive_sectors), 0,
"Primary header is valid");
TEST_EQ(CheckHeader(mock_gpt_secondary, 1, g.drive_sectors), 1,
"Secondary header is invalid");
TEST_CALLS("VbExDiskRead(h, 1, 1)\n"
"VbExDiskRead(h, 2, 32)\n"
"VbExDiskRead(h, 1023, 1)\n");
WriteAndFreeGptData(handle, &g);
/*
* Invalidate primary AND secondary GPT header,
* check that AllocAndReadGptData fails.
*/
ResetMocks();
Memset(mock_gpt_primary, '\0', sizeof(*mock_gpt_primary));
Memset(mock_gpt_secondary, '\0', sizeof(*mock_gpt_secondary));
TEST_EQ(AllocAndReadGptData(handle, &g), 1,
"AllocAndRead primary and secondary invalid");
TEST_EQ(CheckHeader(mock_gpt_primary, 0, g.drive_sectors), 1,
"Primary header is invalid");
TEST_EQ(CheckHeader(mock_gpt_secondary, 1, g.drive_sectors), 1,
"Secondary header is invalid");
TEST_CALLS("VbExDiskRead(h, 1, 1)\n"
"VbExDiskRead(h, 1023, 1)\n");
WriteAndFreeGptData(handle, &g);
/*
* Invalidate primary GPT header and check that it is
* repaired by GptRepair().
*
* This would normally be called by LoadKernel()->GptInit()
* but this callback is mocked in these tests.
*/
ResetMocks();
Memset(mock_gpt_primary, '\0', sizeof(*mock_gpt_primary));
TEST_EQ(AllocAndReadGptData(handle, &g), 0,
"Fix Primary GPT: AllocAndRead");
/* Call GptRepair() with input indicating secondary GPT is valid */
g.valid_headers = g.valid_entries = MASK_SECONDARY;
GptRepair(&g);
TEST_EQ(WriteAndFreeGptData(handle, &g), 0,
"Fix Primary GPT: WriteAndFreeGptData");
TEST_CALLS("VbExDiskRead(h, 1, 1)\n"
"VbExDiskRead(h, 1023, 1)\n"
"VbExDiskRead(h, 991, 32)\n"
"VbExDiskWrite(h, 1, 1)\n"
"VbExDiskWrite(h, 2, 32)\n");
TEST_EQ(CheckHeader(mock_gpt_primary, 0, g.drive_sectors), 0,
"Fix Primary GPT: Primary header is valid");
/*
* Invalidate secondary GPT header and check that it can be
* repaired by GptRepair().
*
* This would normally be called by LoadKernel()->GptInit()
* but this callback is mocked in these tests.
*/
ResetMocks();
Memset(mock_gpt_secondary, '\0', sizeof(*mock_gpt_secondary));
TEST_EQ(AllocAndReadGptData(handle, &g), 0,
"Fix Secondary GPT: AllocAndRead");
/* Call GptRepair() with input indicating primary GPT is valid */
g.valid_headers = g.valid_entries = MASK_PRIMARY;
GptRepair(&g);
TEST_EQ(WriteAndFreeGptData(handle, &g), 0,
"Fix Secondary GPT: WriteAndFreeGptData");
TEST_CALLS("VbExDiskRead(h, 1, 1)\n"
"VbExDiskRead(h, 2, 32)\n"
"VbExDiskRead(h, 1023, 1)\n"
"VbExDiskWrite(h, 1023, 1)\n"
"VbExDiskWrite(h, 991, 32)\n");
TEST_EQ(CheckHeader(mock_gpt_secondary, 1, g.drive_sectors), 0,
"Fix Secondary GPT: Secondary header is valid");
/* Data which is changed is written */
ResetMocks();
AllocAndReadGptData(handle, &g);
g.modified |= GPT_MODIFIED_HEADER1 | GPT_MODIFIED_ENTRIES1;
ResetCallLog();
Memset(g.primary_header, '\0', g.sector_bytes);
h = (GptHeader*)g.primary_header;
h->entries_lba = 2;
TEST_EQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree mod 1");
TEST_CALLS("VbExDiskWrite(h, 1, 1)\n"
"VbExDiskWrite(h, 2, 32)\n");
/* Data which is changed is written */
ResetMocks();
AllocAndReadGptData(handle, &g);
g.modified = -1;
ResetCallLog();
Memset(g.primary_header, '\0', g.sector_bytes);
h = (GptHeader*)g.primary_header;
h->entries_lba = 2;
h = (GptHeader*)g.secondary_header;
h->entries_lba = 991;
TEST_EQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree mod all");
TEST_CALLS("VbExDiskWrite(h, 1, 1)\n"
"VbExDiskWrite(h, 2, 32)\n"
"VbExDiskWrite(h, 1023, 1)\n"
"VbExDiskWrite(h, 991, 32)\n");
/* If legacy signature, don't modify GPT header/entries 1 */
ResetMocks();
AllocAndReadGptData(handle, &g);
h = (GptHeader *)g.primary_header;
memcpy(h->signature, GPT_HEADER_SIGNATURE2, GPT_HEADER_SIGNATURE_SIZE);
g.modified = -1;
ResetCallLog();
TEST_EQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree mod all");
TEST_CALLS("VbExDiskWrite(h, 1023, 1)\n"
"VbExDiskWrite(h, 991, 32)\n");
/* Error reading */
ResetMocks();
disk_read_to_fail = 1;
TEST_NEQ(AllocAndReadGptData(handle, &g), 0, "AllocAndRead disk fail");
Memset(g.primary_header, '\0', g.sector_bytes);
WriteAndFreeGptData(handle, &g);
ResetMocks();
disk_read_to_fail = 2;
TEST_NEQ(AllocAndReadGptData(handle, &g), 0, "AllocAndRead disk fail");
Memset(g.primary_header, '\0', g.sector_bytes);
WriteAndFreeGptData(handle, &g);
ResetMocks();
disk_read_to_fail = 991;
TEST_NEQ(AllocAndReadGptData(handle, &g), 0, "AllocAndRead disk fail");
Memset(g.primary_header, '\0', g.sector_bytes);
WriteAndFreeGptData(handle, &g);
ResetMocks();
disk_read_to_fail = 1023;
TEST_NEQ(AllocAndReadGptData(handle, &g), 0, "AllocAndRead disk fail");
Memset(g.primary_header, '\0', g.sector_bytes);
WriteAndFreeGptData(handle, &g);
/* Error writing */
ResetMocks();
disk_write_to_fail = 1;
AllocAndReadGptData(handle, &g);
g.modified = -1;
Memset(g.primary_header, '\0', g.sector_bytes);
TEST_NEQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree disk fail");
ResetMocks();
disk_write_to_fail = 2;
AllocAndReadGptData(handle, &g);
g.modified = -1;
Memset(g.primary_header, '\0', g.sector_bytes);
h = (GptHeader*)g.primary_header;
h->entries_lba = 2;
TEST_NEQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree disk fail");
ResetMocks();
disk_write_to_fail = 991;
AllocAndReadGptData(handle, &g);
g.modified = -1;
Memset(g.primary_header, '\0', g.sector_bytes);
TEST_NEQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree disk fail");
ResetMocks();
disk_write_to_fail = 1023;
AllocAndReadGptData(handle, &g);
g.modified = -1;
Memset(g.primary_header, '\0', g.sector_bytes);
TEST_NEQ(WriteAndFreeGptData(handle, &g), 0, "WriteAndFree disk fail");
}
/**
* Trivial invalid calls to LoadKernel()
*/
static void InvalidParamsTest(void)
{
ResetMocks();
lkp.bytes_per_lba = 0;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_PARAMETER,
"Bad lba size");
ResetMocks();
lkp.ending_lba = 0;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_PARAMETER,
"Bad lba count");
ResetMocks();
lkp.bytes_per_lba = 128*1024;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_PARAMETER,
"Huge lba size");
ResetMocks();
disk_read_to_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_NO_KERNEL_FOUND,
"Can't read disk");
ResetMocks();
gpt_init_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_NO_KERNEL_FOUND,
"Bad GPT");
}
static void LoadKernelTest(void)
{
uint32_t u;
ResetMocks();
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "First kernel good");
TEST_EQ(lkp.partition_number, 1, " part num");
TEST_EQ(lkp.bootloader_address, 0xbeadd008, " bootloader addr");
TEST_EQ(lkp.bootloader_size, 0x1234, " bootloader size");
TEST_STR_EQ((char *)lkp.partition_guid, "FakeGuid", " guid");
VbNvGet(&vnc, VBNV_RECOVERY_REQUEST, &u);
TEST_EQ(u, 0, " recovery request");
ResetMocks();
mock_parts[1].start = 300;
mock_parts[1].size = 150;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Two good kernels");
TEST_EQ(lkp.partition_number, 1, " part num");
TEST_EQ(mock_part_next, 1, " didn't read second one");
/* Fail if no kernels found */
ResetMocks();
mock_parts[0].size = 0;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_NO_KERNEL_FOUND, "No kernels");
VbNvGet(&vnc, VBNV_RECOVERY_REQUEST, &u);
TEST_EQ(u, VBNV_RECOVERY_RW_NO_OS, " recovery request");
/* Skip kernels which are too small */
ResetMocks();
mock_parts[0].size = 10;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND, "Too small");
VbNvGet(&vnc, VBNV_RECOVERY_REQUEST, &u);
TEST_EQ(u, VBNV_RECOVERY_RW_INVALID_OS, " recovery request");
ResetMocks();
disk_read_to_fail = 100;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Fail reading kernel start");
ResetMocks();
key_block_verify_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Fail key block sig");
/* In dev mode, fail if hash is bad too */
ResetMocks();
lkp.boot_flags |= BOOT_FLAG_DEVELOPER;
key_block_verify_fail = 2;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Fail key block dev hash");
/* But just bad sig is ok */
ResetMocks();
lkp.boot_flags |= BOOT_FLAG_DEVELOPER;
key_block_verify_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Succeed key block dev sig");
/* In dev mode and requiring signed kernel, fail if sig is bad */
ResetMocks();
lkp.boot_flags |= BOOT_FLAG_DEVELOPER;
VbNvSet(&vnc, VBNV_DEV_BOOT_SIGNED_ONLY, 1);
VbNvTeardown(&vnc);
key_block_verify_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Fail key block dev sig");
/* Check key block flag mismatches */
ResetMocks();
kbh.key_block_flags =
KEY_BLOCK_FLAG_RECOVERY_0 | KEY_BLOCK_FLAG_DEVELOPER_1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Key block dev flag mismatch");
ResetMocks();
kbh.key_block_flags =
KEY_BLOCK_FLAG_RECOVERY_1 | KEY_BLOCK_FLAG_DEVELOPER_0;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Key block rec flag mismatch");
ResetMocks();
lkp.boot_flags |= BOOT_FLAG_RECOVERY;
kbh.key_block_flags =
KEY_BLOCK_FLAG_RECOVERY_1 | KEY_BLOCK_FLAG_DEVELOPER_1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Key block recdev flag mismatch");
ResetMocks();
lkp.boot_flags |= BOOT_FLAG_RECOVERY | BOOT_FLAG_DEVELOPER;
kbh.key_block_flags =
KEY_BLOCK_FLAG_RECOVERY_1 | KEY_BLOCK_FLAG_DEVELOPER_0;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Key block rec!dev flag mismatch");
ResetMocks();
kbh.data_key.key_version = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Key block kernel key rollback");
ResetMocks();
kbh.data_key.key_version = 0x10000;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Key block kernel key version too big");
ResetMocks();
kbh.data_key.key_version = 3;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Key block version roll forward");
TEST_EQ(shared->kernel_version_tpm, 0x30001, " shared version");
ResetMocks();
kbh.data_key.key_version = 3;
mock_parts[1].start = 300;
mock_parts[1].size = 150;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Two kernels roll forward");
TEST_EQ(mock_part_next, 2, " read both");
TEST_EQ(shared->kernel_version_tpm, 0x30001, " shared version");
ResetMocks();
kbh.data_key.key_version = 1;
lkp.boot_flags |= BOOT_FLAG_DEVELOPER;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Key version ignored in dev mode");
ResetMocks();
kbh.data_key.key_version = 1;
lkp.boot_flags |= BOOT_FLAG_RECOVERY;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Key version ignored in rec mode");
ResetMocks();
mock_data_key = NULL;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Bad data key");
ResetMocks();
preamble_verify_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Bad preamble");
ResetMocks();
kph.kernel_version = 0;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Kernel version rollback");
ResetMocks();
kph.kernel_version = 0;
lkp.boot_flags |= BOOT_FLAG_DEVELOPER;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Kernel version ignored in dev mode");
ResetMocks();
kph.kernel_version = 0;
lkp.boot_flags |= BOOT_FLAG_RECOVERY;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Kernel version ignored in rec mode");
ResetMocks();
kph.preamble_size |= 0x07;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Kernel body offset");
/* Check getting kernel load address from header */
ResetMocks();
kph.body_load_address = (size_t)kernel_buffer;
lkp.kernel_buffer = NULL;
TEST_EQ(LoadKernel(&lkp, &cparams), 0, "Get load address from preamble");
TEST_PTR_EQ(lkp.kernel_buffer, kernel_buffer, " address");
/* Size is rounded up to nearest sector */
TEST_EQ(lkp.kernel_buffer_size, 70144, " size");
ResetMocks();
lkp.kernel_buffer_size = 8192;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Kernel too big for buffer");
ResetMocks();
mock_parts[0].size = 130;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Kernel too big for partition");
ResetMocks();
disk_read_to_fail = 108;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND,
"Fail reading kernel data");
ResetMocks();
verify_data_fail = 1;
TEST_EQ(LoadKernel(&lkp, &cparams), VBERROR_INVALID_KERNEL_FOUND, "Bad data");
}
int main(void)
{
ReadWriteGptTest();
InvalidParamsTest();
LoadKernelTest();
if (vboot_api_stub_check_memory())
return 255;
return gTestSuccess ? 0 : 255;
}