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// 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
#ifndef _CRYPT_PRI_H
#define _CRYPT_PRI_H
#include <stddef.h>
#include "TpmBuildSwitches.h"
#include "BaseTypes.h"
#include "TpmError.h"
#include "swap.h"
#include "Implementation.h"
#include "TPM_Types.h"
//#include "TPMB.h"
#include "bool.h"
#include "Platform.h"
#ifndef NULL
#define NULL 0
#endif
typedef UINT16 NUMBYTES; // When a size is a number of bytes
typedef UINT32 NUMDIGITS; // When a size is a number of "digits"
// General Purpose Macros
//
#ifndef MAX
# define MAX(a, b) ((a) > (b) ? (a) : b)
#endif
//
// This is the definition of a bit array with one bit per algorithm
//
typedef BYTE ALGORITHM_VECTOR[(ALG_LAST_VALUE + 7) / 8];
//
//
// Self-test
//
// This structure is used to contain self-test tracking information for the crypto engine. Each of the major
// modules is given a 32-bit value in which it may maintain its own self test information. The convention for
// this state is that when all of the bits in this structure are 0, all functions need to be tested.
//
typedef struct {
UINT32 rng;
UINT32 hash;
UINT32 sym;
#ifdef TPM_ALG_RSA
UINT32 rsa;
#endif
#ifdef TPM_ALG_ECC
UINT32 ecc;
#endif
} CRYPTO_SELF_TEST_STATE;
//
//
// Hash-related Structures
//
typedef struct {
const TPM_ALG_ID alg;
const NUMBYTES digestSize;
const NUMBYTES blockSize;
const NUMBYTES derSize;
const BYTE der[20];
} HASH_INFO;
//
// This value will change with each implementation. The value of 16 is used to account for any slop in the
// context values. The overall size needs to be as large as any of the hash contexts. The structure needs to
// start on an alignment boundary and be an even multiple of the alignment
//
#define ALIGNED_SIZE(x, b) ((((x) + (b) - 1) / (b)) * (b))
#define MAX_HASH_STATE_SIZE ((2 * MAX_HASH_BLOCK_SIZE) + 16)
#define MAX_HASH_STATE_SIZE_ALIGNED \
ALIGNED_SIZE(MAX_HASH_STATE_SIZE, CRYPTO_ALIGNMENT)
//
// This is an byte array that will hold any of the hash contexts.
//
typedef CRYPTO_ALIGNED BYTE ALIGNED_HASH_STATE[MAX_HASH_STATE_SIZE_ALIGNED];
//
// Macro to align an address to the next higher size
//
#define AlignPointer(address, align) \
((((intptr_t)&(address)) + (align - 1)) & ~(align - 1))
//
// Macro to test alignment
//
#define IsAddressAligned(address, align) \
(((intptr_t)(address) & (align - 1)) == 0)
//
// This is the structure that is used for passing a context into the hashing functions. It should be the same
// size as the function context used within the hashing functions. This is checked when the hash function is
// initialized. This version uses a new layout for the contexts and a different definition. The state buffer is an
// array of HASH_UNIT values so that a decent compiler will put the structure on a HASH_UNIT boundary.
// If the structure is not properly aligned, the code that manipulates the structure will copy to a properly
// aligned structure before it is used and copy the result back. This just makes things slower.
//
typedef struct _HASH_STATE
{
ALIGNED_HASH_STATE state;
TPM_ALG_ID hashAlg;
} CPRI_HASH_STATE, *PCPRI_HASH_STATE;
extern const HASH_INFO g_hashData[HASH_COUNT + 1];
//
// This is for the external hash state. This implementation assumes that the size of the exported hash state
// is no larger than the internal hash state. There is a compile-time check to make sure that this is true.
//
typedef struct {
ALIGNED_HASH_STATE buffer;
TPM_ALG_ID hashAlg;
} EXPORT_HASH_STATE;
typedef enum {
IMPORT_STATE, // Converts externally formatted state to internal
EXPORT_STATE // Converts internal formatted state to external
} IMPORT_EXPORT;
//
// Values and structures for the random number generator. These values are defined in this header file so
// that the size of the RNG state can be known to TPM.lib. This allows the allocation of some space in NV
// memory for the state to be stored on an orderly shutdown. The GET_PUT enum is used by
// _cpri__DrbgGetPutState() to indicate the direction of data flow.
//
typedef enum {
GET_STATE, // Get the state to save to NV
PUT_STATE // Restore the state from NV
} GET_PUT;
//
// The DRBG based on a symmetric block cipher is defined by three values,
// a) the key size
// b) the block size (the IV size)
// c) the symmetric algorithm
//
#define DRBG_KEY_SIZE_BITS MAX_AES_KEY_BITS
#define DRBG_IV_SIZE_BITS (MAX_AES_BLOCK_SIZE_BYTES * 8)
#define DRBG_ALGORITHM TPM_ALG_AES
#if ((DRBG_KEY_SIZE_BITS % 8) != 0) || ((DRBG_IV_SIZE_BITS % 8) != 0)
#error "Key size and IV for DRBG must be even multiples of 8"
#endif
#if (DRBG_KEY_SIZE_BITS % DRBG_IV_SIZE_BITS) != 0
#error "Key size for DRBG must be even multiple of the cypher block size"
#endif
typedef UINT32 DRBG_SEED[(DRBG_KEY_SIZE_BITS + DRBG_IV_SIZE_BITS) / 32];
typedef struct {
UINT64 reseedCounter;
UINT32 magic;
DRBG_SEED seed; // contains the key and IV for the counter mode DRBG
UINT32 lastValue[4]; // used when the TPM does continuous self-test
// for FIPS compliance of DRBG
} DRBG_STATE, *pDRBG_STATE;
//
//
// Asymmetric Structures and Values
//
#ifdef TPM_ALG_ECC
//
//
// ECC-related Structures
//
// This structure replicates the structure definition in TPM_Types.h. It is duplicated to avoid inclusion of all of
// TPM_Types.h This structure is similar to the RSA_KEY structure below. The purpose of these structures
// is to reduce the overhead of a function call and to make the code less dependent on key types as much
// as possible.
//
typedef struct {
UINT32 curveID; // The curve identifier
TPMS_ECC_POINT *publicPoint; // Pointer to the public point
TPM2B_ECC_PARAMETER *privateKey; // Pointer to the private key
} ECC_KEY;
#endif // TPM_ALG_ECC
#ifdef TPM_ALG_RSA
//
//
// RSA-related Structures
//
// This structure is a succinct representation of the cryptographic components of an RSA key.
//
typedef struct {
UINT32 exponent; // The public exponent pointer
TPM2B *publicKey; // Pointer to the public modulus
TPM2B *privateKey; // The private exponent (not a prime)
} RSA_KEY;
#endif // TPM_ALG_RSA
//
//
// Miscelaneous
//
#ifdef TPM_ALG_RSA
# ifdef TPM_ALG_ECC
# if MAX_RSA_KEY_BYTES > MAX_ECC_KEY_BYTES
# define MAX_NUMBER_SIZE MAX_RSA_KEY_BYTES
# else
# define MAX_NUMBER_SIZE MAX_ECC_KEY_BYTES
# endif
# else // RSA but no ECC
# define MAX_NUMBER_SIZE MAX_RSA_KEY_BYTES
# endif
#elif defined TPM_ALG_ECC
# define MAX_NUMBER_SIZE MAX_ECC_KEY_BYTES
#else
# error No assymmetric algorithm implemented.
#endif
typedef INT16 CRYPT_RESULT;
#define CRYPT_RESULT_MIN INT16_MIN
#define CRYPT_RESULT_MAX INT16_MAX
//
//
// <0 recoverable error
//
// 0 success
// >0 command specific return value (generally a digest size)
//
#define CRYPT_FAIL ((CRYPT_RESULT) 1)
#define CRYPT_SUCCESS ((CRYPT_RESULT) 0)
#define CRYPT_NO_RESULT ((CRYPT_RESULT) -1)
//
#define CRYPT_SCHEME ((CRYPT_RESULT) -2)
#define CRYPT_PARAMETER ((CRYPT_RESULT) -3)
#define CRYPT_UNDERFLOW ((CRYPT_RESULT) -4)
#define CRYPT_POINT ((CRYPT_RESULT) -5)
#define CRYPT_CANCEL ((CRYPT_RESULT) -6)
typedef UINT64 HASH_CONTEXT[MAX_HASH_STATE_SIZE/sizeof(UINT64)];
#include "CpriCryptPri_fp.h"
#ifdef TPM_ALG_ECC
# include "CpriDataEcc.h"
# include "CpriECC_fp.h"
#endif
#include "MathFunctions_fp.h"
#include "CpriRNG_fp.h"
#include "CpriHash_fp.h"
#include "CpriSym_fp.h"
#ifdef TPM_ALG_RSA
# include "CpriRSA_fp.h"
#endif
#endif // !_CRYPT_PRI_H