firmware/lib/cgptlib/cgptlib.c - mirrors/cros/chromiumos/platform/vboot_reference - Git at Google

 /* Copyright (c) 2011 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 "cgptlib.h"
 #include "cgptlib_internal.h"
 #include "crc32.h"
 #include "gpt.h"
 #include "utility.h"
 #include "vboot_api.h"

 int GptInit(GptData *gpt) {
   int retval;

   gpt->modified = 0;
   gpt->current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
   gpt->current_priority = 999;

   retval = GptSanityCheck(gpt);
   if (GPT_SUCCESS != retval) {
     VBDEBUG(("GptInit() failed sanity check\n"));
     return retval;
   }

   GptRepair(gpt);
   return GPT_SUCCESS;
 }


 int GptNextKernelEntry(GptData* gpt, uint64_t* start_sector, uint64_t* size) {
   GptHeader* header = (GptHeader*)gpt->primary_header;
   GptEntry* entries = (GptEntry*)gpt->primary_entries;
   GptEntry* e;
   int new_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
   int new_prio = 0;
   uint32_t i;

   /* If we already found a kernel, continue the scan at the current
    * kernel's prioity, in case there is another kernel with the same
    * priority. */
   if (gpt->current_kernel != CGPT_KERNEL_ENTRY_NOT_FOUND) {
     for (i = gpt->current_kernel + 1; i < header->number_of_entries; i++) {
       e = entries + i;
       if (!IsKernelEntry(e))
         continue;
       VBDEBUG(("GptNextKernelEntry looking at same prio partition %d\n", i+1));
       VBDEBUG(("GptNextKernelEntry s%d t%d p%d\n",
                GetEntrySuccessful(e), GetEntryTries(e), GetEntryPriority(e)));
       if (!(GetEntrySuccessful(e) || GetEntryTries(e)))
         continue;
       if (GetEntryPriority(e) == gpt->current_priority) {
         gpt->current_kernel = i;
         *start_sector = e->starting_lba;
         *size = e->ending_lba - e->starting_lba + 1;
         VBDEBUG(("GptNextKernelEntry likes that one\n"));
         return GPT_SUCCESS;
       }
     }
   }

   /* We're still here, so scan for the remaining kernel with the
    * highest priority less than the previous attempt. */
   for (i = 0, e = entries; i < header->number_of_entries; i++, e++) {
     int current_prio = GetEntryPriority(e);
     if (!IsKernelEntry(e))
       continue;
     VBDEBUG(("GptNextKernelEntry looking at new prio partition %d\n", i+1));
     VBDEBUG(("GptNextKernelEntry s%d t%d p%d\n",
              GetEntrySuccessful(e), GetEntryTries(e), GetEntryPriority(e)));
     if (!(GetEntrySuccessful(e) || GetEntryTries(e)))
       continue;
     if (current_prio >= gpt->current_priority)
       continue;  /* Already returned this kernel in a previous call */
     if (current_prio > new_prio) {
       new_kernel = i;
       new_prio = current_prio;
     }
   }

   /* Save what we found.  Note that if we didn't find a new kernel,
    * new_prio will still be -1, so future calls to this function will
    * also fail. */
   gpt->current_kernel = new_kernel;
   gpt->current_priority = new_prio;

   if (CGPT_KERNEL_ENTRY_NOT_FOUND == new_kernel) {
     VBDEBUG(("GptNextKernelEntry no more kernels\n"));
     return GPT_ERROR_NO_VALID_KERNEL;
   }

   VBDEBUG(("GptNextKernelEntry likes partition %d\n", new_kernel+1));
   e = entries + new_kernel;
   *start_sector = e->starting_lba;
   *size = e->ending_lba - e->starting_lba + 1;
   return GPT_SUCCESS;
 }


 int GptUpdateKernelEntry(GptData* gpt, uint32_t update_type) {
   GptHeader* header = (GptHeader*)gpt->primary_header;
   GptEntry* entries = (GptEntry*)gpt->primary_entries;
   GptEntry* e = entries + gpt->current_kernel;
   uint16_t previous_attr = e->attrs.fields.gpt_att;

   if (gpt->current_kernel == CGPT_KERNEL_ENTRY_NOT_FOUND)
     return GPT_ERROR_INVALID_UPDATE_TYPE;
   if (!IsKernelEntry(e))
     return GPT_ERROR_INVALID_UPDATE_TYPE;

   switch (update_type) {
     case GPT_UPDATE_ENTRY_TRY: {
       /* Used up a try */
       int tries;
       if (GetEntrySuccessful(e))
         return GPT_SUCCESS;  /* Successfully booted this partition, so
                               * tries field is ignored. */
       tries = GetEntryTries(e);
       if (tries > 1) {
         /* Still have tries left */
         SetEntryTries(e, tries - 1);
         break;
       }
       /* Out of tries, so drop through and mark partition bad. */
     }
     case GPT_UPDATE_ENTRY_BAD: {
       /* Giving up on this partition entirely. */
       if (!GetEntrySuccessful(e)) {
         /* Only clear tries and priority if the successful bit is not set. */
         e->attrs.fields.gpt_att = previous_attr & ~(
             CGPT_ATTRIBUTE_TRIES_MASK |
             CGPT_ATTRIBUTE_PRIORITY_MASK);
       }
       break;
     }
     default:
       return GPT_ERROR_INVALID_UPDATE_TYPE;
   }

   /* If no change to attributes, we're done */
   if (e->attrs.fields.gpt_att == previous_attr)
     return GPT_SUCCESS;

   /* Update the CRCs */
   header->entries_crc32 = Crc32((const uint8_t *)entries,
                                 header->size_of_entry *
                                 header->number_of_entries);
   header->header_crc32 = HeaderCrc(header);
   gpt->modified |= GPT_MODIFIED_HEADER1 | GPT_MODIFIED_ENTRIES1;

   /* Use the repair function to update the other copy of the GPT.
    * This is a tad inefficient, but is much faster than the disk I/O
    * to update the GPT on disk so it doesn't matter. */
   gpt->valid_headers = MASK_PRIMARY;
   gpt->valid_entries = MASK_PRIMARY;
   GptRepair(gpt);

   return GPT_SUCCESS;
 }
	/* Copyright (c) 2011 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 "cgptlib.h"
	#include "cgptlib_internal.h"
	#include "crc32.h"
	#include "gpt.h"
	#include "utility.h"
	#include "vboot_api.h"

	int GptInit(GptData *gpt) {
	int retval;

	gpt->modified = 0;
	gpt->current_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
	gpt->current_priority = 999;

	retval = GptSanityCheck(gpt);
	if (GPT_SUCCESS != retval) {
	VBDEBUG(("GptInit() failed sanity check\n"));
	return retval;
	}

	GptRepair(gpt);
	return GPT_SUCCESS;
	}


	int GptNextKernelEntry(GptData* gpt, uint64_t* start_sector, uint64_t* size) {
	GptHeader* header = (GptHeader*)gpt->primary_header;
	GptEntry* entries = (GptEntry*)gpt->primary_entries;
	GptEntry* e;
	int new_kernel = CGPT_KERNEL_ENTRY_NOT_FOUND;
	int new_prio = 0;
	uint32_t i;

	/* If we already found a kernel, continue the scan at the current
	* kernel's prioity, in case there is another kernel with the same
	* priority. */
	if (gpt->current_kernel != CGPT_KERNEL_ENTRY_NOT_FOUND) {
	for (i = gpt->current_kernel + 1; i < header->number_of_entries; i++) {
	e = entries + i;
	if (!IsKernelEntry(e))
	continue;
	VBDEBUG(("GptNextKernelEntry looking at same prio partition %d\n", i+1));
	VBDEBUG(("GptNextKernelEntry s%d t%d p%d\n",
	GetEntrySuccessful(e), GetEntryTries(e), GetEntryPriority(e)));
	if (!(GetEntrySuccessful(e) \|\| GetEntryTries(e)))
	continue;
	if (GetEntryPriority(e) == gpt->current_priority) {
	gpt->current_kernel = i;
	*start_sector = e->starting_lba;
	*size = e->ending_lba - e->starting_lba + 1;
	VBDEBUG(("GptNextKernelEntry likes that one\n"));
	return GPT_SUCCESS;
	}
	}
	}

	/* We're still here, so scan for the remaining kernel with the
	* highest priority less than the previous attempt. */
	for (i = 0, e = entries; i < header->number_of_entries; i++, e++) {
	int current_prio = GetEntryPriority(e);
	if (!IsKernelEntry(e))
	continue;
	VBDEBUG(("GptNextKernelEntry looking at new prio partition %d\n", i+1));
	VBDEBUG(("GptNextKernelEntry s%d t%d p%d\n",
	GetEntrySuccessful(e), GetEntryTries(e), GetEntryPriority(e)));
	if (!(GetEntrySuccessful(e) \|\| GetEntryTries(e)))
	continue;
	if (current_prio >= gpt->current_priority)
	continue; /* Already returned this kernel in a previous call */
	if (current_prio > new_prio) {
	new_kernel = i;
	new_prio = current_prio;
	}
	}

	/* Save what we found. Note that if we didn't find a new kernel,
	* new_prio will still be -1, so future calls to this function will
	* also fail. */
	gpt->current_kernel = new_kernel;
	gpt->current_priority = new_prio;

	if (CGPT_KERNEL_ENTRY_NOT_FOUND == new_kernel) {
	VBDEBUG(("GptNextKernelEntry no more kernels\n"));
	return GPT_ERROR_NO_VALID_KERNEL;
	}

	VBDEBUG(("GptNextKernelEntry likes partition %d\n", new_kernel+1));
	e = entries + new_kernel;
	*start_sector = e->starting_lba;
	*size = e->ending_lba - e->starting_lba + 1;
	return GPT_SUCCESS;
	}


	int GptUpdateKernelEntry(GptData* gpt, uint32_t update_type) {
	GptHeader* header = (GptHeader*)gpt->primary_header;
	GptEntry* entries = (GptEntry*)gpt->primary_entries;
	GptEntry* e = entries + gpt->current_kernel;
	uint16_t previous_attr = e->attrs.fields.gpt_att;

	if (gpt->current_kernel == CGPT_KERNEL_ENTRY_NOT_FOUND)
	return GPT_ERROR_INVALID_UPDATE_TYPE;
	if (!IsKernelEntry(e))
	return GPT_ERROR_INVALID_UPDATE_TYPE;

	switch (update_type) {
	case GPT_UPDATE_ENTRY_TRY: {
	/* Used up a try */
	int tries;
	if (GetEntrySuccessful(e))
	return GPT_SUCCESS; /* Successfully booted this partition, so
	* tries field is ignored. */
	tries = GetEntryTries(e);
	if (tries > 1) {
	/* Still have tries left */
	SetEntryTries(e, tries - 1);
	break;
	}
	/* Out of tries, so drop through and mark partition bad. */
	}
	case GPT_UPDATE_ENTRY_BAD: {
	/* Giving up on this partition entirely. */
	if (!GetEntrySuccessful(e)) {
	/* Only clear tries and priority if the successful bit is not set. */
	e->attrs.fields.gpt_att = previous_attr & ~(
	CGPT_ATTRIBUTE_TRIES_MASK \|
	CGPT_ATTRIBUTE_PRIORITY_MASK);
	}
	break;
	}
	default:
	return GPT_ERROR_INVALID_UPDATE_TYPE;
	}

	/* If no change to attributes, we're done */
	if (e->attrs.fields.gpt_att == previous_attr)
	return GPT_SUCCESS;

	/* Update the CRCs */
	header->entries_crc32 = Crc32((const uint8_t *)entries,
	header->size_of_entry *
	header->number_of_entries);
	header->header_crc32 = HeaderCrc(header);
	gpt->modified \|= GPT_MODIFIED_HEADER1 \| GPT_MODIFIED_ENTRIES1;

	/* Use the repair function to update the other copy of the GPT.
	* This is a tad inefficient, but is much faster than the disk I/O
	* to update the GPT on disk so it doesn't matter. */
	gpt->valid_headers = MASK_PRIMARY;
	gpt->valid_entries = MASK_PRIMARY;
	GptRepair(gpt);

	return GPT_SUCCESS;
	}