gptfdisk/mbr.cc - nest-cam/4320010/gptfdisk - Git at Google

 /* mbr.cc -- Functions for loading, saving, and manipulating legacy MBR partition
    data. */

 /* Initial coding by Rod Smith, January to February, 2009 */

 /* This program is copyright (c) 2009-2013 by Roderick W. Smith. It is distributed
   under the terms of the GNU GPL version 2, as detailed in the COPYING file. */

 #define __STDC_LIMIT_MACROS
 #ifndef __STDC_CONSTANT_MACROS
 #define __STDC_CONSTANT_MACROS
 #endif

 #include <stdio.h>
 #include <stdlib.h>
 #include <stdint.h>
 #include <fcntl.h>
 #include <string.h>
 #include <time.h>
 #include <sys/stat.h>
 #include <errno.h>
 #include <iostream>
 #include "mbr.h"

 using namespace std;

 /****************************************
  *                                      *
  * MBRData class and related structures *
  *                                      *
  ****************************************/

 MBRData::~MBRData(void) {
 } // MBRData destructor

 /* // Assignment operator -- copy entire set of MBR data.
 MBRData & MBRData::operator=(const MBRData & orig) {
    BasicMBRData::operator=(orig);
    return *this;
 } // MBRData::operator=() */

 // Assignment operator -- copy entire set of MBR data.
 MBRData & MBRData::operator=(const BasicMBRData & orig) {
    BasicMBRData::operator=(orig);
    return *this;
 } // MBRData::operator=()

 /*****************************************************
  *                                                   *
  * Functions to create, delete, or change partitions *
  *                                                   *
  *****************************************************/

 // Create a protective MBR. Clears the boot loader area if clearBoot > 0.
 void MBRData::MakeProtectiveMBR(int clearBoot) {

    EmptyMBR(clearBoot);

    // Initialize variables
    nulls = 0;
    MBRSignature = MBR_SIGNATURE;
    diskSignature = UINT32_C(0);

    partitions[0].SetStatus(0); // Flag the protective part. as unbootable

    partitions[0].SetType(UINT8_C(0xEE));
    if (diskSize < UINT32_MAX) { // If the disk is under 2TiB
       partitions[0].SetLocation(UINT32_C(1), (uint32_t) diskSize - UINT32_C(1));
    } else { // disk is too big to represent, so fake it...
       partitions[0].SetLocation(UINT32_C(1), UINT32_MAX);
    } // if/else
    partitions[0].SetInclusion(PRIMARY);

    state = gpt;
 } // MBRData::MakeProtectiveMBR()

 // Optimizes the size of the 0xEE (EFI GPT) partition
 void MBRData::OptimizeEESize(void) {
    int i, typeFlag = 0;
    uint64_t after;

    for (i = 0; i < 4; i++) {
       // Check for non-empty and non-0xEE partitions
       if ((partitions[i].GetType() != 0xEE) && (partitions[i].GetType() != 0x00))
          typeFlag++;
       if (partitions[i].GetType() == 0xEE) {
          // Blank space before this partition; fill it....
          if (SectorUsedAs(partitions[i].GetStartLBA() - 1, 4) == NONE) {
             partitions[i].SetStartLBA(FindFirstInFree(partitions[i].GetStartLBA() - 1));
          } // if
          // Blank space after this partition; fill it....
          after = partitions[i].GetStartLBA() + partitions[i].GetLengthLBA();
          if (SectorUsedAs(after, 4) == NONE) {
             partitions[i].SetLengthLBA(FindLastInFree(after) - partitions[i].GetStartLBA() + 1);
          } // if free space after
          if (after > diskSize) {
             if (diskSize < UINT32_MAX) { // If the disk is under 2TiB
                partitions[i].SetLengthLBA((uint32_t) diskSize - partitions[i].GetStartLBA());
             } else { // disk is too big to represent, so fake it...
                partitions[i].SetLengthLBA(UINT32_MAX - partitions[i].GetStartLBA());
             } // if/else
          } // if protective partition is too big
          RecomputeCHS(i);
       } // if partition is 0xEE
    } // for partition loop
    if (typeFlag == 0) { // No non-hybrid partitions found
       MakeProtectiveMBR(); // ensure it's a fully compliant protective MBR.
    } // if
 } // MBRData::OptimizeEESize()

 // Delete a partition if one exists at the specified location.
 // Returns 1 if a partition was deleted, 0 otherwise....
 // Used to help keep GPT & hybrid MBR partitions in sync....
 int MBRData::DeleteByLocation(uint64_t start64, uint64_t length64) {
    uint32_t start32, length32;
    int i, deleted = 0;

    if ((start64 < UINT32_MAX) && (length64 < UINT32_MAX)) {
       start32 = (uint32_t) start64;
       length32 = (uint32_t) length64;
       for (i = 0; i < MAX_MBR_PARTS; i++) {
          if ((partitions[i].GetType() != 0xEE) && (partitions[i].GetStartLBA() == start32)
              && (partitions[i].GetLengthLBA() == length32)) {
             DeletePartition(i);
          if (state == hybrid)
             OptimizeEESize();
          deleted = 1;
          } // if (match found)
       } // for i (partition scan)
    } // if (hybrid & GPT partition < 2TiB)
    return deleted;
 } // MBRData::DeleteByLocation()

 /******************************************************
  *                                                    *
  * Functions that extract data on specific partitions *
  *                                                    *
  ******************************************************/

 // Return the MBR data as a GPT partition....
 GPTPart MBRData::AsGPT(int i) {
    MBRPart* origPart;
    GPTPart newPart;
    uint8_t origType;
    uint64_t firstSector, lastSector;

    newPart.BlankPartition();
    origPart = GetPartition(i);
    if (origPart != NULL) {
       origType = origPart->GetType();

       // don't convert extended, hybrid protective, or null (non-existent)
       // partitions (Note similar protection is in GPTData::XFormPartitions(),
       // but I want it here too in case I call this function in another
       // context in the future....)
       if ((origType != 0x05) && (origType != 0x0f) && (origType != 0x85) &&
           (origType != 0x00) && (origType != 0xEE)) {
          firstSector = (uint64_t) origPart->GetStartLBA();
          newPart.SetFirstLBA(firstSector);
          lastSector = (uint64_t) origPart->GetLastLBA();
          newPart.SetLastLBA(lastSector);
          newPart.SetType(((uint16_t) origType) * 0x0100);
          newPart.RandomizeUniqueGUID();
          newPart.SetAttributes(0);
          newPart.SetName(newPart.GetTypeName());
       } // if not extended, protective, or non-existent
    } // if (origPart != NULL)
    return newPart;
 } // MBRData::AsGPT()
	/* mbr.cc -- Functions for loading, saving, and manipulating legacy MBR partition
	data. */

	/* Initial coding by Rod Smith, January to February, 2009 */

	/* This program is copyright (c) 2009-2013 by Roderick W. Smith. It is distributed
	under the terms of the GNU GPL version 2, as detailed in the COPYING file. */

	#define __STDC_LIMIT_MACROS
	#ifndef __STDC_CONSTANT_MACROS
	#define __STDC_CONSTANT_MACROS
	#endif

	#include <stdio.h>
	#include <stdlib.h>
	#include <stdint.h>
	#include <fcntl.h>
	#include <string.h>
	#include <time.h>
	#include <sys/stat.h>
	#include <errno.h>
	#include <iostream>
	#include "mbr.h"

	using namespace std;

	/****************************************
	* *
	* MBRData class and related structures *
	* *
	****************************************/

	MBRData::~MBRData(void) {
	} // MBRData destructor

	/* // Assignment operator -- copy entire set of MBR data.
	MBRData & MBRData::operator=(const MBRData & orig) {
	BasicMBRData::operator=(orig);
	return *this;
	} // MBRData::operator=() */

	// Assignment operator -- copy entire set of MBR data.
	MBRData & MBRData::operator=(const BasicMBRData & orig) {
	BasicMBRData::operator=(orig);
	return *this;
	} // MBRData::operator=()

	/*****************************************************
	* *
	* Functions to create, delete, or change partitions *
	* *
	*****************************************************/

	// Create a protective MBR. Clears the boot loader area if clearBoot > 0.
	void MBRData::MakeProtectiveMBR(int clearBoot) {

	EmptyMBR(clearBoot);

	// Initialize variables
	nulls = 0;
	MBRSignature = MBR_SIGNATURE;
	diskSignature = UINT32_C(0);

	partitions[0].SetStatus(0); // Flag the protective part. as unbootable

	partitions[0].SetType(UINT8_C(0xEE));
	if (diskSize < UINT32_MAX) { // If the disk is under 2TiB
	partitions[0].SetLocation(UINT32_C(1), (uint32_t) diskSize - UINT32_C(1));
	} else { // disk is too big to represent, so fake it...
	partitions[0].SetLocation(UINT32_C(1), UINT32_MAX);
	} // if/else
	partitions[0].SetInclusion(PRIMARY);

	state = gpt;
	} // MBRData::MakeProtectiveMBR()

	// Optimizes the size of the 0xEE (EFI GPT) partition
	void MBRData::OptimizeEESize(void) {
	int i, typeFlag = 0;
	uint64_t after;

	for (i = 0; i < 4; i++) {
	// Check for non-empty and non-0xEE partitions
	if ((partitions[i].GetType() != 0xEE) && (partitions[i].GetType() != 0x00))
	typeFlag++;
	if (partitions[i].GetType() == 0xEE) {
	// Blank space before this partition; fill it....
	if (SectorUsedAs(partitions[i].GetStartLBA() - 1, 4) == NONE) {
	partitions[i].SetStartLBA(FindFirstInFree(partitions[i].GetStartLBA() - 1));
	} // if
	// Blank space after this partition; fill it....
	after = partitions[i].GetStartLBA() + partitions[i].GetLengthLBA();
	if (SectorUsedAs(after, 4) == NONE) {
	partitions[i].SetLengthLBA(FindLastInFree(after) - partitions[i].GetStartLBA() + 1);
	} // if free space after
	if (after > diskSize) {
	if (diskSize < UINT32_MAX) { // If the disk is under 2TiB
	partitions[i].SetLengthLBA((uint32_t) diskSize - partitions[i].GetStartLBA());
	} else { // disk is too big to represent, so fake it...
	partitions[i].SetLengthLBA(UINT32_MAX - partitions[i].GetStartLBA());
	} // if/else
	} // if protective partition is too big
	RecomputeCHS(i);
	} // if partition is 0xEE
	} // for partition loop
	if (typeFlag == 0) { // No non-hybrid partitions found
	MakeProtectiveMBR(); // ensure it's a fully compliant protective MBR.
	} // if
	} // MBRData::OptimizeEESize()

	// Delete a partition if one exists at the specified location.
	// Returns 1 if a partition was deleted, 0 otherwise....
	// Used to help keep GPT & hybrid MBR partitions in sync....
	int MBRData::DeleteByLocation(uint64_t start64, uint64_t length64) {
	uint32_t start32, length32;
	int i, deleted = 0;

	if ((start64 < UINT32_MAX) && (length64 < UINT32_MAX)) {
	start32 = (uint32_t) start64;
	length32 = (uint32_t) length64;
	for (i = 0; i < MAX_MBR_PARTS; i++) {
	if ((partitions[i].GetType() != 0xEE) && (partitions[i].GetStartLBA() == start32)
	&& (partitions[i].GetLengthLBA() == length32)) {
	DeletePartition(i);
	if (state == hybrid)
	OptimizeEESize();
	deleted = 1;
	} // if (match found)
	} // for i (partition scan)
	} // if (hybrid & GPT partition < 2TiB)
	return deleted;
	} // MBRData::DeleteByLocation()

	/******************************************************
	* *
	* Functions that extract data on specific partitions *
	* *
	******************************************************/

	// Return the MBR data as a GPT partition....
	GPTPart MBRData::AsGPT(int i) {
	MBRPart* origPart;
	GPTPart newPart;
	uint8_t origType;
	uint64_t firstSector, lastSector;

	newPart.BlankPartition();
	origPart = GetPartition(i);
	if (origPart != NULL) {
	origType = origPart->GetType();

	// don't convert extended, hybrid protective, or null (non-existent)
	// partitions (Note similar protection is in GPTData::XFormPartitions(),
	// but I want it here too in case I call this function in another
	// context in the future....)
	if ((origType != 0x05) && (origType != 0x0f) && (origType != 0x85) &&
	(origType != 0x00) && (origType != 0xEE)) {
	firstSector = (uint64_t) origPart->GetStartLBA();
	newPart.SetFirstLBA(firstSector);
	lastSector = (uint64_t) origPart->GetLastLBA();
	newPart.SetLastLBA(lastSector);
	newPart.SetType(((uint16_t) origType) * 0x0100);
	newPart.RandomizeUniqueGUID();
	newPart.SetAttributes(0);
	newPart.SetName(newPart.GetTypeName());
	} // if not extended, protective, or non-existent
	} // if (origPart != NULL)
	return newPart;
	} // MBRData::AsGPT()