coreboot-libre-fam15h-rdimm/3rdparty/chromeec/chip/g/dcrypto/dcrypto.h

/* Copyright 2015 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.
 */

/*
 * Crypto wrapper library for the g chip.
 */
#ifndef __EC_CHIP_G_DCRYPTO_DCRYPTO_H
#define __EC_CHIP_G_DCRYPTO_DCRYPTO_H

#ifdef __cplusplus
extern "C" {
#endif

#if defined(TEST_FUZZ) || !defined(TEST_BUILD)

#include "internal.h"

#include "crypto_api.h"

#include <stddef.h>

#include "cryptoc/hmac.h"

enum cipher_mode {
	CIPHER_MODE_ECB = 0, /* NIST SP 800-38A */
	CIPHER_MODE_CTR = 1, /* NIST SP 800-38A */
	CIPHER_MODE_CBC = 2, /* NIST SP 800-38A */
	CIPHER_MODE_GCM = 3  /* NIST SP 800-38D */
};

enum encrypt_mode {
	DECRYPT_MODE = 0,
	ENCRYPT_MODE = 1
};

enum hashing_mode {
	HASH_SHA1 = 0,
	HASH_SHA256 = 1,
	HASH_SHA384 = 2,  /* Only supported for PKCS#1 signing */
	HASH_SHA512 = 3,  /* Only supported for PKCS#1 signing */
	HASH_NULL = 4  /* Only supported for PKCS#1 signing */
};

/*
 * AES implementation, based on a hardware AES block.
 * FIPS Publication 197, The Advanced Encryption Standard (AES)
 */
#define AES256_BLOCK_CIPHER_KEY_SIZE       32

int DCRYPTO_aes_init(const uint8_t *key, uint32_t key_len, const uint8_t *iv,
		enum cipher_mode c_mode, enum encrypt_mode e_mode);
int DCRYPTO_aes_block(const uint8_t *in, uint8_t *out);

void DCRYPTO_aes_write_iv(const uint8_t *iv);
void DCRYPTO_aes_read_iv(uint8_t *iv);

/* AES-CTR-128/192/256
 * NIST Special Publication 800-38A
 */
int DCRYPTO_aes_ctr(uint8_t *out, const uint8_t *key, uint32_t key_bits,
		const uint8_t *iv, const uint8_t *in, size_t in_len);

/* AES-GCM-128/192/256
 * NIST Special Publication 800-38D, IV is provided externally
 * Caller should use IV length according to section 8.2 of SP 800-38D
 * And choose appropriate IV construction method, constrain number
 * of invocations according to section 8.3 of SP 800-38D
 */
struct GCM_CTX {
	union {
		uint32_t d[4];
		uint8_t c[16];
	} block, Ej0;

	uint64_t aad_len;
	uint64_t count;
	size_t remainder;
};

/* Initialize the GCM context structure. */
void DCRYPTO_gcm_init(struct GCM_CTX *ctx, const uint8_t *key,
		const uint8_t *iv, size_t iv_len);
/* Additional authentication data to include in the tag calculation. */
void DCRYPTO_gcm_aad(struct GCM_CTX *ctx, const uint8_t *aad_data, size_t len);
/* Encrypt & decrypt return the number of bytes written to out
 * (always an integral multiple of 16), or -1 on error.  These functions
 * may be called repeatedly with incremental data.
 *
 * NOTE: if in_len is not a integral multiple of 16, then out_len must
 * be atleast in_len - (in_len % 16) + 16 bytes.
 */
int DCRYPTO_gcm_encrypt(struct GCM_CTX *ctx, uint8_t *out, size_t out_len,
			const uint8_t *in, size_t in_len);
int DCRYPTO_gcm_decrypt(struct GCM_CTX *ctx, uint8_t *out, size_t out_len,
			const uint8_t *in, size_t in_len);
/* Encrypt & decrypt a partial final block, if any.  These functions
 * return the number of bytes written to out (<= 15), or -1 on error.
 */
int DCRYPTO_gcm_encrypt_final(struct GCM_CTX *ctx,
			uint8_t *out, size_t out_len);
int DCRYPTO_gcm_decrypt_final(struct GCM_CTX *ctx,
			uint8_t *out, size_t out_len);
/* Compute the tag over AAD + encrypt or decrypt data, and return the
 * number of bytes written to tag.  Returns -1 on error.
 */
int DCRYPTO_gcm_tag(struct GCM_CTX *ctx, uint8_t *tag, size_t tag_len);
/* Cleanup secrets. */
void DCRYPTO_gcm_finish(struct GCM_CTX *ctx);

/* AES-CMAC-128
 * NIST Special Publication 800-38B, RFC 4493
 * K: 128-bit key, M: message, len: number of bytes in M
 * Writes 128-bit tag to T; returns 0 if an error is encountered and 1
 * otherwise.
 */
int DCRYPTO_aes_cmac(const uint8_t *K, const uint8_t *M, const uint32_t len,
		uint32_t T[4]);
/* key: 128-bit key, M: message, len: number of bytes in M,
 *    T: tag to be verified
 * Returns 1 if the tag is correct and 0 otherwise.
 */
int DCRYPTO_aes_cmac_verify(const uint8_t *key, const uint8_t *M, const int len,
		const uint32_t T[4]);

/*
 * SHA implementation.  This abstraction is backed by either a
 * software or hardware implementation.
 *
 * There could be only a single hardware SHA context in progress. The init
 * functions will try using the HW context, if available, unless 'sw_required'
 * is TRUE, in which case there will be no attempt to use the hardware for
 * this particular hashing session.
 */
void DCRYPTO_SHA1_init(SHA_CTX *ctx, uint32_t sw_required);
/*  SHA256/384/512 FIPS 180-4
 */
void DCRYPTO_SHA256_init(LITE_SHA256_CTX *ctx, uint32_t sw_required);
void DCRYPTO_SHA384_init(LITE_SHA384_CTX *ctx);
void DCRYPTO_SHA512_init(LITE_SHA512_CTX *ctx);
const uint8_t *DCRYPTO_SHA1_hash(const void *data, uint32_t n,
				uint8_t *digest);
const uint8_t *DCRYPTO_SHA256_hash(const void *data, uint32_t n,
				   uint8_t *digest);
const uint8_t *DCRYPTO_SHA384_hash(const void *data, uint32_t n,
				   uint8_t *digest);
const uint8_t *DCRYPTO_SHA512_hash(const void *data, uint32_t n,
				   uint8_t *digest);
/*
 *  HMAC. FIPS 198-1
 */
void DCRYPTO_HMAC_SHA256_init(LITE_HMAC_CTX *ctx, const void *key,
			unsigned int len);
const uint8_t *DCRYPTO_HMAC_final(LITE_HMAC_CTX *ctx);

/*
 * BIGNUM utility methods.
 */
void DCRYPTO_bn_wrap(struct LITE_BIGNUM *b, void *buf, size_t len);

/*
 *  RSA.
 */

/* Largest supported key size for signing / encryption: 2048-bits.
 * Verification is a special case and supports 4096-bits (signing /
 * decryption could also support 4k-RSA, but is disabled since support
 * is not required, and enabling support would result in increased
 * stack usage for all key sizes.)
 */
#define RSA_BYTES_2K    256
#define RSA_BYTES_4K    512
#define RSA_WORDS_2K    (RSA_BYTES_2K / sizeof(uint32_t))
#define RSA_WORDS_4K    (RSA_BYTES_4K / sizeof(uint32_t))
#ifndef RSA_MAX_BYTES
#define RSA_MAX_BYTES   RSA_BYTES_2K
#endif
#define RSA_MAX_WORDS   (RSA_MAX_BYTES / sizeof(uint32_t))
#define RSA_F4          65537

struct RSA {
	uint32_t e;
	struct LITE_BIGNUM N;
	struct LITE_BIGNUM d;
};

enum padding_mode {
	PADDING_MODE_PKCS1 = 0,
	PADDING_MODE_OAEP  = 1,
	PADDING_MODE_PSS = 2,
	/* USE OF NULL PADDING IS NOT RECOMMENDED.
	 * SUPPORT EXISTS AS A REQUIREMENT FOR TPM2 OPERATION. */
	PADDING_MODE_NULL  = 3
};

/* RSA support, FIPS PUB 186-4 *
 * Calculate r = m ^ e mod N
 */
int DCRYPTO_rsa_encrypt(struct RSA *rsa, uint8_t *out, uint32_t *out_len,
			const uint8_t *in, uint32_t in_len,
			enum padding_mode padding, enum hashing_mode hashing,
			const char *label);

/* Calculate r = m ^ d mod N
 * return 0 if error
 */
int DCRYPTO_rsa_decrypt(struct RSA *rsa, uint8_t *out, uint32_t *out_len,
			const uint8_t *in, const uint32_t in_len,
			enum padding_mode padding, enum hashing_mode hashing,
			const char *label);

/* Calculate r = m ^ d mod N
 * return 0 if error
 */
int DCRYPTO_rsa_sign(struct RSA *rsa, uint8_t *out, uint32_t *out_len,
		const uint8_t *in, const uint32_t in_len,
		enum padding_mode padding, enum hashing_mode hashing);

/* Calculate r = m ^ e mod N
 * return 0 if error
 */
int DCRYPTO_rsa_verify(const struct RSA *rsa, const uint8_t *digest,
		uint32_t digest_len, const uint8_t *sig,
		const uint32_t sig_len,	enum padding_mode padding,
		enum hashing_mode hashing);

/* Calculate n = p * q, d = e ^ -1 mod phi. */
int DCRYPTO_rsa_key_compute(struct LITE_BIGNUM *N, struct LITE_BIGNUM *d,
			struct LITE_BIGNUM *p, struct LITE_BIGNUM *q,
			uint32_t e);

/*
 *  EC.
 */

/* DCRYPTO_p256_base_point_mul sets {out_x,out_y} = nG, where n is < the
 * order of the group.
 */
int DCRYPTO_p256_base_point_mul(p256_int *out_x, p256_int *out_y,
				const p256_int *n);

/* DCRYPTO_p256_point_mul sets {out_x,out_y} = n*{in_x,in_y}, where n is <
 * the order of the group.
 */
int DCRYPTO_p256_point_mul(p256_int *out_x, p256_int *out_y,
			const p256_int *n, const p256_int *in_x,
			const p256_int *in_y);
/*
 * Key selection based on FIPS-186-4, section B.4.2 (Key Pair
 * Generation by Testing Candidates).
 * Produce uniform private key from seed.
 * If x or y is NULL, the public key part is not computed.
 * Returns !0 on success.
 */
int DCRYPTO_p256_key_from_bytes(p256_int *x, p256_int *y, p256_int *d,
				const uint8_t bytes[P256_NBYTES]);


/* P256 based integration encryption (DH+AES128+SHA256).
 * Not FIPS 140-2 compliant, not used other than for tests
 * Authenticated data may be provided, where the first auth_data_len
 * bytes of in will be authenticated but not encrypted. *
 * Supports in-place encryption / decryption. *
 * The output format is:
 * 0x04 || PUBKEY || AUTH_DATA || AES128_CTR(PLAINTEXT) ||
 *         HMAC_SHA256(AUTH_DATA || CIPHERTEXT)
 */
size_t DCRYPTO_ecies_encrypt(
	void *out, size_t out_len, const void *in, size_t in_len,
	size_t auth_data_len, const uint8_t *iv,
	const p256_int *pub_x, const p256_int *pub_y,
	const uint8_t *salt, size_t salt_len,
	const uint8_t *info, size_t info_len);
size_t DCRYPTO_ecies_decrypt(
	void *out, size_t out_len, const void *in, size_t in_len,
	size_t auth_data_len, const uint8_t *iv,
	const p256_int *d,
	const uint8_t *salt, size_t salt_len,
	const uint8_t *info, size_t info_len);

/*
 * HKDF as per RFC 5869. Mentioned as conforming NIST SP 800-56C Rev.1
 * [RFC 5869] specifies a version of the above extraction-then-expansion
 * key-derivation procedure using HMAC for both the extraction and expansion
 * steps.
 */
int DCRYPTO_hkdf(uint8_t *OKM, size_t OKM_len,
		const uint8_t *salt, size_t salt_len,
		const uint8_t *IKM, size_t IKM_len,
		const uint8_t *info, size_t info_len);

/*
 *  BN.
 */

/* Apply Miller-Rabin test for prime candidate p.
 * Returns 1 if test passed, 0 otherwise
 */
int DCRYPTO_bn_generate_prime(struct LITE_BIGNUM *p);
void DCRYPTO_bn_wrap(struct LITE_BIGNUM *b, void *buf, size_t len);
void DCRYPTO_bn_mul(struct LITE_BIGNUM *c, const struct LITE_BIGNUM *a,
		const struct LITE_BIGNUM *b);
int DCRYPTO_bn_div(struct LITE_BIGNUM *quotient, struct LITE_BIGNUM *remainder,
		const struct LITE_BIGNUM *input,
		const struct LITE_BIGNUM *divisor);

/*
 * ASN.1 DER
 */
size_t DCRYPTO_asn1_sigp(uint8_t *buf, const p256_int *r, const p256_int *s);
size_t DCRYPTO_asn1_pubp(uint8_t *buf, const p256_int *x, const p256_int *y);

/*
 *  X509.
 */
/* DCRYPTO_x509_verify verifies that the provided X509 certificate was issued
 * by the specified certifcate authority.
 *
 * cert is a pointer to a DER encoded X509 certificate, as specified
 * in https://tools.ietf.org/html/rfc5280#section-4.1.  In ASN.1
 * notation, the certificate has the following structure:
 *
 *   Certificate  ::=  SEQUENCE  {
 *        tbsCertificate       TBSCertificate,
 *        signatureAlgorithm   AlgorithmIdentifier,
 *        signatureValue       BIT STRING  }
 *
 *   TBSCertificate  ::=  SEQUENCE  { }
 *   AlgorithmIdentifier  ::=  SEQUENCE  { }
 *
 * where signatureValue = SIGN(HASH(tbsCertificate)), with SIGN and
 * HASH specified by signatureAlgorithm.
 * Accepts only certs with OID: sha256WithRSAEncryption:
 * 30 0d 06 09 2a 86 48 86 f7 0d 01 01 0b 05 00
 */
int DCRYPTO_x509_verify(const uint8_t *cert, size_t len,
			const struct RSA *ca_pub_key);

/* Generate U2F Certificate and sign it
 * Use ECDSA with NIST P-256 curve, and SHA2-256 digest
 * @param d: key handle, used for NIST SP 800-90A HMAC DRBG
 * @param pk_x, pk_y: public key
 * @param serial: serial number for certificate
 * @param name: certificate issuer and subject
 * @param cert: output buffer for certificate
 * @param n: max size of cert
 */
int DCRYPTO_x509_gen_u2f_cert_name(const p256_int *d, const p256_int *pk_x,
				   const p256_int *pk_y, const p256_int *serial,
				   const char *name, uint8_t *cert,
				   const int n);

/* Generate U2F Certificate with DCRYPTO_x509_gen_u2f_cert_name
 * Providing certificate issuer as BOARD or U2F
 * @param d: key handle, used for NIST SP 800-90A HMAC DRBG
 * @param pk_x, pk_y: public key
 * @param serial: serial number for certificate
 * @param name: certificate issuer and subject
 * @param cert: output buffer for certificate
 * @param n: max size of cert
 */
int DCRYPTO_x509_gen_u2f_cert(const p256_int *d, const p256_int *pk_x,
			const p256_int *pk_y, const p256_int *serial,
			uint8_t *cert, const int n);

/*
 * Memory related functions.
 */
int DCRYPTO_equals(const void *a, const void *b, size_t len);

/*
 * Key-ladder and application key related functions.
 */
enum dcrypto_appid {
	RESERVED = 0,
	NVMEM = 1,
	U2F_ATTEST = 2,
	U2F_ORIGIN = 3,
	U2F_WRAP = 4,
	PERSO_AUTH = 5,
	PINWEAVER = 6,
	/* This enum value should not exceed 7. */
};

struct APPKEY_CTX {
#ifdef TEST_FUZZ
	uint8_t unused_for_cxx_compatibility;
#endif
};

int DCRYPTO_ladder_compute_frk2(size_t major_fw_version, uint8_t *frk2);
int DCRYPTO_ladder_random(void *output);
void DCRYPTO_ladder_revoke(void);

int DCRYPTO_appkey_init(enum dcrypto_appid id, struct APPKEY_CTX *ctx);
void DCRYPTO_appkey_finish(struct APPKEY_CTX *ctx);
int DCRYPTO_appkey_derive(enum dcrypto_appid appid, const uint32_t input[8],
			  uint32_t output[8]);

/* Number of bytes in the salt object. */
#define DCRYPTO_CIPHER_SALT_SIZE 16
BUILD_ASSERT(DCRYPTO_CIPHER_SALT_SIZE == CIPHER_SALT_SIZE);

/*
 * Encrypt/decrypt a flat blob.
 *
 * Encrypt or decrypt the input buffer, and write the correspondingly
 * ciphered output to out.  The number of bytes produced is equal to
 * the number of input bytes.  Note that the input and output pointers
 * MUST be word-aligned.
 *
 * This API is expected to be applied to a single contiguous region.

 * WARNING: A given salt/"in" pair MUST be unique, i.e. re-using a
 * salt with a logically different input buffer is catastrophic.  An
 * example of a suitable salt is one that is derived from "in", e.g. a
 * digest of the input data.
 *
 * @param appid the application-id of the calling context.
 * @param salt pointer to a unique value to be associated with this blob,
 *	       used for derivation of the proper IV, the size of the value
 *	       is as defined by DCRYPTO_CIPHER_SALT_SIZE above.
 * @param out Destination pointer where to write plaintext / ciphertext.
 * @param in  Source pointer where to read ciphertext / plaintext.
 * @param len Number of bytes to read from in / write to out.
 * @return non-zero on success, and zero otherwise.
 */
int DCRYPTO_app_cipher(enum dcrypto_appid appid, const void *salt,
		void *out, const void *in, size_t len);

#endif  /*  ^^^^^^^^^^^^^^^^^^^^^  !TEST_BUILD   */
/*
 * Query whether Key Ladder is enabled.
 *
 * @return 1 if Key Ladder is enabled, and 0 otherwise.
 */
int DCRYPTO_ladder_is_enabled(void);

#ifdef __cplusplus
}
#endif

#endif  /* ! __EC_CHIP_G_DCRYPTO_DCRYPTO_H */
Initial commit 2024-03-04 11:14:53 +01:00			`/* Copyright 2015 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.`
			`*/`

			`/*`
			`* Crypto wrapper library for the g chip.`
			`*/`
			`#ifndef __EC_CHIP_G_DCRYPTO_DCRYPTO_H`
			`#define __EC_CHIP_G_DCRYPTO_DCRYPTO_H`

			`#ifdef __cplusplus`
			`extern "C" {`
			`#endif`

			`#if defined(TEST_FUZZ) \|\| !defined(TEST_BUILD)`

			`#include "internal.h"`

			`#include "crypto_api.h"`

			`#include <stddef.h>`

			`#include "cryptoc/hmac.h"`

			`enum cipher_mode {`
			`CIPHER_MODE_ECB = 0, /* NIST SP 800-38A */`
			`CIPHER_MODE_CTR = 1, /* NIST SP 800-38A */`
			`CIPHER_MODE_CBC = 2, /* NIST SP 800-38A */`
			`CIPHER_MODE_GCM = 3 /* NIST SP 800-38D */`
			`};`

			`enum encrypt_mode {`
			`DECRYPT_MODE = 0,`
			`ENCRYPT_MODE = 1`
			`};`

			`enum hashing_mode {`
			`HASH_SHA1 = 0,`
			`HASH_SHA256 = 1,`
			`HASH_SHA384 = 2, /* Only supported for PKCS#1 signing */`
			`HASH_SHA512 = 3, /* Only supported for PKCS#1 signing */`
			`HASH_NULL = 4 /* Only supported for PKCS#1 signing */`
			`};`

			`/*`
			`* AES implementation, based on a hardware AES block.`
			`* FIPS Publication 197, The Advanced Encryption Standard (AES)`
			`*/`
			`#define AES256_BLOCK_CIPHER_KEY_SIZE 32`

			`int DCRYPTO_aes_init(const uint8_t key, uint32_t key_len, const uint8_t iv,`
			`enum cipher_mode c_mode, enum encrypt_mode e_mode);`
			`int DCRYPTO_aes_block(const uint8_t in, uint8_t out);`

			`void DCRYPTO_aes_write_iv(const uint8_t *iv);`
			`void DCRYPTO_aes_read_iv(uint8_t *iv);`

			`/* AES-CTR-128/192/256`
			`* NIST Special Publication 800-38A`
			`*/`
			`int DCRYPTO_aes_ctr(uint8_t out, const uint8_t key, uint32_t key_bits,`
			`const uint8_t iv, const uint8_t in, size_t in_len);`

			`/* AES-GCM-128/192/256`
			`* NIST Special Publication 800-38D, IV is provided externally`
			`* Caller should use IV length according to section 8.2 of SP 800-38D`
			`* And choose appropriate IV construction method, constrain number`
			`* of invocations according to section 8.3 of SP 800-38D`
			`*/`
			`struct GCM_CTX {`
			`union {`
			`uint32_t d[4];`
			`uint8_t c[16];`
			`} block, Ej0;`

			`uint64_t aad_len;`
			`uint64_t count;`
			`size_t remainder;`
			`};`

			`/* Initialize the GCM context structure. */`
			`void DCRYPTO_gcm_init(struct GCM_CTX ctx, const uint8_t key,`
			`const uint8_t *iv, size_t iv_len);`
			`/* Additional authentication data to include in the tag calculation. */`
			`void DCRYPTO_gcm_aad(struct GCM_CTX ctx, const uint8_t aad_data, size_t len);`
			`/* Encrypt & decrypt return the number of bytes written to out`
			`* (always an integral multiple of 16), or -1 on error. These functions`
			`* may be called repeatedly with incremental data.`
			`*`
			`* NOTE: if in_len is not a integral multiple of 16, then out_len must`
			`* be atleast in_len - (in_len % 16) + 16 bytes.`
			`*/`
			`int DCRYPTO_gcm_encrypt(struct GCM_CTX ctx, uint8_t out, size_t out_len,`
			`const uint8_t *in, size_t in_len);`
			`int DCRYPTO_gcm_decrypt(struct GCM_CTX ctx, uint8_t out, size_t out_len,`
			`const uint8_t *in, size_t in_len);`
			`/* Encrypt & decrypt a partial final block, if any. These functions`
			`* return the number of bytes written to out (<= 15), or -1 on error.`
			`*/`
			`int DCRYPTO_gcm_encrypt_final(struct GCM_CTX *ctx,`
			`uint8_t *out, size_t out_len);`
			`int DCRYPTO_gcm_decrypt_final(struct GCM_CTX *ctx,`
			`uint8_t *out, size_t out_len);`
			`/* Compute the tag over AAD + encrypt or decrypt data, and return the`
			`* number of bytes written to tag. Returns -1 on error.`
			`*/`
			`int DCRYPTO_gcm_tag(struct GCM_CTX ctx, uint8_t tag, size_t tag_len);`
			`/* Cleanup secrets. */`
			`void DCRYPTO_gcm_finish(struct GCM_CTX *ctx);`

			`/* AES-CMAC-128`
			`* NIST Special Publication 800-38B, RFC 4493`
			`* K: 128-bit key, M: message, len: number of bytes in M`
			`* Writes 128-bit tag to T; returns 0 if an error is encountered and 1`
			`* otherwise.`
			`*/`
			`int DCRYPTO_aes_cmac(const uint8_t K, const uint8_t M, const uint32_t len,`
			`uint32_t T[4]);`
			`/* key: 128-bit key, M: message, len: number of bytes in M,`
			`* T: tag to be verified`
			`* Returns 1 if the tag is correct and 0 otherwise.`
			`*/`
			`int DCRYPTO_aes_cmac_verify(const uint8_t key, const uint8_t M, const int len,`
			`const uint32_t T[4]);`

			`/*`
			`* SHA implementation. This abstraction is backed by either a`
			`* software or hardware implementation.`
			`*`
			`* There could be only a single hardware SHA context in progress. The init`
			`* functions will try using the HW context, if available, unless 'sw_required'`
			`* is TRUE, in which case there will be no attempt to use the hardware for`
			`* this particular hashing session.`
			`*/`
			`void DCRYPTO_SHA1_init(SHA_CTX *ctx, uint32_t sw_required);`
			`/* SHA256/384/512 FIPS 180-4`
			`*/`
			`void DCRYPTO_SHA256_init(LITE_SHA256_CTX *ctx, uint32_t sw_required);`
			`void DCRYPTO_SHA384_init(LITE_SHA384_CTX *ctx);`
			`void DCRYPTO_SHA512_init(LITE_SHA512_CTX *ctx);`
			`const uint8_t DCRYPTO_SHA1_hash(const void data, uint32_t n,`
			`uint8_t *digest);`
			`const uint8_t DCRYPTO_SHA256_hash(const void data, uint32_t n,`
			`uint8_t *digest);`
			`const uint8_t DCRYPTO_SHA384_hash(const void data, uint32_t n,`
			`uint8_t *digest);`
			`const uint8_t DCRYPTO_SHA512_hash(const void data, uint32_t n,`
			`uint8_t *digest);`
			`/*`
			`* HMAC. FIPS 198-1`
			`*/`
			`void DCRYPTO_HMAC_SHA256_init(LITE_HMAC_CTX ctx, const void key,`
			`unsigned int len);`
			`const uint8_t DCRYPTO_HMAC_final(LITE_HMAC_CTX ctx);`

			`/*`
			`* BIGNUM utility methods.`
			`*/`
			`void DCRYPTO_bn_wrap(struct LITE_BIGNUM b, void buf, size_t len);`

			`/*`
			`* RSA.`
			`*/`

			`/* Largest supported key size for signing / encryption: 2048-bits.`
			`* Verification is a special case and supports 4096-bits (signing /`
			`* decryption could also support 4k-RSA, but is disabled since support`
			`* is not required, and enabling support would result in increased`
			`* stack usage for all key sizes.)`
			`*/`
			`#define RSA_BYTES_2K 256`
			`#define RSA_BYTES_4K 512`
			`#define RSA_WORDS_2K (RSA_BYTES_2K / sizeof(uint32_t))`
			`#define RSA_WORDS_4K (RSA_BYTES_4K / sizeof(uint32_t))`
			`#ifndef RSA_MAX_BYTES`
			`#define RSA_MAX_BYTES RSA_BYTES_2K`
			`#endif`
			`#define RSA_MAX_WORDS (RSA_MAX_BYTES / sizeof(uint32_t))`
			`#define RSA_F4 65537`

			`struct RSA {`
			`uint32_t e;`
			`struct LITE_BIGNUM N;`
			`struct LITE_BIGNUM d;`
			`};`

			`enum padding_mode {`
			`PADDING_MODE_PKCS1 = 0,`
			`PADDING_MODE_OAEP = 1,`
			`PADDING_MODE_PSS = 2,`
			`/* USE OF NULL PADDING IS NOT RECOMMENDED.`
			`* SUPPORT EXISTS AS A REQUIREMENT FOR TPM2 OPERATION. */`
			`PADDING_MODE_NULL = 3`
			`};`

			`/* RSA support, FIPS PUB 186-4 *`
			`* Calculate r = m ^ e mod N`
			`*/`
			`int DCRYPTO_rsa_encrypt(struct RSA rsa, uint8_t out, uint32_t *out_len,`
			`const uint8_t *in, uint32_t in_len,`
			`enum padding_mode padding, enum hashing_mode hashing,`
			`const char *label);`

			`/* Calculate r = m ^ d mod N`
			`* return 0 if error`
			`*/`
			`int DCRYPTO_rsa_decrypt(struct RSA rsa, uint8_t out, uint32_t *out_len,`
			`const uint8_t *in, const uint32_t in_len,`
			`enum padding_mode padding, enum hashing_mode hashing,`
			`const char *label);`

			`/* Calculate r = m ^ d mod N`
			`* return 0 if error`
			`*/`
			`int DCRYPTO_rsa_sign(struct RSA rsa, uint8_t out, uint32_t *out_len,`
			`const uint8_t *in, const uint32_t in_len,`
			`enum padding_mode padding, enum hashing_mode hashing);`

			`/* Calculate r = m ^ e mod N`
			`* return 0 if error`
			`*/`
			`int DCRYPTO_rsa_verify(const struct RSA rsa, const uint8_t digest,`
			`uint32_t digest_len, const uint8_t *sig,`
			`const uint32_t sig_len, enum padding_mode padding,`
			`enum hashing_mode hashing);`

			`/* Calculate n = p * q, d = e ^ -1 mod phi. */`
			`int DCRYPTO_rsa_key_compute(struct LITE_BIGNUM N, struct LITE_BIGNUM d,`
			`struct LITE_BIGNUM p, struct LITE_BIGNUM q,`
			`uint32_t e);`

			`/*`
			`* EC.`
			`*/`

			`/* DCRYPTO_p256_base_point_mul sets {out_x,out_y} = nG, where n is < the`
			`* order of the group.`
			`*/`
			`int DCRYPTO_p256_base_point_mul(p256_int out_x, p256_int out_y,`
			`const p256_int *n);`

			`/* DCRYPTO_p256_point_mul sets {out_x,out_y} = n*{in_x,in_y}, where n is <`
			`* the order of the group.`
			`*/`
			`int DCRYPTO_p256_point_mul(p256_int out_x, p256_int out_y,`
			`const p256_int n, const p256_int in_x,`
			`const p256_int *in_y);`
			`/*`
			`* Key selection based on FIPS-186-4, section B.4.2 (Key Pair`
			`* Generation by Testing Candidates).`
			`* Produce uniform private key from seed.`
			`* If x or y is NULL, the public key part is not computed.`
			`* Returns !0 on success.`
			`*/`
			`int DCRYPTO_p256_key_from_bytes(p256_int x, p256_int y, p256_int *d,`
			`const uint8_t bytes[P256_NBYTES]);`


			`/* P256 based integration encryption (DH+AES128+SHA256).`
			`* Not FIPS 140-2 compliant, not used other than for tests`
			`* Authenticated data may be provided, where the first auth_data_len`
			`* bytes of in will be authenticated but not encrypted. *`
			`* Supports in-place encryption / decryption. *`
			`* The output format is:`
			`* 0x04 \|\| PUBKEY \|\| AUTH_DATA \|\| AES128_CTR(PLAINTEXT) \|\|`
			`* HMAC_SHA256(AUTH_DATA \|\| CIPHERTEXT)`
			`*/`
			`size_t DCRYPTO_ecies_encrypt(`
			`void out, size_t out_len, const void in, size_t in_len,`
			`size_t auth_data_len, const uint8_t *iv,`
			`const p256_int pub_x, const p256_int pub_y,`
			`const uint8_t *salt, size_t salt_len,`
			`const uint8_t *info, size_t info_len);`
			`size_t DCRYPTO_ecies_decrypt(`
			`void out, size_t out_len, const void in, size_t in_len,`
			`size_t auth_data_len, const uint8_t *iv,`
			`const p256_int *d,`
			`const uint8_t *salt, size_t salt_len,`
			`const uint8_t *info, size_t info_len);`

			`/*`
			`* HKDF as per RFC 5869. Mentioned as conforming NIST SP 800-56C Rev.1`
			`* [RFC 5869] specifies a version of the above extraction-then-expansion`
			`* key-derivation procedure using HMAC for both the extraction and expansion`
			`* steps.`
			`*/`
			`int DCRYPTO_hkdf(uint8_t *OKM, size_t OKM_len,`
			`const uint8_t *salt, size_t salt_len,`
			`const uint8_t *IKM, size_t IKM_len,`
			`const uint8_t *info, size_t info_len);`

			`/*`
			`* BN.`
			`*/`

			`/* Apply Miller-Rabin test for prime candidate p.`
			`* Returns 1 if test passed, 0 otherwise`
			`*/`
			`int DCRYPTO_bn_generate_prime(struct LITE_BIGNUM *p);`
			`void DCRYPTO_bn_wrap(struct LITE_BIGNUM b, void buf, size_t len);`
			`void DCRYPTO_bn_mul(struct LITE_BIGNUM c, const struct LITE_BIGNUM a,`
			`const struct LITE_BIGNUM *b);`
			`int DCRYPTO_bn_div(struct LITE_BIGNUM quotient, struct LITE_BIGNUM remainder,`
			`const struct LITE_BIGNUM *input,`
			`const struct LITE_BIGNUM *divisor);`

			`/*`
			`* ASN.1 DER`
			`*/`
			`size_t DCRYPTO_asn1_sigp(uint8_t buf, const p256_int r, const p256_int *s);`
			`size_t DCRYPTO_asn1_pubp(uint8_t buf, const p256_int x, const p256_int *y);`

			`/*`
			`* X509.`
			`*/`
			`/* DCRYPTO_x509_verify verifies that the provided X509 certificate was issued`
			`* by the specified certifcate authority.`
			`*`
			`* cert is a pointer to a DER encoded X509 certificate, as specified`
			`* in https://tools.ietf.org/html/rfc5280#section-4.1. In ASN.1`
			`* notation, the certificate has the following structure:`
			`*`
			`* Certificate ::= SEQUENCE {`
			`* tbsCertificate TBSCertificate,`
			`* signatureAlgorithm AlgorithmIdentifier,`
			`* signatureValue BIT STRING }`
			`*`
			`* TBSCertificate ::= SEQUENCE { }`
			`* AlgorithmIdentifier ::= SEQUENCE { }`
			`*`
			`* where signatureValue = SIGN(HASH(tbsCertificate)), with SIGN and`
			`* HASH specified by signatureAlgorithm.`
			`* Accepts only certs with OID: sha256WithRSAEncryption:`
			`* 30 0d 06 09 2a 86 48 86 f7 0d 01 01 0b 05 00`
			`*/`
			`int DCRYPTO_x509_verify(const uint8_t *cert, size_t len,`
			`const struct RSA *ca_pub_key);`

			`/* Generate U2F Certificate and sign it`
			`* Use ECDSA with NIST P-256 curve, and SHA2-256 digest`
			`* @param d: key handle, used for NIST SP 800-90A HMAC DRBG`
			`* @param pk_x, pk_y: public key`
			`* @param serial: serial number for certificate`
			`* @param name: certificate issuer and subject`
			`* @param cert: output buffer for certificate`
			`* @param n: max size of cert`
			`*/`
			`int DCRYPTO_x509_gen_u2f_cert_name(const p256_int d, const p256_int pk_x,`
			`const p256_int pk_y, const p256_int serial,`
			`const char name, uint8_t cert,`
			`const int n);`

			`/* Generate U2F Certificate with DCRYPTO_x509_gen_u2f_cert_name`
			`* Providing certificate issuer as BOARD or U2F`
			`* @param d: key handle, used for NIST SP 800-90A HMAC DRBG`
			`* @param pk_x, pk_y: public key`
			`* @param serial: serial number for certificate`
			`* @param name: certificate issuer and subject`
			`* @param cert: output buffer for certificate`
			`* @param n: max size of cert`
			`*/`
			`int DCRYPTO_x509_gen_u2f_cert(const p256_int d, const p256_int pk_x,`
			`const p256_int pk_y, const p256_int serial,`
			`uint8_t *cert, const int n);`

			`/*`
			`* Memory related functions.`
			`*/`
			`int DCRYPTO_equals(const void a, const void b, size_t len);`

			`/*`
			`* Key-ladder and application key related functions.`
			`*/`
			`enum dcrypto_appid {`
			`RESERVED = 0,`
			`NVMEM = 1,`
			`U2F_ATTEST = 2,`
			`U2F_ORIGIN = 3,`
			`U2F_WRAP = 4,`
			`PERSO_AUTH = 5,`
			`PINWEAVER = 6,`
			`/* This enum value should not exceed 7. */`
			`};`

			`struct APPKEY_CTX {`
			`#ifdef TEST_FUZZ`
			`uint8_t unused_for_cxx_compatibility;`
			`#endif`
			`};`

			`int DCRYPTO_ladder_compute_frk2(size_t major_fw_version, uint8_t *frk2);`
			`int DCRYPTO_ladder_random(void *output);`
			`void DCRYPTO_ladder_revoke(void);`

			`int DCRYPTO_appkey_init(enum dcrypto_appid id, struct APPKEY_CTX *ctx);`
			`void DCRYPTO_appkey_finish(struct APPKEY_CTX *ctx);`
			`int DCRYPTO_appkey_derive(enum dcrypto_appid appid, const uint32_t input[8],`
			`uint32_t output[8]);`

			`/* Number of bytes in the salt object. */`
			`#define DCRYPTO_CIPHER_SALT_SIZE 16`
			`BUILD_ASSERT(DCRYPTO_CIPHER_SALT_SIZE == CIPHER_SALT_SIZE);`

			`/*`
			`* Encrypt/decrypt a flat blob.`
			`*`
			`* Encrypt or decrypt the input buffer, and write the correspondingly`
			`* ciphered output to out. The number of bytes produced is equal to`
			`* the number of input bytes. Note that the input and output pointers`
			`* MUST be word-aligned.`
			`*`
			`* This API is expected to be applied to a single contiguous region.`

			`* WARNING: A given salt/"in" pair MUST be unique, i.e. re-using a`
			`* salt with a logically different input buffer is catastrophic. An`
			`* example of a suitable salt is one that is derived from "in", e.g. a`
			`* digest of the input data.`
			`*`
			`* @param appid the application-id of the calling context.`
			`* @param salt pointer to a unique value to be associated with this blob,`
			`* used for derivation of the proper IV, the size of the value`
			`* is as defined by DCRYPTO_CIPHER_SALT_SIZE above.`
			`* @param out Destination pointer where to write plaintext / ciphertext.`
			`* @param in Source pointer where to read ciphertext / plaintext.`
			`* @param len Number of bytes to read from in / write to out.`
			`* @return non-zero on success, and zero otherwise.`
			`*/`
			`int DCRYPTO_app_cipher(enum dcrypto_appid appid, const void *salt,`
			`void out, const void in, size_t len);`

			`#endif /* ^^^^^^^^^^^^^^^^^^^^^ !TEST_BUILD */`
			`/*`
			`* Query whether Key Ladder is enabled.`
			`*`
			`* @return 1 if Key Ladder is enabled, and 0 otherwise.`
			`*/`
			`int DCRYPTO_ladder_is_enabled(void);`

			`#ifdef __cplusplus`
			`}`
			`#endif`

			`#endif /* ! __EC_CHIP_G_DCRYPTO_DCRYPTO_H */`