static void tpm_clear_tests(void)
{
/* No clear request */
reset_common_data();
TEST_SUCC(vb2_check_tpm_clear(&cc), "no clear request");
TEST_EQ(mock_tpm_clear_called, 0, "tpm not cleared");
/* Successful request */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_CLEAR_TPM_OWNER_REQUEST, 1);
TEST_SUCC(vb2_check_tpm_clear(&cc), "clear request");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_CLEAR_TPM_OWNER_REQUEST),
0, "request cleared");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_CLEAR_TPM_OWNER_DONE),
1, "done set");
TEST_EQ(mock_tpm_clear_called, 1, "tpm cleared");
/* Failed request */
reset_common_data();
mock_tpm_clear_retval = VB2_ERROR_EX_TPM_CLEAR_OWNER;
vb2_nv_set(&cc, VB2_NV_CLEAR_TPM_OWNER_REQUEST, 1);
TEST_EQ(vb2_check_tpm_clear(&cc),
VB2_ERROR_EX_TPM_CLEAR_OWNER, "clear failure");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_CLEAR_TPM_OWNER_REQUEST),
0, "request cleared");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_CLEAR_TPM_OWNER_DONE),
0, "done not set");
}
int vb2_check_tpm_clear(struct vb2_context *ctx)
{
int rv;
/* Check if we've been asked to clear the owner */
if (!vb2_nv_get(ctx, VB2_NV_CLEAR_TPM_OWNER_REQUEST))
return VB2_SUCCESS; /* No need to clear */
/* Request applies one time only */
vb2_nv_set(ctx, VB2_NV_CLEAR_TPM_OWNER_REQUEST, 0);
/* Try clearing */
rv = vb2ex_tpm_clear_owner(ctx);
if (rv) {
/*
* Note that this truncates rv to 8 bit. Which is not as
* useful as the full error code, but we don't have NVRAM space
* to store the full 32-bit code.
*/
vb2_fail(ctx, VB2_RECOVERY_TPM_CLEAR_OWNER, rv);
return rv;
}
/* Clear successful */
vb2_nv_set(ctx, VB2_NV_CLEAR_TPM_OWNER_DONE, 1);
return VB2_SUCCESS;
}
void vb2_fail(struct vb2_context *ctx, uint8_t reason, uint8_t subcode)
{
struct vb2_shared_data *sd = vb2_get_sd(ctx);
/* If NV data hasn't been initialized, initialize it now */
if (!(sd->status & VB2_SD_STATUS_NV_INIT))
vb2_nv_init(ctx);
/* See if we were far enough in the boot process to choose a slot */
if (sd->status & VB2_SD_STATUS_CHOSE_SLOT) {
/* Boot failed */
vb2_nv_set(ctx, VB2_NV_FW_RESULT, VB2_FW_RESULT_FAILURE);
/* Use up remaining tries */
vb2_nv_set(ctx, VB2_NV_TRY_COUNT, 0);
/*
* Try the other slot next time. We'll alternate
* between slots, which may help if one or both slots is
* flaky.
*/
vb2_nv_set(ctx, VB2_NV_TRY_NEXT, 1 - sd->fw_slot);
/*
* If we didn't try the other slot last boot, or we tried it
* and it didn't fail, try it next boot.
*/
if (sd->last_fw_slot != 1 - sd->fw_slot ||
sd->last_fw_result != VB2_FW_RESULT_FAILURE)
return;
}
/*
* If we're still here, we failed before choosing a slot, or both
* this slot and the other slot failed in successive boots. So we
* need to go to recovery.
*
* Set a recovery reason and subcode only if they're not already set.
* If recovery is already requested, it's a more specific error code
* than later code is providing and we shouldn't overwrite it.
*/
VB2_DEBUG("Need recovery, reason: %#x / %#x\n", reason, subcode);
if (!vb2_nv_get(ctx, VB2_NV_RECOVERY_REQUEST)) {
vb2_nv_set(ctx, VB2_NV_RECOVERY_REQUEST, reason);
vb2_nv_set(ctx, VB2_NV_RECOVERY_SUBCODE, subcode);
}
}
void vb2_check_recovery(struct vb2_context *ctx)
{
struct vb2_shared_data *sd = vb2_get_sd(ctx);
uint32_t reason = vb2_nv_get(ctx, VB2_NV_RECOVERY_REQUEST);
uint32_t subcode = vb2_nv_get(ctx, VB2_NV_RECOVERY_SUBCODE);
VB2_DEBUG("Recovery reason from previous boot: %#x / %#x\n",
reason, subcode);
/*
* Sets the current recovery request, unless there's already been a
* failure earlier in the boot process.
*/
if (!sd->recovery_reason)
sd->recovery_reason = reason;
/* Clear request and subcode so we don't get stuck in recovery mode */
vb2_nv_set(ctx, VB2_NV_RECOVERY_REQUEST, VB2_RECOVERY_NOT_REQUESTED);
vb2_nv_set(ctx, VB2_NV_RECOVERY_SUBCODE, VB2_RECOVERY_NOT_REQUESTED);
if (ctx->flags & VB2_CONTEXT_FORCE_RECOVERY_MODE) {
VB2_DEBUG("Recovery was requested manually\n");
if (subcode && !sd->recovery_reason)
/*
* Recovery was requested at 'broken' screen.
* Promote subcode to reason.
*/
sd->recovery_reason = subcode;
else
/* Recovery was forced. Override recovery reason */
sd->recovery_reason = VB2_RECOVERY_RO_MANUAL;
sd->flags |= VB2_SD_FLAG_MANUAL_RECOVERY;
}
/* If recovery reason is non-zero, tell caller we need recovery mode */
if (sd->recovery_reason) {
ctx->flags |= VB2_CONTEXT_RECOVERY_MODE;
VB2_DEBUG("We have a recovery request: %#x / %#x\n",
sd->recovery_reason,
vb2_nv_get(ctx, VB2_NV_RECOVERY_SUBCODE));
}
}
static void recovery_tests(void)
{
/* No recovery */
reset_common_data();
vb2_check_recovery(&cc);
TEST_EQ(sd->recovery_reason, 0, "No recovery reason");
TEST_EQ(sd->flags & VB2_SD_FLAG_MANUAL_RECOVERY,
0, "Not manual recovery");
TEST_EQ(cc.flags & VB2_CONTEXT_RECOVERY_MODE,
0, "Not recovery mode");
/* From request */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_RECOVERY_REQUEST, 3);
vb2_check_recovery(&cc);
TEST_EQ(sd->recovery_reason, 3, "Recovery reason from request");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST), 0, "NV cleared");
TEST_EQ(sd->flags & VB2_SD_FLAG_MANUAL_RECOVERY,
0, "Not manual recovery");
TEST_NEQ(cc.flags & VB2_CONTEXT_RECOVERY_MODE,
0, "Recovery mode");
/* From request, but already failed */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_RECOVERY_REQUEST, 4);
sd->recovery_reason = 5;
vb2_check_recovery(&cc);
TEST_EQ(sd->recovery_reason, 5, "Recovery reason already failed");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST),
0, "NV still cleared");
/* Override */
reset_common_data();
sd->recovery_reason = 6;
cc.flags |= VB2_CONTEXT_FORCE_RECOVERY_MODE;
vb2_check_recovery(&cc);
TEST_EQ(sd->recovery_reason, VB2_RECOVERY_RO_MANUAL,
"Recovery reason forced");
TEST_NEQ(sd->flags & VB2_SD_FLAG_MANUAL_RECOVERY,
0, "SD flag set");
}
int vb2_select_fw_slot(struct vb2_context *ctx)
{
struct vb2_shared_data *sd = vb2_get_sd(ctx);
uint32_t tries;
/* Get result of last boot */
sd->last_fw_slot = vb2_nv_get(ctx, VB2_NV_FW_TRIED);
sd->last_fw_result = vb2_nv_get(ctx, VB2_NV_FW_RESULT);
/* Save to the previous result fields in NV storage */
vb2_nv_set(ctx, VB2_NV_FW_PREV_TRIED, sd->last_fw_slot);
vb2_nv_set(ctx, VB2_NV_FW_PREV_RESULT, sd->last_fw_result);
/* Clear result, since we don't know what will happen this boot */
vb2_nv_set(ctx, VB2_NV_FW_RESULT, VB2_FW_RESULT_UNKNOWN);
/* Get slot to try */
sd->fw_slot = vb2_nv_get(ctx, VB2_NV_TRY_NEXT);
/* Check try count */
tries = vb2_nv_get(ctx, VB2_NV_TRY_COUNT);
if (sd->last_fw_result == VB2_FW_RESULT_TRYING &&
sd->last_fw_slot == sd->fw_slot &&
tries == 0) {
/*
* We used up our last try on the previous boot, so fall back
* to the other slot this boot.
*/
sd->fw_slot = 1 - sd->fw_slot;
vb2_nv_set(ctx, VB2_NV_TRY_NEXT, sd->fw_slot);
}
if (tries > 0) {
/* Still trying this firmware */
vb2_nv_set(ctx, VB2_NV_FW_RESULT, VB2_FW_RESULT_TRYING);
/* Decrement non-zero try count, unless told not to */
if (!(ctx->flags & VB2_CONTEXT_NOFAIL_BOOT))
vb2_nv_set(ctx, VB2_NV_TRY_COUNT, tries - 1);
}
/* Store the slot we're trying */
vb2_nv_set(ctx, VB2_NV_FW_TRIED, sd->fw_slot);
/* Set context flag if we're using slot B */
if (sd->fw_slot)
ctx->flags |= VB2_CONTEXT_FW_SLOT_B;
/* Set status flag */
sd->status |= VB2_SD_STATUS_CHOSE_SLOT;
return VB2_SUCCESS;
}
/* Test display key checking */
static void DisplayKeyTest(void)
{
ResetMocks();
VbCheckDisplayKey(&ctx, 'q', NULL);
TEST_EQ(*debug_info, '\0', "DisplayKey q = does nothing");
ResetMocks();
VbCheckDisplayKey(&ctx, '\t', NULL);
TEST_NEQ(*debug_info, '\0', "DisplayKey tab = display");
/* Toggle localization */
ResetMocks();
vb2_nv_set(&ctx, VB2_NV_LOCALIZATION_INDEX, 0);
VbCheckDisplayKey(&ctx, VB_KEY_DOWN, NULL);
TEST_EQ(vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX), 2,
"DisplayKey up");
VbCheckDisplayKey(&ctx, VB_KEY_LEFT, NULL);
vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX);
TEST_EQ(vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX), 1,
"DisplayKey left");
VbCheckDisplayKey(&ctx, VB_KEY_RIGHT, NULL);
vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX);
TEST_EQ(vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX), 2,
"DisplayKey right");
VbCheckDisplayKey(&ctx, VB_KEY_UP, NULL);
vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX);
TEST_EQ(vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX), 0,
"DisplayKey up");
/* Reset localization if localization count is invalid */
ResetMocks();
vb2_nv_set(&ctx, VB2_NV_LOCALIZATION_INDEX, 1);
mock_localization_count = 0xffffffff;
VbCheckDisplayKey(&ctx, VB_KEY_UP, NULL);
TEST_EQ(vb2_nv_get(&ctx, VB2_NV_LOCALIZATION_INDEX), 0,
"DisplayKey invalid");
}
int vb2_check_dev_switch(struct vb2_context *ctx)
{
struct vb2_shared_data *sd = vb2_get_sd(ctx);
uint32_t flags = 0;
uint32_t old_flags;
int is_dev = 0;
int use_secdata = 1;
int rv;
/* Read secure flags */
rv = vb2_secdata_get(ctx, VB2_SECDATA_FLAGS, &flags);
if (rv) {
if (ctx->flags & VB2_CONTEXT_RECOVERY_MODE) {
/*
* Recovery mode needs to check other ways developer
* mode can be enabled, so don't give up yet. But
* since we can't read secdata, assume dev mode was
* disabled.
*/
use_secdata = 0;
flags = 0;
} else {
/* Normal mode simply fails */
return rv;
}
}
old_flags = flags;
/* Handle dev disable request */
if (use_secdata && vb2_nv_get(ctx, VB2_NV_DISABLE_DEV_REQUEST)) {
flags &= ~VB2_SECDATA_FLAG_DEV_MODE;
/* Clear the request */
vb2_nv_set(ctx, VB2_NV_DISABLE_DEV_REQUEST, 0);
}
/*
* Check if we've been asked by the caller to disable dev mode. Note
* that hardware switch and GBB flag will take precedence over this.
*/
if (ctx->flags & VB2_DISABLE_DEVELOPER_MODE)
flags &= ~VB2_SECDATA_FLAG_DEV_MODE;
/* Check virtual dev switch */
if (flags & VB2_SECDATA_FLAG_DEV_MODE)
is_dev = 1;
/* Handle forcing dev mode via physical switch */
if (ctx->flags & VB2_CONTEXT_FORCE_DEVELOPER_MODE)
is_dev = 1;
/* Check if GBB is forcing dev mode */
if (sd->gbb_flags & VB2_GBB_FLAG_FORCE_DEV_SWITCH_ON)
is_dev = 1;
/* Handle whichever mode we end up in */
if (is_dev) {
/* Developer mode */
sd->flags |= VB2_SD_DEV_MODE_ENABLED;
ctx->flags |= VB2_CONTEXT_DEVELOPER_MODE;
flags |= VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER;
} else {
/* Normal mode */
flags &= ~VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER;
/*
* Disable dev_boot_* flags. This ensures they will be
* initially disabled if the user later transitions back into
* developer mode.
*/
vb2_nv_set(ctx, VB2_NV_DEV_BOOT_USB, 0);
vb2_nv_set(ctx, VB2_NV_DEV_BOOT_LEGACY, 0);
vb2_nv_set(ctx, VB2_NV_DEV_BOOT_SIGNED_ONLY, 0);
vb2_nv_set(ctx, VB2_NV_DEV_BOOT_FASTBOOT_FULL_CAP, 0);
vb2_nv_set(ctx, VB2_NV_DEV_DEFAULT_BOOT, 0);
vb2_nv_set(ctx, VB2_NV_FASTBOOT_UNLOCK_IN_FW, 0);
}
if (ctx->flags & VB2_CONTEXT_FORCE_WIPEOUT_MODE)
vb2_nv_set(ctx, VB2_NV_REQ_WIPEOUT, 1);
if (flags != old_flags) {
/*
* Just changed dev mode state. Clear TPM owner. This must be
* done here instead of simply passing a flag to
* vb2_check_tpm_clear(), because we don't want to update
* last_boot_developer and then fail to clear the TPM owner.
*
* Note that we do this even if we couldn't read secdata, since
* the TPM owner and secdata may be independent, and we want
* the owner to be cleared if *this boot* is different than the
* last one (perhaps due to GBB or hardware override).
*/
rv = vb2ex_tpm_clear_owner(ctx);
if (use_secdata) {
/* Check for failure to clear owner */
if (rv) {
/*
* Note that this truncates rv to 8 bit. Which
* is not as useful as the full error code, but
* we don't have NVRAM space to store the full
* 32-bit code.
*/
vb2_fail(ctx, VB2_RECOVERY_TPM_CLEAR_OWNER, rv);
return rv;
}
/* Save new flags */
rv = vb2_secdata_set(ctx, VB2_SECDATA_FLAGS, flags);
if (rv)
return rv;
}
}
return VB2_SUCCESS;
}
int vb2api_fw_phase1(struct vb2_context *ctx)
{
int rv;
struct vb2_shared_data *sd;
/* Initialize the vboot context if it hasn't been yet */
vb2_init_context(ctx);
sd = vb2_get_sd(ctx);
/* Initialize NV context */
vb2_nv_init(ctx);
/*
* Handle caller-requested reboot due to secdata. Do this before we
* even look at secdata. If we fail because of a reboot loop we'll be
* the first failure so will get to set the recovery reason.
*/
if (!(ctx->flags & VB2_CONTEXT_SECDATA_WANTS_REBOOT)) {
/* No reboot requested */
vb2_nv_set(ctx, VB2_NV_TPM_REQUESTED_REBOOT, 0);
} else if (vb2_nv_get(ctx, VB2_NV_TPM_REQUESTED_REBOOT)) {
/*
* Reboot requested... again. Fool me once, shame on you.
* Fool me twice, shame on me. Fail into recovery to avoid
* a reboot loop.
*/
vb2_fail(ctx, VB2_RECOVERY_RO_TPM_REBOOT, 0);
} else {
/* Reboot requested for the first time */
vb2_nv_set(ctx, VB2_NV_TPM_REQUESTED_REBOOT, 1);
return VB2_ERROR_API_PHASE1_SECDATA_REBOOT;
}
/* Initialize secure data */
rv = vb2_secdata_init(ctx);
if (rv)
vb2_fail(ctx, VB2_RECOVERY_SECDATA_INIT, rv);
/* Load and parse the GBB header */
rv = vb2_fw_parse_gbb(ctx);
if (rv)
vb2_fail(ctx, VB2_RECOVERY_GBB_HEADER, rv);
/*
* Check for recovery. Note that this function returns void, since any
* errors result in requesting recovery. That's also why we don't
* return error from failures in the preceding two steps; those
* failures simply cause us to detect recovery mode here.
*/
vb2_check_recovery(ctx);
/* Check for dev switch */
rv = vb2_check_dev_switch(ctx);
if (rv && !(ctx->flags & VB2_CONTEXT_RECOVERY_MODE)) {
/*
* Error in dev switch processing, and we weren't already
* headed for recovery mode. Reboot into recovery mode, since
* it's too late to handle those errors this boot, and we need
* to take a different path through the dev switch checking
* code in that case.
*/
vb2_fail(ctx, VB2_RECOVERY_DEV_SWITCH, rv);
return rv;
}
/*
* Check for possible reasons to ask the firmware to make display
* available. sd->recovery_reason may have been set above by
* vb2_check_recovery. VB2_SD_FLAG_DEV_MODE_ENABLED may have been set
* above by vb2_check_dev_switch.
*/
if (!(ctx->flags & VB2_CONTEXT_DISPLAY_INIT) &&
(vb2_nv_get(ctx, VB2_NV_OPROM_NEEDED) ||
sd->flags & VB2_SD_FLAG_DEV_MODE_ENABLED ||
sd->recovery_reason))
ctx->flags |= VB2_CONTEXT_DISPLAY_INIT;
/* Mark display as available for downstream vboot and vboot callers. */
if (ctx->flags & VB2_CONTEXT_DISPLAY_INIT)
sd->flags |= VB2_SD_FLAG_DISPLAY_AVAILABLE;
/* Return error if recovery is needed */
if (ctx->flags & VB2_CONTEXT_RECOVERY_MODE) {
/* Always clear RAM when entering recovery mode */
ctx->flags |= VB2_CONTEXT_CLEAR_RAM;
return VB2_ERROR_API_PHASE1_RECOVERY;
}
return VB2_SUCCESS;
}
static void nv_storage_test(void)
{
struct nv_field *vnf;
uint8_t goodcrc;
uint8_t workbuf[VB2_WORKBUF_RECOMMENDED_SIZE]
__attribute__ ((aligned (VB2_WORKBUF_ALIGN)));
struct vb2_context c = {
.flags = 0,
.workbuf = workbuf,
.workbuf_size = sizeof(workbuf),
};
struct vb2_shared_data *sd = vb2_get_sd(&c);
memset(c.nvdata, 0xA6, sizeof(c.nvdata));
vb2_init_context(&c);
/* Init with invalid data should set defaults and regenerate CRC */
vb2_nv_init(&c);
TEST_EQ(c.nvdata[0], 0x70, "vb2_nv_init() reset header byte");
TEST_NEQ(c.nvdata[15], 0, "vb2_nv_init() CRC");
TEST_EQ(sd->status, VB2_SD_STATUS_NV_INIT | VB2_SD_STATUS_NV_REINIT,
"vb2_nv_init() status changed");
test_changed(&c, 1, "vb2_nv_init() reset changed");
goodcrc = c.nvdata[15];
TEST_SUCC(vb2_nv_check_crc(&c), "vb2_nv_check_crc() good");
/* Another init should not cause further changes */
c.flags = 0;
sd->status = 0;
vb2_nv_init(&c);
test_changed(&c, 0, "vb2_nv_init() didn't re-reset");
TEST_EQ(c.nvdata[15], goodcrc, "vb2_nv_init() CRC same");
TEST_EQ(sd->status, VB2_SD_STATUS_NV_INIT, "vb2_nv_init() status same");
/* Perturbing the header should force defaults */
c.nvdata[0] ^= 0x40;
TEST_EQ(vb2_nv_check_crc(&c),
VB2_ERROR_NV_HEADER, "vb2_nv_check_crc() bad header");
vb2_nv_init(&c);
TEST_EQ(c.nvdata[0], 0x70, "vb2_nv_init() reset header byte again");
test_changed(&c, 1, "vb2_nv_init() corrupt changed");
TEST_EQ(c.nvdata[15], goodcrc, "vb2_nv_init() CRC same again");
/* So should perturbing some other byte */
TEST_EQ(c.nvdata[11], 0, "Kernel byte starts at 0");
c.nvdata[11] = 12;
TEST_EQ(vb2_nv_check_crc(&c),
VB2_ERROR_NV_CRC, "vb2_nv_check_crc() bad CRC");
vb2_nv_init(&c);
TEST_EQ(c.nvdata[11], 0, "vb2_nv_init() reset kernel byte");
test_changed(&c, 1, "vb2_nv_init() corrupt elsewhere changed");
TEST_EQ(c.nvdata[15], goodcrc, "vb2_nv_init() CRC same again");
/* Clear the kernel and firmware flags */
vb2_nv_init(&c);
TEST_EQ(vb2_nv_get(&c, VB2_NV_FIRMWARE_SETTINGS_RESET),
1, "Firmware settings are reset");
vb2_nv_set(&c, VB2_NV_FIRMWARE_SETTINGS_RESET, 0);
TEST_EQ(vb2_nv_get(&c, VB2_NV_FIRMWARE_SETTINGS_RESET),
0, "Firmware settings are clear");
TEST_EQ(vb2_nv_get(&c, VB2_NV_KERNEL_SETTINGS_RESET),
1, "Kernel settings are reset");
vb2_nv_set(&c, VB2_NV_KERNEL_SETTINGS_RESET, 0);
TEST_EQ(vb2_nv_get(&c, VB2_NV_KERNEL_SETTINGS_RESET),
0, "Kernel settings are clear");
TEST_EQ(c.nvdata[0], 0x40, "Header byte now just has the header bit");
/* That should have changed the CRC */
TEST_NEQ(c.nvdata[15], goodcrc,
"vb2_nv_init() CRC changed due to flags clear");
/* Test explicitly setting the reset flags again */
vb2_nv_init(&c);
vb2_nv_set(&c, VB2_NV_FIRMWARE_SETTINGS_RESET, 1);
TEST_EQ(vb2_nv_get(&c, VB2_NV_FIRMWARE_SETTINGS_RESET),
1, "Firmware settings forced reset");
vb2_nv_set(&c, VB2_NV_FIRMWARE_SETTINGS_RESET, 0);
vb2_nv_set(&c, VB2_NV_KERNEL_SETTINGS_RESET, 1);
TEST_EQ(vb2_nv_get(&c, VB2_NV_KERNEL_SETTINGS_RESET),
1, "Kernel settings forced reset");
vb2_nv_set(&c, VB2_NV_KERNEL_SETTINGS_RESET, 0);
/* Get/set an invalid field */
vb2_nv_init(&c);
vb2_nv_set(&c, -1, 1);
TEST_EQ(vb2_nv_get(&c, -1), 0, "Get invalid setting");
/* Test other fields */
vb2_nv_init(&c);
for (vnf = nvfields; vnf->desc; vnf++) {
TEST_EQ(vb2_nv_get(&c, vnf->param), vnf->default_value,
vnf->desc);
vb2_nv_set(&c, vnf->param, vnf->test_value);
TEST_EQ(vb2_nv_get(&c, vnf->param), vnf->test_value, vnf->desc);
vb2_nv_set(&c, vnf->param, vnf->test_value2);
TEST_EQ(vb2_nv_get(&c, vnf->param), vnf->test_value2,
vnf->desc);
}
/* None of those changes should have caused a reset to defaults */
vb2_nv_init(&c);
TEST_EQ(vb2_nv_get(&c, VB2_NV_FIRMWARE_SETTINGS_RESET),
0, "Firmware settings are still clear");
TEST_EQ(vb2_nv_get(&c, VB2_NV_KERNEL_SETTINGS_RESET),
0, "Kernel settings are still clear");
/* Writing identical settings doesn't cause the CRC to regenerate */
c.flags = 0;
vb2_nv_init(&c);
test_changed(&c, 0, "No regen CRC on open");
for (vnf = nvfields; vnf->desc; vnf++)
vb2_nv_set(&c, vnf->param, vnf->test_value2);
test_changed(&c, 0, "No regen CRC if data not changed");
/* Test out-of-range fields mapping to defaults or failing */
vb2_nv_init(&c);
vb2_nv_set(&c, VB2_NV_TRY_COUNT, 16);
TEST_EQ(vb2_nv_get(&c, VB2_NV_TRY_COUNT),
15, "Try b count out of range");
vb2_nv_set(&c, VB2_NV_RECOVERY_REQUEST, 0x101);
TEST_EQ(vb2_nv_get(&c, VB2_NV_RECOVERY_REQUEST),
VB2_RECOVERY_LEGACY, "Recovery request out of range");
vb2_nv_set(&c, VB2_NV_LOCALIZATION_INDEX, 0x102);
TEST_EQ(vb2_nv_get(&c, VB2_NV_LOCALIZATION_INDEX),
0, "Localization index out of range");
vb2_nv_set(&c, VB2_NV_FW_RESULT, VB2_FW_RESULT_UNKNOWN + 1);
vb2_nv_set(&c, VB2_NV_FW_RESULT, VB2_FW_RESULT_UNKNOWN + 100);
TEST_EQ(vb2_nv_get(&c, VB2_NV_FW_RESULT),
VB2_FW_RESULT_UNKNOWN, "Firmware result out of range");
}
int main(int argc, char* argv[])
{
nv_storage_test();
return gTestSuccess ? 0 : 255;
}
static void init_context_tests(void)
{
/* Use our own context struct so we can re-init it */
struct vb2_context c = {
.workbuf = workbuf,
.workbuf_size = sizeof(workbuf),
};
reset_common_data();
TEST_SUCC(vb2_init_context(&c), "Init context good");
TEST_EQ(c.workbuf_used, sizeof(struct vb2_shared_data),
"Init vbsd");
/* Don't re-init if used is non-zero */
c.workbuf_used = 200;
TEST_SUCC(vb2_init_context(&c), "Re-init context good");
TEST_EQ(c.workbuf_used, 200, "Didn't re-init");
/* Handle workbuf errors */
c.workbuf_used = 0;
c.workbuf_size = sizeof(struct vb2_shared_data) - 1;
TEST_EQ(vb2_init_context(&c),
VB2_ERROR_INITCTX_WORKBUF_SMALL, "Init too small");
c.workbuf_size = sizeof(workbuf);
/* Handle workbuf unaligned */
c.workbuf++;
TEST_EQ(vb2_init_context(&c),
VB2_ERROR_INITCTX_WORKBUF_ALIGN, "Init unaligned");
}
static void misc_tests(void)
{
struct vb2_workbuf wb;
reset_common_data();
cc.workbuf_used = 16;
vb2_workbuf_from_ctx(&cc, &wb);
TEST_PTR_EQ(wb.buf, workbuf + 16, "vb_workbuf_from_ctx() buf");
TEST_EQ(wb.size, cc.workbuf_size - 16, "vb_workbuf_from_ctx() size");
}
static void gbb_tests(void)
{
struct vb2_gbb_header gbb = {
.signature = {'$', 'G', 'B', 'B'},
.major_version = VB2_GBB_MAJOR_VER,
.minor_version = VB2_GBB_MINOR_VER,
.header_size = sizeof(struct vb2_gbb_header),
.flags = 0x1234,
.rootkey_offset = 240,
.rootkey_size = 1040,
};
struct vb2_gbb_header gbbdest;
TEST_EQ(sizeof(struct vb2_gbb_header),
EXPECTED_VB2_GBB_HEADER_SIZE,
"sizeof(struct vb2_gbb_header)");
reset_common_data();
/* Good contents */
mock_resource_index = VB2_RES_GBB;
mock_resource_ptr = &gbb;
mock_resource_size = sizeof(gbb);
TEST_SUCC(vb2_read_gbb_header(&cc, &gbbdest), "read gbb header good");
TEST_SUCC(memcmp(&gbb, &gbbdest, sizeof(gbb)), "read gbb contents");
mock_resource_index = VB2_RES_GBB + 1;
TEST_EQ(vb2_read_gbb_header(&cc, &gbbdest),
VB2_ERROR_EX_READ_RESOURCE_INDEX, "read gbb header missing");
mock_resource_index = VB2_RES_GBB;
gbb.signature[0]++;
TEST_EQ(vb2_read_gbb_header(&cc, &gbbdest),
VB2_ERROR_GBB_MAGIC, "read gbb header bad magic");
gbb.signature[0]--;
gbb.major_version = VB2_GBB_MAJOR_VER + 1;
TEST_EQ(vb2_read_gbb_header(&cc, &gbbdest),
VB2_ERROR_GBB_VERSION, "read gbb header major version");
gbb.major_version = VB2_GBB_MAJOR_VER;
gbb.minor_version = VB2_GBB_MINOR_VER + 1;
TEST_SUCC(vb2_read_gbb_header(&cc, &gbbdest),
"read gbb header minor++");
gbb.minor_version = 1;
TEST_EQ(vb2_read_gbb_header(&cc, &gbbdest),
VB2_ERROR_GBB_TOO_OLD, "read gbb header 1.1 fails");
gbb.minor_version = 0;
TEST_EQ(vb2_read_gbb_header(&cc, &gbbdest),
VB2_ERROR_GBB_TOO_OLD, "read gbb header 1.0 fails");
gbb.minor_version = VB2_GBB_MINOR_VER;
gbb.header_size--;
TEST_EQ(vb2_read_gbb_header(&cc, &gbbdest),
VB2_ERROR_GBB_HEADER_SIZE, "read gbb header size");
TEST_EQ(vb2_fw_parse_gbb(&cc),
VB2_ERROR_GBB_HEADER_SIZE, "parse gbb failure");
gbb.header_size++;
/* Parse GBB */
TEST_SUCC(vb2_fw_parse_gbb(&cc), "parse gbb");
TEST_EQ(sd->gbb_flags, gbb.flags, "gbb flags");
TEST_EQ(sd->gbb_rootkey_offset, gbb.rootkey_offset, "rootkey offset");
TEST_EQ(sd->gbb_rootkey_size, gbb.rootkey_size, "rootkey size");
/* Workbuf failure */
reset_common_data();
cc.workbuf_used = cc.workbuf_size - 4;
TEST_EQ(vb2_fw_parse_gbb(&cc),
VB2_ERROR_GBB_WORKBUF, "parse gbb no workbuf");
}
static void fail_tests(void)
{
/* Early fail (before even NV init) */
reset_common_data();
sd->status &= ~VB2_SD_STATUS_NV_INIT;
vb2_fail(&cc, 1, 2);
TEST_NEQ(sd->status & VB2_SD_STATUS_NV_INIT, 0, "vb2_fail inits NV");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST),
1, "vb2_fail request");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_SUBCODE),
2, "vb2_fail subcode");
/* Repeated fail doesn't overwrite the error code */
vb2_fail(&cc, 3, 4);
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST),
1, "vb2_fail repeat");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_SUBCODE),
2, "vb2_fail repeat2");
/* Fail with other slot good doesn't trigger recovery */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_TRY_COUNT, 3);
vb2_nv_set(&cc, VB2_NV_FW_RESULT, VB2_FW_RESULT_UNKNOWN);
sd->status |= VB2_SD_STATUS_CHOSE_SLOT;
sd->fw_slot = 0;
sd->last_fw_slot = 1;
sd->last_fw_result = VB2_FW_RESULT_UNKNOWN;
vb2_fail(&cc, 5, 6);
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST), 0, "vb2_failover");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_RESULT),
VB2_FW_RESULT_FAILURE, "vb2_fail this fw");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_COUNT), 0, "vb2_fail use up tries");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_NEXT), 1, "vb2_fail try other slot");
/* Fail with other slot already failing triggers recovery */
reset_common_data();
sd->status |= VB2_SD_STATUS_CHOSE_SLOT;
sd->fw_slot = 1;
sd->last_fw_slot = 0;
sd->last_fw_result = VB2_FW_RESULT_FAILURE;
vb2_fail(&cc, 7, 8);
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST), 7,
"vb2_fail both slots bad");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_RESULT),
VB2_FW_RESULT_FAILURE, "vb2_fail this fw");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_NEXT), 0, "vb2_fail try other slot");
}
static void select_slot_tests(void)
{
/* Slot A */
reset_common_data();
TEST_SUCC(vb2_select_fw_slot(&cc), "select slot A");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_RESULT),
VB2_FW_RESULT_UNKNOWN, "result unknown");
TEST_NEQ(sd->status & VB2_SD_STATUS_CHOSE_SLOT, 0, "chose slot");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_TRIED), 0, "tried A");
TEST_EQ(sd->fw_slot, 0, "selected A");
TEST_EQ(cc.flags & VB2_CONTEXT_FW_SLOT_B, 0, "didn't choose B");
/* Slot B */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_TRY_NEXT, 1);
TEST_SUCC(vb2_select_fw_slot(&cc), "select slot B");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_RESULT),
VB2_FW_RESULT_UNKNOWN, "result unknown");
TEST_NEQ(sd->status & VB2_SD_STATUS_CHOSE_SLOT, 0, "chose slot");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_TRIED), 1, "tried B");
TEST_EQ(sd->fw_slot, 1, "selected B");
TEST_NEQ(cc.flags & VB2_CONTEXT_FW_SLOT_B, 0, "ctx says choose B");
/* Slot A ran out of tries */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_FW_RESULT, VB2_FW_RESULT_TRYING);
TEST_SUCC(vb2_select_fw_slot(&cc), "select slot A out of tries");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_NEXT), 1, "try B next");
TEST_NEQ(sd->status & VB2_SD_STATUS_CHOSE_SLOT, 0, "chose slot");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_TRIED), 1, "tried B");
TEST_EQ(sd->fw_slot, 1, "selected B");
TEST_NEQ(cc.flags & VB2_CONTEXT_FW_SLOT_B, 0, "ctx says choose B");
/* Slot A ran out of tries, even with nofail active */
reset_common_data();
cc.flags |= VB2_CONTEXT_NOFAIL_BOOT;
vb2_nv_set(&cc, VB2_NV_FW_RESULT, VB2_FW_RESULT_TRYING);
TEST_SUCC(vb2_select_fw_slot(&cc), "select slot A out of tries");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_NEXT), 1, "try B next");
TEST_NEQ(sd->status & VB2_SD_STATUS_CHOSE_SLOT, 0, "chose slot");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_TRIED), 1, "tried B");
TEST_EQ(sd->fw_slot, 1, "selected B");
TEST_NEQ(cc.flags & VB2_CONTEXT_FW_SLOT_B, 0, "ctx says choose B");
/* Slot A used up a try */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_TRY_COUNT, 3);
TEST_SUCC(vb2_select_fw_slot(&cc), "try slot A");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_RESULT),
VB2_FW_RESULT_TRYING, "result trying");
TEST_NEQ(sd->status & VB2_SD_STATUS_CHOSE_SLOT, 0, "chose slot");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_TRIED), 0, "tried A");
TEST_EQ(sd->fw_slot, 0, "selected A");
TEST_EQ(cc.flags & VB2_CONTEXT_FW_SLOT_B, 0, "didn't choose B");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_COUNT), 2, "tries decremented");
/* Slot A failed, but nofail active */
reset_common_data();
cc.flags |= VB2_CONTEXT_NOFAIL_BOOT;
vb2_nv_set(&cc, VB2_NV_TRY_COUNT, 3);
TEST_SUCC(vb2_select_fw_slot(&cc), "try slot A");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_RESULT),
VB2_FW_RESULT_TRYING, "result trying");
TEST_NEQ(sd->status & VB2_SD_STATUS_CHOSE_SLOT, 0, "chose slot");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_TRIED), 0, "tried A");
TEST_EQ(sd->fw_slot, 0, "selected A");
TEST_EQ(cc.flags & VB2_CONTEXT_FW_SLOT_B, 0, "didn't choose B");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_TRY_COUNT), 3, "tries not decremented");
/* Tried/result get copied to the previous fields */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_FW_TRIED, 0);
vb2_nv_set(&cc, VB2_NV_FW_RESULT, VB2_FW_RESULT_SUCCESS);
vb2_select_fw_slot(&cc);
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_PREV_TRIED), 0, "prev A");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_PREV_RESULT), VB2_FW_RESULT_SUCCESS,
"prev success");
reset_common_data();
vb2_nv_set(&cc, VB2_NV_FW_TRIED, 1);
vb2_nv_set(&cc, VB2_NV_FW_RESULT, VB2_FW_RESULT_FAILURE);
vb2_select_fw_slot(&cc);
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_PREV_TRIED), 1, "prev B");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FW_PREV_RESULT), VB2_FW_RESULT_FAILURE,
"prev failure");
}
static void dev_switch_tests(void)
{
uint32_t v;
/* Normal mode */
reset_common_data();
TEST_SUCC(vb2_check_dev_switch(&cc), "dev mode off");
TEST_EQ(sd->flags & VB2_SD_DEV_MODE_ENABLED, 0, "sd not in dev");
TEST_EQ(cc.flags & VB2_CONTEXT_DEVELOPER_MODE, 0, "ctx not in dev");
TEST_EQ(mock_tpm_clear_called, 0, "no tpm clear");
/* Dev mode */
reset_common_data();
vb2_secdata_set(&cc, VB2_SECDATA_FLAGS,
(VB2_SECDATA_FLAG_DEV_MODE |
VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER));
TEST_SUCC(vb2_check_dev_switch(&cc), "dev mode on");
TEST_NEQ(sd->flags & VB2_SD_DEV_MODE_ENABLED, 0, "sd in dev");
TEST_NEQ(cc.flags & VB2_CONTEXT_DEVELOPER_MODE, 0, "ctx in dev");
TEST_EQ(mock_tpm_clear_called, 0, "no tpm clear");
/* Any normal mode boot clears dev boot flags */
reset_common_data();
vb2_nv_set(&cc, VB2_NV_DEV_BOOT_USB, 1);
vb2_nv_set(&cc, VB2_NV_DEV_BOOT_LEGACY, 1);
vb2_nv_set(&cc, VB2_NV_DEV_BOOT_SIGNED_ONLY, 1);
vb2_nv_set(&cc, VB2_NV_DEV_BOOT_FASTBOOT_FULL_CAP, 1);
vb2_nv_set(&cc, VB2_NV_FASTBOOT_UNLOCK_IN_FW, 1);
TEST_SUCC(vb2_check_dev_switch(&cc), "dev mode off");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_DEV_BOOT_USB),
0, "cleared dev boot usb");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_DEV_BOOT_LEGACY),
0, "cleared dev boot legacy");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_DEV_BOOT_SIGNED_ONLY),
0, "cleared dev boot signed only");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_DEV_BOOT_FASTBOOT_FULL_CAP),
0, "cleared dev boot fastboot full cap");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_FASTBOOT_UNLOCK_IN_FW),
0, "cleared dev boot fastboot unlock in fw");
/* Normal-dev transition clears TPM */
reset_common_data();
vb2_secdata_set(&cc, VB2_SECDATA_FLAGS, VB2_SECDATA_FLAG_DEV_MODE);
TEST_SUCC(vb2_check_dev_switch(&cc), "to dev mode");
TEST_EQ(mock_tpm_clear_called, 1, "tpm clear");
vb2_secdata_get(&cc, VB2_SECDATA_FLAGS, &v);
TEST_EQ(v, (VB2_SECDATA_FLAG_DEV_MODE |
VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER),
"last boot developer now");
/* Dev-normal transition clears TPM too */
reset_common_data();
vb2_secdata_set(&cc, VB2_SECDATA_FLAGS,
VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER);
TEST_SUCC(vb2_check_dev_switch(&cc), "from dev mode");
TEST_EQ(mock_tpm_clear_called, 1, "tpm clear");
vb2_secdata_get(&cc, VB2_SECDATA_FLAGS, &v);
TEST_EQ(v, 0, "last boot not developer now");
/* Disable dev mode */
reset_common_data();
vb2_secdata_set(&cc, VB2_SECDATA_FLAGS,
(VB2_SECDATA_FLAG_DEV_MODE |
VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER));
vb2_nv_set(&cc, VB2_NV_DISABLE_DEV_REQUEST, 1);
TEST_SUCC(vb2_check_dev_switch(&cc), "disable dev request");
TEST_EQ(sd->flags & VB2_SD_DEV_MODE_ENABLED, 0, "sd not in dev");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_DISABLE_DEV_REQUEST),
0, "request cleared");
/* Force enabled by gbb */
reset_common_data();
sd->gbb_flags |= VB2_GBB_FLAG_FORCE_DEV_SWITCH_ON;
TEST_SUCC(vb2_check_dev_switch(&cc), "dev on via gbb");
TEST_NEQ(sd->flags & VB2_SD_DEV_MODE_ENABLED, 0, "sd in dev");
vb2_secdata_get(&cc, VB2_SECDATA_FLAGS, &v);
TEST_EQ(v, VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER,
"doesn't set dev on in secdata but does set last boot dev");
TEST_EQ(mock_tpm_clear_called, 1, "tpm clear");
/* Force enabled by ctx flag */
reset_common_data();
cc.flags |= VB2_CONTEXT_FORCE_DEVELOPER_MODE;
TEST_SUCC(vb2_check_dev_switch(&cc), "dev on via ctx flag");
TEST_NEQ(sd->flags & VB2_SD_DEV_MODE_ENABLED, 0, "sd in dev");
vb2_secdata_get(&cc, VB2_SECDATA_FLAGS, &v);
TEST_EQ(v, VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER,
"doesn't set dev on in secdata but does set last boot dev");
TEST_EQ(mock_tpm_clear_called, 1, "tpm clear");
/* Simulate clear owner failure */
reset_common_data();
vb2_secdata_set(&cc, VB2_SECDATA_FLAGS,
VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER);
mock_tpm_clear_retval = VB2_ERROR_EX_TPM_CLEAR_OWNER;
TEST_EQ(vb2_check_dev_switch(&cc),
VB2_ERROR_EX_TPM_CLEAR_OWNER, "tpm clear fail");
TEST_EQ(mock_tpm_clear_called, 1, "tpm clear");
vb2_secdata_get(&cc, VB2_SECDATA_FLAGS, &v);
TEST_EQ(v, VB2_SECDATA_FLAG_LAST_BOOT_DEVELOPER,
"last boot still developer");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_REQUEST),
VB2_RECOVERY_TPM_CLEAR_OWNER, "requests recovery");
TEST_EQ(vb2_nv_get(&cc, VB2_NV_RECOVERY_SUBCODE),
(uint8_t)VB2_ERROR_EX_TPM_CLEAR_OWNER, "recovery subcode");
}
