| /* Copyright (c) 2012 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. |
| */ |
| |
| /* APIs provided by firmware to vboot_reference. */ |
| |
| /* General notes: |
| * |
| * All verified boot functions now start with "Vb" for namespace |
| * clarity. This fixes the problem where uboot and vboot both defined |
| * assert(). |
| * |
| * Verified boot APIs to be implemented by the calling firmware and |
| * exported to vboot_reference start with "VbEx". |
| */ |
| /* TODO: split this file into a vboot_entry_points.h file which |
| * contains the entry points for the firmware to call vboot_reference, |
| * and a vboot_firmware_exports.h which contains the APIs to be |
| * implemented by the calling firmware and exported to |
| * vboot_reference. */ |
| |
| #ifndef VBOOT_REFERENCE_VBOOT_API_H_ |
| #define VBOOT_REFERENCE_VBOOT_API_H_ |
| |
| #include "sysincludes.h" |
| #include "bmpblk_header.h" |
| |
| |
| /*****************************************************************************/ |
| /* Error codes */ |
| |
| /* Functions which return an error all return this type. This is a |
| * 32-bit value rather than an int so it's consistent across UEFI, |
| * which is 32-bit during PEI and 64-bit during DXE/BDS. */ |
| typedef uint32_t VbError_t; |
| |
| /* Predefined error numbers. */ |
| enum VbErrorPredefined_t { |
| /* No error; function completed successfully. */ |
| VBERROR_SUCCESS = 0, |
| |
| /* Errors are non-zero, but differ between functions. For example, |
| * the TPM functions may pass through TPM error codes, some of which |
| * may be recoverable. */ |
| |
| /* The verified boot entry points VbInit(), VbSelectFirmware(), |
| * VbSelectAndLoadKernel() may return the following errors. */ |
| |
| /* Unknown error */ |
| VBERROR_UNKNOWN = 0x10000, |
| /* Unable to initialize shared data */ |
| VBERROR_INIT_SHARED_DATA = 0x10001, |
| /* Error resuming TPM during a S3 resume */ |
| VBERROR_TPM_S3_RESUME = 0x10002, |
| /* VbSelectFirmware() failed to find a valid firmware */ |
| VBERROR_LOAD_FIRMWARE = 0x10003, |
| /* Unable to write firmware versions to TPM */ |
| VBERROR_TPM_WRITE_FIRMWARE = 0x10004, |
| /* Unable to lock firmware versions in TPM */ |
| VBERROR_TPM_LOCK_FIRMWARE = 0x10005, |
| /* Unable to set boot mode state in TPM */ |
| VBERROR_TPM_SET_BOOT_MODE_STATE = 0x10006, |
| /* TPM requires reboot */ |
| VBERROR_TPM_REBOOT_REQUIRED = 0x10007, |
| /* Unable to set up TPM */ |
| VBERROR_TPM_FIRMWARE_SETUP = 0x10008, |
| /* Unable to read kernel versions from TPM */ |
| VBERROR_TPM_READ_KERNEL = 0x10009, |
| /* Attempted to load developer-only firmware when developer switch was off */ |
| VBERROR_DEV_FIRMWARE_SWITCH_MISMATCH = 0x1000A, |
| /* Unable to write kernel versions to TPM */ |
| VBERROR_TPM_WRITE_KERNEL = 0x1000B, |
| /* Unable to lock kernel versions in TPM */ |
| VBERROR_TPM_LOCK_KERNEL = 0x1000C, |
| /* Calling firmware requested shutdown via VbExIsShutdownRequested() */ |
| VBERROR_SHUTDOWN_REQUESTED = 0x1000D, |
| /* Unable to find a suitable boot device on which to look for a kernel */ |
| VBERROR_NO_DISK_FOUND = 0x1000E, |
| /* No OS kernel found on any boot device */ |
| VBERROR_NO_KERNEL_FOUND = 0x1000F, |
| /* All OS kernels found were invalid (corrupt, improperly signed, etc.) */ |
| VBERROR_INVALID_KERNEL_FOUND = 0x10010, |
| /* VbSelectAndLoadKernel() requested recovery mode */ |
| VBERROR_LOAD_KERNEL_RECOVERY = 0x10011, |
| /* Other error inside VbSelectAndLoadKernel() */ |
| VBERROR_LOAD_KERNEL = 0x10012, |
| /* Invalid Google binary block */ |
| VBERROR_INVALID_GBB = 0x10013, |
| /* Invalid bitmap volume */ |
| VBERROR_INVALID_BMPFV = 0x10014, |
| /* Invalid screen index */ |
| VBERROR_INVALID_SCREEN_INDEX = 0x10015, |
| /* Simulated (test) error */ |
| VBERROR_SIMULATED = 0x10016, |
| /* Invalid parameter */ |
| VBERROR_INVALID_PARAMETER = 0x10017, |
| /* VbExBeep() can't make sounds at all */ |
| VBERROR_NO_SOUND = 0x10018, |
| /* VbExBeep() can't make sound in the background */ |
| VBERROR_NO_BACKGROUND_SOUND = 0x10019, |
| /* Developer has requested a BIOS shell */ |
| VBERROR_BIOS_SHELL_REQUESTED = 0x10020, |
| /* Need VGA and don't have it, or vice-versa */ |
| VBERROR_VGA_OPROM_MISMATCH = 0x10021, |
| }; |
| |
| |
| /*****************************************************************************/ |
| /* Main entry points from firmware into vboot_reference */ |
| |
| /* Minimum and recommended size of shared_data_blob in bytes. Shared |
| * data blob is used to communicate data between calls to VbInit(), |
| * VbSelectFirmware(), the OS. Minimum size is enough to hold all |
| * required data for verified boot but may not be able to hold debug |
| * output. */ |
| #define VB_SHARED_DATA_MIN_SIZE 3072 |
| #define VB_SHARED_DATA_REC_SIZE 16384 |
| |
| /* Data passed by firmware to VbInit(), VbSelectFirmware() and |
| * VbSelectAndLoadKernel(). */ |
| /* Note that in UEFI, these are called by different phases in |
| * different processor modes (VbInit() and VbSelectFirmware() = 32-bit PEI, |
| * VbSelectAndLoadKernel() = 64-bit BDS), so the data may be at a different |
| * location between calls. */ |
| typedef struct VbCommonParams { |
| void* gbb_data; /* Pointer to GBB data */ |
| uint32_t gbb_size; /* Size of GBB data in bytes */ |
| |
| /* Shared data blob for data shared between verified boot entry |
| * points. This should be at least VB_SHARED_DATA_MIN_SIZE bytes |
| * long, and ideally is VB_SHARED_DATA_REC_SIZE bytes long. */ |
| void* shared_data_blob; /* Pointer to shared data blob buffer */ |
| uint32_t shared_data_size; /* On input, set to size of shared data blob |
| * buffer, in bytes. On output, this will |
| * contain the actual data size placed into |
| * the buffer. */ |
| |
| /* Internal context/data for verified boot, to maintain state during |
| * calls to other API functions such as VbExHashFirmwareBody(). |
| * Allocated and freed inside the entry point; firmware should not |
| * look at this. */ |
| void* vboot_context; |
| |
| /* Internal context/data for firmware / VbExHashFirmwareBody(). |
| * Needed because the PEI phase of UEFI boot runs out of ROM and |
| * thus can't modify global variables; everything needs to get |
| * passed around on the stack. */ |
| void* caller_context; |
| } VbCommonParams; |
| |
| |
| /* Flags for VbInitParams.flags */ |
| /* Developer switch was on at boot time. */ |
| #define VB_INIT_FLAG_DEV_SWITCH_ON 0x00000001 |
| /* Recovery button was pressed at boot time. */ |
| #define VB_INIT_FLAG_REC_BUTTON_PRESSED 0x00000002 |
| /* Hardware write protect was enabled at boot time. */ |
| #define VB_INIT_FLAG_WP_ENABLED 0x00000004 |
| /* This is a S3 resume, not a normal boot. */ |
| #define VB_INIT_FLAG_S3_RESUME 0x00000008 |
| /* Previous boot attempt failed for reasons external to verified boot (RAM |
| * init failure, SSD missing, etc.). */ |
| /* TODO: add a field to VbInitParams which holds a reason code, and report |
| * that via VbSharedData. */ |
| #define VB_INIT_FLAG_PREVIOUS_BOOT_FAIL 0x00000010 |
| /* Calling firmware supports read only firmware for normal/developer |
| * boot path. */ |
| #define VB_INIT_FLAG_RO_NORMAL_SUPPORT 0x00000020 |
| /* This platform does not have a physical dev-switch, so we must rely on a |
| * virtual switch (kept in the TPM) instead. When this flag is set, |
| * VB_INIT_FLAG_DEV_SWITCH_ON is ignored. */ |
| #define VB_INIT_FLAG_VIRTUAL_DEV_SWITCH 0x00000040 |
| /* Set when the VGA Option ROM has been loaded already. */ |
| #define VB_INIT_FLAG_OPROM_LOADED 0x00000080 |
| /* Set if we care about the VGA Option ROM - some platforms don't. */ |
| #define VB_INIT_FLAG_OPROM_MATTERS 0x00000100 |
| /* EC on this platform supports EC software sync. */ |
| #define VB_INIT_FLAG_EC_SOFTWARE_SYNC 0x00000200 |
| |
| /* Output flags for VbInitParams.out_flags. Used to indicate |
| * potential boot paths and configuration to the calling firmware |
| * early in the boot process, so that it can properly configure itself |
| * for the capabilities subsequently required by VbSelectFirmware() |
| * and VbSelectAndLoadKernel(). */ |
| /* Enable recovery path. Do not rely on any rewritable data (cached |
| * RAM timings, etc.). Reliable operation is more important than boot |
| * speed. */ |
| #define VB_INIT_OUT_ENABLE_RECOVERY 0x00000001 |
| /* RAM must be cleared before calling VbSelectFirmware(). */ |
| #define VB_INIT_OUT_CLEAR_RAM 0x00000002 |
| /* Load display drivers; VbExDisplay*() functions may be called. If this flag |
| * is not present, VbExDisplay*() functions will not be called this boot. */ |
| #define VB_INIT_OUT_ENABLE_DISPLAY 0x00000004 |
| /* Load USB storage drivers; VbExDisk*() functions may be called with the |
| * VB_DISK_FLAG_REMOVABLE flag. If this flag is not present, VbExDisk*() |
| * functions will only be called for fixed disks. */ |
| #define VB_INIT_OUT_ENABLE_USB_STORAGE 0x00000008 |
| /* If this is a S3 resume, do a debug reset boot instead */ |
| #define VB_INIT_OUT_S3_DEBUG_BOOT 0x00000010 |
| /* BIOS should load any PCI option ROMs it finds, not just internal video */ |
| #define VB_INIT_OUT_ENABLE_OPROM 0x00000020 |
| /* BIOS may be asked to boot something other than ChromeOS */ |
| #define VB_INIT_OUT_ENABLE_ALTERNATE_OS 0x00000040 |
| /* Enable developer path. */ |
| #define VB_INIT_OUT_ENABLE_DEVELOPER 0x00000080 |
| |
| |
| /* Data only used by VbInit() */ |
| typedef struct VbInitParams { |
| /* Inputs to VbInit() */ |
| uint32_t flags; /* Flags (see VB_INIT_FLAG_*) */ |
| |
| /* Outputs from VbInit(); valid only if it returns success. */ |
| uint32_t out_flags; /* Output flags for firmware; see |
| * VB_INIT_OUT_*) */ |
| } VbInitParams; |
| |
| |
| /* Firmware types for VbHashFirmwareBody() and |
| * VbSelectFirmwareParams.selected_firmware. Note that we store these |
| * in a uint32_t because enum maps to int, which isn't fixed-size. */ |
| enum VbSelectFirmware_t { |
| /* Recovery mode */ |
| VB_SELECT_FIRMWARE_RECOVERY = 0, |
| /* Rewritable firmware A/B for normal or developer path */ |
| VB_SELECT_FIRMWARE_A = 1, |
| VB_SELECT_FIRMWARE_B = 2, |
| /* Read only firmware for normal or developer path. */ |
| VB_SELECT_FIRMWARE_READONLY = 3 |
| }; |
| |
| |
| /* Data only used by VbSelectFirmware() */ |
| typedef struct VbSelectFirmwareParams { |
| /* Inputs to VbSelectFirmware() */ |
| void* verification_block_A; /* Key block + preamble for firmware A */ |
| void* verification_block_B; /* Key block + preamble for firmware B */ |
| uint32_t verification_size_A; /* Verification block A size in bytes */ |
| uint32_t verification_size_B; /* Verification block B size in bytes */ |
| |
| /* Outputs from VbSelectFirmware(); valid only if it returns success. */ |
| uint32_t selected_firmware; /* Main firmware to run; see |
| * VB_SELECT_FIRMWARE_*. */ |
| } VbSelectFirmwareParams; |
| |
| |
| /* We use disk handles rather than indices. Using indices causes problems if |
| * a disk is removed/inserted in the middle of processing. */ |
| typedef void* VbExDiskHandle_t; |
| |
| |
| /* Data used only by VbSelectAndLoadKernel() */ |
| typedef struct VbSelectAndLoadKernelParams { |
| /* Inputs to VbSelectAndLoadKernel() */ |
| void* kernel_buffer; /* Destination buffer for kernel |
| * (normally at 0x100000 on x86) */ |
| uint32_t kernel_buffer_size; /* Size of kernel buffer in bytes */ |
| |
| /* Outputs from VbSelectAndLoadKernel(); valid only if it returns success. */ |
| VbExDiskHandle_t disk_handle; /* Handle of disk containing loaded kernel */ |
| uint32_t partition_number; /* Partition number on disk to boot (1...M) */ |
| uint64_t bootloader_address; /* Address of bootloader image in RAM */ |
| uint32_t bootloader_size; /* Size of bootloader image in bytes */ |
| uint8_t partition_guid[16]; /* UniquePartitionGuid for boot partition */ |
| /* TODO: in H2C, all that pretty much just gets passed to the bootloader |
| * as KernelBootloaderOptions, though the disk handle is passed as an index |
| * instead of a handle. Is that used anymore now that we're passing |
| * partition_guid? */ |
| } VbSelectAndLoadKernelParams; |
| |
| |
| /* Initialize the verified boot library. |
| * |
| * Returns VBERROR_SUCCESS if success, non-zero if error; on error, |
| * caller should reboot. */ |
| VbError_t VbInit(VbCommonParams* cparams, VbInitParams* iparams); |
| |
| |
| /* Select the main firmware. |
| * |
| * Returns VBERROR_SUCCESS if success, non-zero if error; on error, |
| * caller should reboot. */ |
| /* NOTE: This is now called in all modes, including recovery. |
| * Previously, LoadFirmware() was not called in recovery mode, which |
| * meant that LoadKernel() needed to duplicate the TPM and |
| * VbSharedData initialization code. */ |
| VbError_t VbSelectFirmware(VbCommonParams* cparams, |
| VbSelectFirmwareParams* fparams); |
| |
| /* Update the data hash for the current firmware image, extending it |
| * by [size] bytes stored in [*data]. This function must only be |
| * called inside VbExHashFirmwareBody(), which is in turn called by |
| * VbSelectFirmware(). */ |
| void VbUpdateFirmwareBodyHash(VbCommonParams* cparams, |
| uint8_t* data, uint32_t size); |
| |
| /* Select and loads the kernel. |
| * |
| * Returns VBERROR_SUCCESS if success, non-zero if error; on error, |
| * caller should reboot. */ |
| VbError_t VbSelectAndLoadKernel(VbCommonParams* cparams, |
| VbSelectAndLoadKernelParams* kparams); |
| |
| /*****************************************************************************/ |
| /* Debug output (from utility.h) */ |
| |
| /* Output an error message and quit. Does not return. Supports |
| * printf()-style formatting. */ |
| void VbExError(const char* format, ...); |
| |
| /* Output a debug message. Supports printf()-style formatting. */ |
| void VbExDebug(const char* format, ...); |
| |
| |
| /*****************************************************************************/ |
| /* Memory (from utility.h) */ |
| |
| /* Allocate [size] bytes and return a pointer to the allocated memory. Abort |
| * on error; this always either returns a good pointer or never returns. |
| * |
| * If any of the firmware API implementations require aligned data |
| * (for example, disk access on ARM), all pointers returned by |
| * VbExMalloc() must also be aligned. */ |
| void* VbExMalloc(size_t size); |
| |
| /* Free memory pointed to by [ptr] previously allocated by VbExMalloc(). */ |
| void VbExFree(void* ptr); |
| |
| |
| /*****************************************************************************/ |
| /* Timer and delay (first two from utility.h) */ |
| |
| /* Read a high-resolution timer. Returns the current timer value in |
| * arbitrary units. |
| * |
| * This is intended for benchmarking, so this call MUST be fast. The |
| * timer frequency must be >1 KHz (preferably >1 MHz), and the timer |
| * must not wrap around for at least 10 minutes. It is preferable |
| * (but not required) that the timer be initialized to 0 at boot. |
| * |
| * It is assumed that the firmware has some other way of communicating |
| * the timer frequency to the OS. For example, on x86 we use TSC, and |
| * the OS kernel reports the initial TSC value at kernel-start and |
| * calculates the frequency. */ |
| uint64_t VbExGetTimer(void); |
| |
| /* Delay for at least the specified number of milliseconds. Should be |
| * accurate to within 10% (a requested delay of 1000 ms should |
| * result in an actual delay of between 1000 - 1100 ms). */ |
| void VbExSleepMs(uint32_t msec); |
| |
| /* Play a beep tone of the specified frequency in Hz and duration in msec. |
| * This is effectively a VbSleep() variant that makes noise. |
| * |
| * If the audio codec can run in the background, then: |
| * zero frequency means OFF, non-zero frequency means ON |
| * zero msec means return immediately, non-zero msec means delay (and |
| * then OFF if needed) |
| * else: |
| * non-zero msec and non-zero frequency means ON, delay, OFF, return |
| * zero msec or zero frequency means do nothing and return immediately |
| * |
| * The return value is used by the caller to determine the capabilities. The |
| * implementation should always do the best it can if it cannot fully support |
| * all features - for example, beeping at a fixed frequency if frequency |
| * support is not available. At a minimum, it must delay for the specified |
| * non-zero duration. |
| */ |
| VbError_t VbExBeep(uint32_t msec, uint32_t frequency); |
| |
| |
| /*****************************************************************************/ |
| /* TPM (from tlcl_stub.h) */ |
| |
| /* Initialize the stub library. */ |
| VbError_t VbExTpmInit(void); |
| |
| /* Close and open the device. This is needed for running more complex commands |
| * at user level, such as TPM_TakeOwnership, since the TPM device can be opened |
| * only by one process at a time. */ |
| VbError_t VbExTpmClose(void); |
| VbError_t VbExTpmOpen(void); |
| |
| /* Send a request_length-byte request to the TPM and receive a |
| * response. On input, response_length is the size of the response |
| * buffer in bytes. On exit, response_length is set to the actual |
| * received response length in bytes. */ |
| VbError_t VbExTpmSendReceive(const uint8_t* request, uint32_t request_length, |
| uint8_t* response, uint32_t* response_length); |
| |
| |
| /*****************************************************************************/ |
| /* Non-volatile storage */ |
| |
| #define VBNV_BLOCK_SIZE 16 /* Size of NV storage block in bytes */ |
| |
| /* Read the VBNV_BLOCK_SIZE-byte non-volatile storage into buf. */ |
| VbError_t VbExNvStorageRead(uint8_t* buf); |
| |
| /* Write the VBNV_BLOCK_SIZE-byte non-volatile storage from buf. */ |
| VbError_t VbExNvStorageWrite(const uint8_t* buf); |
| |
| |
| /*****************************************************************************/ |
| /* Firmware / EEPROM access (previously in load_firmware_fw.h) */ |
| |
| /* Calculate the hash of the firmware body data for [firmware_index], |
| * which is either VB_SELECT_FIRMWARE_A or VB_SELECT_FIRMWARE B. |
| * |
| * This function must call VbUpdateFirmwareBodyHash() before |
| * returning, to update the secure hash for the firmware image. For |
| * best performance, the implementation should call |
| * VbUpdateFirmwareBodyHash() periodically during the read, so that |
| * updating the hash can be pipelined with the read. If the reader |
| * cannot update the hash during the read process, it should call |
| * VbUpdateFirmwareBodyHash() on the entire firmware data after the |
| * read, before returning. |
| * |
| * It is recommended that the firmware use this call to copy the |
| * requested firmware body from EEPROM into RAM, so that it doesn't |
| * need to do a second slow copy from EEPROM to RAM if this firmware |
| * body is selected. |
| * |
| * Note this function doesn't actually pass the firmware body data to |
| * verified boot, because verified boot doesn't actually need the |
| * firmware body, just its hash. This is important on x86, where the |
| * firmware is stored compressed. We hash the compressed data, but |
| * the BIOS decompresses it during read. Simply updating a hash is |
| * compatible with the x86 read-and-decompress pipeline. */ |
| VbError_t VbExHashFirmwareBody(VbCommonParams* cparams, |
| uint32_t firmware_index); |
| |
| /*****************************************************************************/ |
| /* Disk access (previously in boot_device.h) */ |
| |
| /* Flags for VbDisk APIs */ |
| /* Disk is removable. Example removable disks: SD cards, USB keys. */ |
| #define VB_DISK_FLAG_REMOVABLE 0x00000001 |
| /* Disk is fixed. If this flag is present, disk is internal to the |
| * system and not removable. Example fixed disks: internal SATA SSD, eMMC. */ |
| #define VB_DISK_FLAG_FIXED 0x00000002 |
| /* Note that VB_DISK_FLAG_REMOVABLE and VB_DISK_FLAG_FIXED are |
| * mutually-exclusive for a single disk. VbExDiskGetInfo() may specify |
| * both flags to request disks of both types in a single call. */ |
| /* At some point we could specify additional flags, but we don't currently |
| * have a way to make use of these: |
| * |
| * USB Device is known to be attached to USB. Note that the SD |
| * card reader inside x86 systems is attached to USB so this |
| * isn't super useful. |
| * SD Device is known to be a SD card. Note that external card |
| * readers might not return this information, so also of |
| * questionable use. |
| * READ_ONLY Device is known to be read-only. Could be used by recovery |
| * when processing read-only recovery image. |
| **/ |
| |
| /* Information on a single disk */ |
| typedef struct VbDiskInfo { |
| VbExDiskHandle_t handle; /* Disk handle */ |
| uint64_t bytes_per_lba; /* Size of a LBA sector in bytes */ |
| uint64_t lba_count; /* Number of LBA sectors on the device */ |
| uint32_t flags; /* Flags (see VB_DISK_FLAG_* constants) */ |
| const char* name; /* Optional name string, for use in debugging. |
| * May be empty or null if not available. */ |
| } VbDiskInfo; |
| |
| /* Store information into [info] for all disks (storage devices) |
| * attached to the system which match all of the disk_flags. |
| * |
| * On output, count indicates how many disks are present, and |
| * [infos_ptr] points to a [count]-sized array of VbDiskInfo structs |
| * with the information on those disks; this pointer must be freed by |
| * calling VbExDiskFreeInfo(). If count=0, infos_ptr may point to |
| * NULL. If [infos_ptr] points to NULL because count=0 or error, it |
| * is not necessary to call VbExDiskFreeInfo(). |
| * |
| * A multi-function device (such as a 4-in-1 card reader) should provide |
| * multiple disk handles. |
| * |
| * The firmware must not alter or free the list pointed to by |
| * [infos_ptr] until VbExDiskFreeInfo() is called. */ |
| VbError_t VbExDiskGetInfo(VbDiskInfo** infos_ptr, uint32_t* count, |
| uint32_t disk_flags); |
| |
| /* Free a disk information list [infos] previously returned by |
| * VbExDiskGetInfo(). If [preserve_handle] != NULL, the firmware must |
| * ensure that handle remains valid after this call; all other handles |
| * from the info list need not remain valid after this call. */ |
| VbError_t VbExDiskFreeInfo(VbDiskInfo* infos, |
| VbExDiskHandle_t preserve_handle); |
| |
| /* Read lba_count LBA sectors, starting at sector lba_start, from the disk, |
| * into the buffer. |
| * |
| * If the disk handle is invalid (for example, the handle refers to a |
| * disk which as been removed), the function must return error but |
| * must not crash. */ |
| VbError_t VbExDiskRead(VbExDiskHandle_t handle, uint64_t lba_start, |
| uint64_t lba_count, void* buffer); |
| |
| /* Write lba_count LBA sectors, starting at sector lba_start, to the |
| * disk, from the buffer. |
| * |
| * If the disk handle is invalid (for example, the handle refers to a |
| * disk which as been removed), the function must return error but |
| * must not crash. */ |
| VbError_t VbExDiskWrite(VbExDiskHandle_t handle, uint64_t lba_start, |
| uint64_t lba_count, const void* buffer); |
| |
| |
| /*****************************************************************************/ |
| /* Display */ |
| |
| /* Predefined (default) screens for VbExDisplayScreen(). */ |
| enum VbScreenType_t { |
| VB_SCREEN_BLANK = 0, /* Blank (clear) screen */ |
| VB_SCREEN_DEVELOPER_WARNING = 0x101, /* Developer - warning */ |
| VB_SCREEN_DEVELOPER_EGG = 0x102, /* Developer - easter egg */ |
| VB_SCREEN_RECOVERY_REMOVE = 0x201, /* Recovery - remove inserted devices */ |
| VB_SCREEN_RECOVERY_INSERT = 0x202, /* Recovery - insert recovery image */ |
| VB_SCREEN_RECOVERY_NO_GOOD = 0x203, /* Recovery - inserted image invalid */ |
| VB_SCREEN_RECOVERY_TO_DEV = 0x204, /* Recovery - confirm dev mode */ |
| VB_SCREEN_RECOVERY_TO_NORM = 0x205, /* Recovery - confirm normal mode */ |
| }; |
| |
| /* Initialize and clear the display. Set width and height to the screen |
| * dimensions in pixels. */ |
| VbError_t VbExDisplayInit(uint32_t* width, uint32_t* height); |
| |
| |
| /* Enable (enable!=0) or disable (enable=0) the display backlight. */ |
| VbError_t VbExDisplayBacklight(uint8_t enable); |
| |
| |
| /* Display a predefined screen; see VB_SCREEN_* for valid screens. |
| * This is a backup method of screen display, intended for use if the |
| * GBB does not contain a full set of bitmaps. It is acceptable for |
| * the backup screen to be simple ASCII text such as "NO GOOD" or |
| * "INSERT"; these screens should only be seen during development. */ |
| VbError_t VbExDisplayScreen(uint32_t screen_type); |
| |
| |
| /* Write an image to the display, with the upper left corner at the specified |
| * pixel coordinates. The bitmap buffer is a pointer to the platform-dependent |
| * uncompressed binary blob with dimensions and format specified internally |
| * (for example, a raw BMP, GIF, PNG, whatever). We pass the size just for |
| * convenience. |
| */ |
| VbError_t VbExDisplayImage(uint32_t x, uint32_t y, |
| void* buffer, uint32_t buffersize); |
| |
| /* Display a string containing debug information on the screen, |
| * rendered in a platform-dependent font. Should be able to handle |
| * newlines '\n' in the string. Firmware must support displaying at |
| * least 20 lines of text, where each line may be at least 80 |
| * characters long. If the firmware has its own debug state, it may |
| * display it to the screen below this information. */ |
| VbError_t VbExDisplayDebugInfo(const char* info_str); |
| /* NOTE: This is what we currently display on ZGB/Alex when TAB is |
| * pressed. Some information (HWID, recovery reason) is ours; some |
| * (CMOS breadcrumbs) is platform-specific. If we decide to |
| * soft-render the HWID string (chrome-os-partner:3693), we'll need to |
| * maintain our own fonts, so we'll likely display it via |
| * VbExDisplayImage() above. */ |
| |
| |
| /*****************************************************************************/ |
| /* Keyboard and switches */ |
| |
| /* Key codes for required non-printable-ASCII characters. */ |
| enum VbKeyCode_t { |
| VB_KEY_UP = 0x100, |
| VB_KEY_DOWN = 0x101, |
| VB_KEY_LEFT = 0x102, |
| VB_KEY_RIGHT = 0x103, |
| VB_KEY_CTRL_ENTER = 0x104, |
| }; |
| |
| /* Read the next keypress from the keyboard buffer. |
| * |
| * Returns the keypress, or zero if no keypress is pending or error. |
| * |
| * The following keys must be returned as ASCII character codes: |
| * 0x08 Backspace |
| * 0x09 Tab |
| * 0x0D Enter (carriage return) |
| * 0x01 - 0x1A Ctrl+A - Ctrl+Z (yes, those alias with backspace/tab/enter) |
| * 0x1B Esc |
| * 0x20 Space |
| * 0x30 - 0x39 '0' - '9' |
| * 0x60 - 0x7A 'a' - 'z' |
| * |
| * Some extended keys must also be supported; see the VB_KEY_* defines above. |
| * |
| * Keys ('/') or key-chords (Fn+Q) not defined above may be handled in any of |
| * the following ways: |
| * 1. Filter (don't report anything if one of these keys is pressed). |
| * 2. Report as ASCII (if a well-defined ASCII value exists for the key). |
| * 3. Report as any other value in the range 0x200 - 0x2FF. |
| * It is not permitted to report a key as a multi-byte code (for example, |
| * sending an arrow key as the sequence of keys '\x1b', '[', '1', 'A'). */ |
| uint32_t VbExKeyboardRead(void); |
| |
| |
| /*****************************************************************************/ |
| /* Embedded controller (EC) */ |
| |
| /* This is called only if the system implements a keyboard-based (virtual) |
| * developer switch. It must return true only if the system has an embedded |
| * controller which is provably running in its RO firmware at the time the |
| * function is called. */ |
| int VbExTrustEC(void); |
| |
| /* Check if the EC is currently running rewritable code. |
| * |
| * If the EC is in RO code, sets *in_rw=0. |
| * If the EC is in RW code, sets *in_rw non-zero. |
| * If the current EC image is unknown, returns error. */ |
| VbError_t VbExEcRunningRW(int *in_rw); |
| |
| /* Request the EC jump to its rewritable code. If successful, returns |
| * when the EC has booting its RW code far enough to respond to |
| * subsequent commands. Does nothing if the EC is already in its |
| * rewritable code. */ |
| VbError_t VbExEcJumpToRW(void); |
| |
| /* Cold-reboot the EC into read-only code. This also reboots the main |
| * processor, so this function only returns if there was an error. */ |
| VbError_t VbExEcRebootToRO(void); |
| |
| /* Tell the EC to stay in RO code until it reboots. Subsequent calls to |
| * VbExEcJumpToRW() this boot will fail. Fails if the EC is not currently in |
| * RO code. */ |
| VbError_t VbExEcStayInRO(void); |
| |
| /* Read the SHA-256 hash of the rewriteable EC image. */ |
| VbError_t VbExEcHashRW(const uint8_t **hash, int *hash_size); |
| |
| /* Get the expected contents of the EC image as stored in the main firmware. */ |
| VbError_t VbExEcGetExpectedRW(const uint8_t **image, int *image_size); |
| |
| /* Update the EC rewritable image. */ |
| VbError_t VbExEcUpdateRW(const uint8_t *image, int image_size); |
| |
| /* Lock the EC code to prevent updates until the EC is rebooted. |
| * Subsequent calls to VbExEcUpdateRW() this boot will fail. */ |
| VbError_t VbExEcProtectRW(void); |
| |
| |
| /*****************************************************************************/ |
| /* Misc */ |
| |
| /* Checks if the firmware needs to shut down the system. |
| * |
| * Returns 1 if a shutdown is being requested (for example, the user has |
| * pressed the power button or closed the lid), or 0 if a shutdown is not |
| * being requested. */ |
| /* NOTE: When we're displaying a screen, pressing the power button |
| * should shut down the computer. We need a way to break out of our |
| * control loop so this can occur cleanly. */ |
| uint32_t VbExIsShutdownRequested(void); |
| |
| /* Expose the BIOS' built-in decompression routine to the vboot wrapper. The |
| * caller must know how large the uncompressed data will be and must manage |
| * that memory. The decompression routine just puts the uncompressed data into |
| * the specified buffer. We pass in the size of the outbuf, and get back the |
| * actual size used. |
| */ |
| VbError_t VbExDecompress(void *inbuf, uint32_t in_size, |
| uint32_t compression_type, |
| void *outbuf, uint32_t *out_size); |
| |
| |
| #endif /* VBOOT_REFERENCE_VBOOT_API_H_ */ |