NVMem.c - platform/external/tpm2 - Gitiles

 // This file was extracted from the TCG Published
 // Trusted Platform Module Library
 // Part 4: Supporting Routines
 // Family "2.0"
 // Level 00 Revision 01.16
 // October 30, 2014

 #include     <memory.h>
 #include     <stdio.h>
 #include     <string.h>

 #include     "PlatformData.h"
 #include     "TpmError.h"
 #include     "assert.h"
 //
 //
 //          Functions
 //
 //          _plat__NvErrors()
 //
 //     This function is used by the simulator to set the error flags in the NV subsystem to simulate an error in the
 //     NV loading process
 //
 LIB_EXPORT void
 _plat__NvErrors(
      BOOL                 recoverable,
      BOOL                 unrecoverable
      )
 {
      s_NV_unrecoverable = unrecoverable;
      s_NV_recoverable = recoverable;
 }
 //
 //
 //          _plat__NVEnable()
 //
 //     Enable NV memory.
 //     This version just pulls in data from a file. In a real TPM, with NV on chip, this function would verify the
 //     integrity of the saved context. If the NV memory was not on chip but was in something like RPMB, the NV
 //     state would be read in, decrypted and integrity checked.
 //     The recovery from an integrity failure depends on where the error occurred. It it was in the state that is
 //     discarded by TPM Reset, then the error is recoverable if the TPM is reset. Otherwise, the TPM must go
 //     into failure mode.
 //
 //     Return Value                      Meaning
 //
 //     0                                 if success
 //     >0                                if receive recoverable error
 //     <0                                if unrecoverable error
 //
 LIB_EXPORT int
 _plat__NVEnable(
      void                *platParameter       // IN: platform specific parameter
      )
 {
      // Start assuming everything is OK
    s_NV_unrecoverable = FALSE;
    s_NV_recoverable = FALSE;
 #ifdef FILE_BACKED_NV
    if(s_NVFile != NULL) return 0;
    // Try to open an exist NVChip file for read/write
    s_NVFile = fopen("NVChip", "r+b");
    if(NULL != s_NVFile)
    {
        // See if the NVChip file is empty
        fseek(s_NVFile, 0, SEEK_END);
        if(0 == ftell(s_NVFile))
            s_NVFile = NULL;
    }
    if(s_NVFile == NULL)
    {
        // Initialize all the byte in the new file to 0
        memset(s_NV, 0, NV_MEMORY_SIZE);
           // If NVChip file does not exist, try to create it for read/write
           s_NVFile = fopen("NVChip", "w+b");
           // Start initialize at the end of new file
           fseek(s_NVFile, 0, SEEK_END);
           // Write 0s to NVChip file
           fwrite(s_NV, 1, NV_MEMORY_SIZE, s_NVFile);
    }
    else
    {
        // If NVChip file exist, assume the size is correct
        fseek(s_NVFile, 0, SEEK_END);
        assert(ftell(s_NVFile) == NV_MEMORY_SIZE);
        // read NV file data to memory
        fseek(s_NVFile, 0, SEEK_SET);
        fread(s_NV, NV_MEMORY_SIZE, 1, s_NVFile);
    }
 #endif
    // NV contents have been read and the error checks have been performed. For
    // simulation purposes, use the signaling interface to indicate if an error is
    // to be simulated and the type of the error.
    if(s_NV_unrecoverable)
        return -1;
    return s_NV_recoverable;
 }
 //
 //
 //         _plat__NVDisable()
 //
 //     Disable NV memory
 //
 LIB_EXPORT void
 _plat__NVDisable(
    void
    )
 {
 #ifdef     FILE_BACKED_NV
    assert(s_NVFile != NULL);
    // Close NV file
    fclose(s_NVFile);
    // Set file handle to NULL
 //
     s_NVFile = NULL;
 #endif
     return;
 }
 //
 //
 //          _plat__IsNvAvailable()
 //
 //      Check if NV is available
 //
 //      Return Value                      Meaning
 //
 //      0                                 NV is available
 //      1                                 NV is not available due to write failure
 //      2                                 NV is not available due to rate limit
 //
 LIB_EXPORT int
 _plat__IsNvAvailable(
     void
     )
 {
     // NV is not available if the TPM is in failure mode
     if(!s_NvIsAvailable)
         return 1;
 #ifdef FILE_BACKED_NV
    if(s_NVFile == NULL)
        return 1;
 #endif
     return 0;
 }
 //
 //
 //          _plat__NvMemoryRead()
 //
 //      Function: Read a chunk of NV memory
 //
 LIB_EXPORT void
 _plat__NvMemoryRead(
     unsigned int           startOffset,       // IN: read start
     unsigned int           size,              // IN: size of bytes to read
     void                  *data               // OUT: data buffer
     )
 {
     assert(startOffset + size <= NV_MEMORY_SIZE);
     // Copy data from RAM
     memcpy(data, &s_NV[startOffset], size);
     return;
 }
 //
 //
 //          _plat__NvIsDifferent()
 //
 //      This function checks to see if the NV is different from the test value. This is so that NV will not be written if
 //      it has not changed.
 //
 //
 //
 //
 //      Return Value                  Meaning
 //
 //      TRUE                          the NV location is different from the test value
 //      FALSE                         the NV location is the same as the test value
 //
 LIB_EXPORT BOOL
 _plat__NvIsDifferent(
    unsigned int        startOffset,       // IN: read start
    unsigned int        size,              // IN: size of bytes to read
    void               *data               // IN: data buffer
    )
 {
    return (memcmp(&s_NV[startOffset], data, size) != 0);
 }
 //
 //
 //         _plat__NvMemoryWrite()
 //
 //      This function is used to update NV memory. The write is to a memory copy of NV. At the end of the
 //      current command, any changes are written to the actual NV memory.
 //
 LIB_EXPORT void
 _plat__NvMemoryWrite(
    unsigned int        startOffset,       // IN: write start
    unsigned int        size,              // IN: size of bytes to write
    void               *data               // OUT: data buffer
    )
 {
    assert(startOffset + size <= NV_MEMORY_SIZE);
    // Copy the data to the NV image
    memcpy(&s_NV[startOffset], data, size);
 }
 //
 //
 //         _plat__NvMemoryMove()
 //
 //      Function: Move a chunk of NV memory from source to destination This function should ensure that if
 //      there overlap, the original data is copied before it is written
 //
 LIB_EXPORT void
 _plat__NvMemoryMove(
    unsigned int        sourceOffset,      // IN: source offset
    unsigned int        destOffset,        // IN: destination offset
    unsigned int        size               // IN: size of data being moved
    )
 {
    assert(sourceOffset + size <= NV_MEMORY_SIZE);
    assert(destOffset + size <= NV_MEMORY_SIZE);
    // Move data in RAM
    memmove(&s_NV[destOffset], &s_NV[sourceOffset], size);
    return;
 }
 //
 //
 //         _plat__NvCommit()
 //
 //      Update NV chip
 //
 //
 //
 //      Return Value                      Meaning
 //
 //      0                                 NV write success
 //      non-0                             NV write fail
 //
 LIB_EXPORT int
 _plat__NvCommit(
    void
    )
 {
 #ifdef FILE_BACKED_NV
    // If NV file is not available, return failure
    if(s_NVFile == NULL)
        return 1;
    // Write RAM data to NV
    fseek(s_NVFile, 0, SEEK_SET);
    fwrite(s_NV, 1, NV_MEMORY_SIZE, s_NVFile);
    return 0;
 #else
    return 0;
 #endif
 }
 //
 //
 //       _plat__SetNvAvail()
 //
 //      Set the current NV state to available. This function is for testing purpose only. It is not part of the
 //      platform NV logic
 //
 LIB_EXPORT void
 _plat__SetNvAvail(
    void
    )
 {
    s_NvIsAvailable = TRUE;
    return;
 }
 //
 //
 //       _plat__ClearNvAvail()
 //
 //      Set the current NV state to unavailable. This function is for testing purpose only. It is not part of the
 //      platform NV logic
 //
 LIB_EXPORT void
 _plat__ClearNvAvail(
    void
    )
 {
    s_NvIsAvailable = FALSE;
    return;
 }
	// This file was extracted from the TCG Published
	// Trusted Platform Module Library
	// Part 4: Supporting Routines
	// Family "2.0"
	// Level 00 Revision 01.16
	// October 30, 2014

	#include <memory.h>
	#include <stdio.h>
	#include <string.h>

	#include "PlatformData.h"
	#include "TpmError.h"
	#include "assert.h"
	//
	//
	// Functions
	//
	// _plat__NvErrors()
	//
	// This function is used by the simulator to set the error flags in the NV subsystem to simulate an error in the
	// NV loading process
	//
	LIB_EXPORT void
	_plat__NvErrors(
	BOOL recoverable,
	BOOL unrecoverable
	)
	{
	s_NV_unrecoverable = unrecoverable;
	s_NV_recoverable = recoverable;
	}
	//
	//
	// _plat__NVEnable()
	//
	// Enable NV memory.
	// This version just pulls in data from a file. In a real TPM, with NV on chip, this function would verify the
	// integrity of the saved context. If the NV memory was not on chip but was in something like RPMB, the NV
	// state would be read in, decrypted and integrity checked.
	// The recovery from an integrity failure depends on where the error occurred. It it was in the state that is
	// discarded by TPM Reset, then the error is recoverable if the TPM is reset. Otherwise, the TPM must go
	// into failure mode.
	//
	// Return Value Meaning
	//
	// 0 if success
	// >0 if receive recoverable error
	// <0 if unrecoverable error
	//
	LIB_EXPORT int
	_plat__NVEnable(
	void *platParameter // IN: platform specific parameter
	)
	{
	// Start assuming everything is OK
	s_NV_unrecoverable = FALSE;
	s_NV_recoverable = FALSE;
	#ifdef FILE_BACKED_NV
	if(s_NVFile != NULL) return 0;
	// Try to open an exist NVChip file for read/write
	s_NVFile = fopen("NVChip", "r+b");
	if(NULL != s_NVFile)
	{
	// See if the NVChip file is empty
	fseek(s_NVFile, 0, SEEK_END);
	if(0 == ftell(s_NVFile))
	s_NVFile = NULL;
	}
	if(s_NVFile == NULL)
	{
	// Initialize all the byte in the new file to 0
	memset(s_NV, 0, NV_MEMORY_SIZE);
	// If NVChip file does not exist, try to create it for read/write
	s_NVFile = fopen("NVChip", "w+b");
	// Start initialize at the end of new file
	fseek(s_NVFile, 0, SEEK_END);
	// Write 0s to NVChip file
	fwrite(s_NV, 1, NV_MEMORY_SIZE, s_NVFile);
	}
	else
	{
	// If NVChip file exist, assume the size is correct
	fseek(s_NVFile, 0, SEEK_END);
	assert(ftell(s_NVFile) == NV_MEMORY_SIZE);
	// read NV file data to memory
	fseek(s_NVFile, 0, SEEK_SET);
	fread(s_NV, NV_MEMORY_SIZE, 1, s_NVFile);
	}
	#endif
	// NV contents have been read and the error checks have been performed. For
	// simulation purposes, use the signaling interface to indicate if an error is
	// to be simulated and the type of the error.
	if(s_NV_unrecoverable)
	return -1;
	return s_NV_recoverable;
	}
	//
	//
	// _plat__NVDisable()
	//
	// Disable NV memory
	//
	LIB_EXPORT void
	_plat__NVDisable(
	void
	)
	{
	#ifdef FILE_BACKED_NV
	assert(s_NVFile != NULL);
	// Close NV file
	fclose(s_NVFile);
	// Set file handle to NULL
	//
	s_NVFile = NULL;
	#endif
	return;
	}
	//
	//
	// _plat__IsNvAvailable()
	//
	// Check if NV is available
	//
	// Return Value Meaning
	//
	// 0 NV is available
	// 1 NV is not available due to write failure
	// 2 NV is not available due to rate limit
	//
	LIB_EXPORT int
	_plat__IsNvAvailable(
	void
	)
	{
	// NV is not available if the TPM is in failure mode
	if(!s_NvIsAvailable)
	return 1;
	#ifdef FILE_BACKED_NV
	if(s_NVFile == NULL)
	return 1;
	#endif
	return 0;
	}
	//
	//
	// _plat__NvMemoryRead()
	//
	// Function: Read a chunk of NV memory
	//
	LIB_EXPORT void
	_plat__NvMemoryRead(
	unsigned int startOffset, // IN: read start
	unsigned int size, // IN: size of bytes to read
	void *data // OUT: data buffer
	)
	{
	assert(startOffset + size <= NV_MEMORY_SIZE);
	// Copy data from RAM
	memcpy(data, &s_NV[startOffset], size);
	return;
	}
	//
	//
	// _plat__NvIsDifferent()
	//
	// This function checks to see if the NV is different from the test value. This is so that NV will not be written if
	// it has not changed.
	//
	//
	//
	//
	// Return Value Meaning
	//
	// TRUE the NV location is different from the test value
	// FALSE the NV location is the same as the test value
	//
	LIB_EXPORT BOOL
	_plat__NvIsDifferent(
	unsigned int startOffset, // IN: read start
	unsigned int size, // IN: size of bytes to read
	void *data // IN: data buffer
	)
	{
	return (memcmp(&s_NV[startOffset], data, size) != 0);
	}
	//
	//
	// _plat__NvMemoryWrite()
	//
	// This function is used to update NV memory. The write is to a memory copy of NV. At the end of the
	// current command, any changes are written to the actual NV memory.
	//
	LIB_EXPORT void
	_plat__NvMemoryWrite(
	unsigned int startOffset, // IN: write start
	unsigned int size, // IN: size of bytes to write
	void *data // OUT: data buffer
	)
	{
	assert(startOffset + size <= NV_MEMORY_SIZE);
	// Copy the data to the NV image
	memcpy(&s_NV[startOffset], data, size);
	}
	//
	//
	// _plat__NvMemoryMove()
	//
	// Function: Move a chunk of NV memory from source to destination This function should ensure that if
	// there overlap, the original data is copied before it is written
	//
	LIB_EXPORT void
	_plat__NvMemoryMove(
	unsigned int sourceOffset, // IN: source offset
	unsigned int destOffset, // IN: destination offset
	unsigned int size // IN: size of data being moved
	)
	{
	assert(sourceOffset + size <= NV_MEMORY_SIZE);
	assert(destOffset + size <= NV_MEMORY_SIZE);
	// Move data in RAM
	memmove(&s_NV[destOffset], &s_NV[sourceOffset], size);
	return;
	}
	//
	//
	// _plat__NvCommit()
	//
	// Update NV chip
	//
	//
	//
	// Return Value Meaning
	//
	// 0 NV write success
	// non-0 NV write fail
	//
	LIB_EXPORT int
	_plat__NvCommit(
	void
	)
	{
	#ifdef FILE_BACKED_NV
	// If NV file is not available, return failure
	if(s_NVFile == NULL)
	return 1;
	// Write RAM data to NV
	fseek(s_NVFile, 0, SEEK_SET);
	fwrite(s_NV, 1, NV_MEMORY_SIZE, s_NVFile);
	return 0;
	#else
	return 0;
	#endif
	}
	//
	//
	// _plat__SetNvAvail()
	//
	// Set the current NV state to available. This function is for testing purpose only. It is not part of the
	// platform NV logic
	//
	LIB_EXPORT void
	_plat__SetNvAvail(
	void
	)
	{
	s_NvIsAvailable = TRUE;
	return;
	}
	//
	//
	// _plat__ClearNvAvail()
	//
	// Set the current NV state to unavailable. This function is for testing purpose only. It is not part of the
	// platform NV logic
	//
	LIB_EXPORT void
	_plat__ClearNvAvail(
	void
	)
	{
	s_NvIsAvailable = FALSE;
	return;
	}