/* * Copyright (c) 2016 Thomas Pornin * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #ifndef BR_BEARSSL_HASH_H__ #define BR_BEARSSL_HASH_H__ #include #include #include #ifdef __cplusplus extern "C" { #endif /** \file bearssl_hash.h * * # Hash Functions * * This file documents the API for hash functions. * * * ## Procedural API * * For each implemented hash function, of name "`xxx`", the following * elements are defined: * * - `br_xxx_vtable` * * An externally defined instance of `br_hash_class`. * * - `br_xxx_SIZE` * * A macro that evaluates to the output size (in bytes) of the * hash function. * * - `br_xxx_ID` * * A macro that evaluates to a symbolic identifier for the hash * function. Such identifiers are used with HMAC and signature * algorithm implementations. * * NOTE: for the "standard" hash functions defined in [the TLS * standard](https://tools.ietf.org/html/rfc5246#section-7.4.1.4.1), * the symbolic identifiers match the constants used in TLS, i.e. * 1 to 6 for MD5, SHA-1, SHA-224, SHA-256, SHA-384 and SHA-512, * respectively. * * - `br_xxx_context` * * Context for an ongoing computation. It is allocated by the * caller, and a pointer to it is passed to all functions. A * context contains no interior pointer, so it can be moved around * and cloned (with a simple `memcpy()` or equivalent) in order to * capture the function state at some point. Computations that use * distinct context structures are independent of each other. The * first field of `br_xxx_context` is always a pointer to the * `br_xxx_vtable` structure; `br_xxx_init()` sets that pointer. * * - `br_xxx_init(br_xxx_context *ctx)` * * Initialise the provided context. Previous contents of the structure * are ignored. This calls resets the context to the start of a new * hash computation; it also sets the first field of the context * structure (called `vtable`) to a pointer to the statically * allocated constant `br_xxx_vtable` structure. * * - `br_xxx_update(br_xxx_context *ctx, const void *data, size_t len)` * * Add some more bytes to the hash computation represented by the * provided context. * * - `br_xxx_out(const br_xxx_context *ctx, void *out)` * * Complete the hash computation and write the result in the provided * buffer. The output buffer MUST be large enough to accommodate the * result. The context is NOT modified by this operation, so this * function can be used to get a "partial hash" while still keeping * the possibility of adding more bytes to the input. * * - `br_xxx_state(const br_xxx_context *ctx, void *out)` * * Get a copy of the "current state" for the computation so far. For * MD functions (MD5, SHA-1, SHA-2 family), this is the running state * resulting from the processing of the last complete input block. * Returned value is the current input length (in bytes). * * - `br_xxx_set_state(br_xxx_context *ctx, const void *stb, uint64_t count)` * * Set the internal state to the provided values. The 'stb' and * 'count' values shall match that which was obtained from * `br_xxx_state()`. This restores the hash state only if the state * values were at an appropriate block boundary. This does NOT set * the `vtable` pointer in the context. * * Context structures can be discarded without any explicit deallocation. * Hash function implementations are purely software and don't reserve * any resources outside of the context structure itself. * * * ## Object-Oriented API * * For each hash function that follows the procedural API described * above, an object-oriented API is also provided. In that API, function * pointers from the vtable (`br_xxx_vtable`) are used. The vtable * incarnates object-oriented programming. An introduction on the OOP * concept used here can be read on the BearSSL Web site:
*    [https://www.bearssl.org/oop.html](https://www.bearssl.org/oop.html) * * The vtable offers functions called `init()`, `update()`, `out()`, * `set()` and `set_state()`, which are in fact the functions from * the procedural API. That vtable also contains two informative fields: * * - `context_size` * * The size of the context structure (`br_xxx_context`), in bytes. * This can be used by generic implementations to perform dynamic * context allocation. * * - `desc` * * A "descriptor" field that encodes some information on the hash * function: symbolic identifier, output size, state size, * internal block size, details on the padding. * * Users of this object-oriented API (in particular generic HMAC * implementations) may make the following assumptions: * * - Hash output size is no more than 64 bytes. * - Hash internal state size is no more than 64 bytes. * - Internal block size is a power of two, no less than 16 and no more * than 256. * * * ## Implemented Hash Functions * * Implemented hash functions are: * * | Function | Name | Output length | State length | * | :-------- | :------ | :-----------: | :----------: | * | MD5 | md5 | 16 | 16 | * | SHA-1 | sha1 | 20 | 20 | * | SHA-224 | sha224 | 28 | 32 | * | SHA-256 | sha256 | 32 | 32 | * | SHA-384 | sha384 | 48 | 64 | * | SHA-512 | sha512 | 64 | 64 | * | MD5+SHA-1 | md5sha1 | 36 | 36 | * * (MD5+SHA-1 is the concatenation of MD5 and SHA-1 computed over the * same input; in the implementation, the internal data buffer is * shared, thus making it more memory-efficient than separate MD5 and * SHA-1. It can be useful in implementing SSL 3.0, TLS 1.0 and TLS * 1.1.) * * * ## Multi-Hasher * * An aggregate hasher is provided, that can compute several standard * hash functions in parallel. It uses `br_multihash_context` and a * procedural API. It is configured with the implementations (the vtables) * that it should use; it will then compute all these hash functions in * parallel, on the same input. It is meant to be used in cases when the * hash of an object will be used, but the exact hash function is not * known yet (typically, streamed processing on X.509 certificates). * * Only the standard hash functions (MD5, SHA-1, SHA-224, SHA-256, SHA-384 * and SHA-512) are supported by the multi-hasher. * * * ## GHASH * * GHASH is not a generic hash function; it is a _universal_ hash function, * which, as the name does not say, means that it CANNOT be used in most * places where a hash function is needed. GHASH is used within the GCM * encryption mode, to provide the checked integrity functionality. * * A GHASH implementation is basically a function that uses the type defined * in this file under the name `br_ghash`: * * typedef void (*br_ghash)(void *y, const void *h, const void *data, size_t len); * * The `y` pointer refers to a 16-byte value which is used as input, and * receives the output of the GHASH invocation. `h` is a 16-byte secret * value (that serves as key). `data` and `len` define the input data. * * Three GHASH implementations are provided, all constant-time, based on * the use of integer multiplications with appropriate masking to cancel * carry propagation. */ /** * \brief Class type for hash function implementations. * * A `br_hash_class` instance references the methods implementing a hash * function. Constant instances of this structure are defined for each * implemented hash function. Such instances are also called "vtables". * * Vtables are used to support object-oriented programming, as * described on [the BearSSL Web site](https://www.bearssl.org/oop.html). */ typedef struct br_hash_class_ br_hash_class; struct br_hash_class_ { /** * \brief Size (in bytes) of the context structure appropriate for * computing this hash function. */ size_t context_size; /** * \brief Descriptor word that contains information about the hash * function. * * For each word `xxx` described below, use `BR_HASHDESC_xxx_OFF` * and `BR_HASHDESC_xxx_MASK` to access the specific value, as * follows: * * (hf->desc >> BR_HASHDESC_xxx_OFF) & BR_HASHDESC_xxx_MASK * * The defined elements are: * * - `ID`: the symbolic identifier for the function, as defined * in [TLS](https://tools.ietf.org/html/rfc5246#section-7.4.1.4.1) * (MD5 = 1, SHA-1 = 2,...). * * - `OUT`: hash output size, in bytes. * * - `STATE`: internal running state size, in bytes. * * - `LBLEN`: base-2 logarithm for the internal block size, as * defined for HMAC processing (this is 6 for MD5, SHA-1, SHA-224 * and SHA-256, since these functions use 64-byte blocks; for * SHA-384 and SHA-512, this is 7, corresponding to their * 128-byte blocks). * * The descriptor may contain a few other flags. */ uint32_t desc; /** * \brief Initialisation method. * * This method takes as parameter a pointer to a context area, * that it initialises. The first field of the context is set * to this vtable; other elements are initialised for a new hash * computation. * * \param ctx pointer to (the first field of) the context. */ void (*init)(const br_hash_class **ctx); /** * \brief Data injection method. * * The `len` bytes starting at address `data` are injected into * the running hash computation incarnated by the specified * context. The context is updated accordingly. It is allowed * to have `len == 0`, in which case `data` is ignored (and could * be `NULL`), and nothing happens. * on the input data. * * \param ctx pointer to (the first field of) the context. * \param data pointer to the first data byte to inject. * \param len number of bytes to inject. */ void (*update)(const br_hash_class **ctx, const void *data, size_t len); /** * \brief Produce hash output. * * The hash output corresponding to all data bytes injected in the * context since the last `init()` call is computed, and written * in the buffer pointed to by `dst`. The hash output size depends * on the implemented hash function (e.g. 16 bytes for MD5). * The context is _not_ modified by this call, so further bytes * may be afterwards injected to continue the current computation. * * \param ctx pointer to (the first field of) the context. * \param dst destination buffer for the hash output. */ void (*out)(const br_hash_class *const *ctx, void *dst); /** * \brief Get running state. * * This method saves the current running state into the `dst` * buffer. What constitutes the "running state" depends on the * hash function; for Merkle-Damgård hash functions (like * MD5 or SHA-1), this is the output obtained after processing * each block. The number of bytes injected so far is returned. * The context is not modified by this call. * * \param ctx pointer to (the first field of) the context. * \param dst destination buffer for the state. * \return the injected total byte length. */ uint64_t (*state)(const br_hash_class *const *ctx, void *dst); /** * \brief Set running state. * * This methods replaces the running state for the function. * * \param ctx pointer to (the first field of) the context. * \param stb source buffer for the state. * \param count injected total byte length. */ void (*set_state)(const br_hash_class **ctx, const void *stb, uint64_t count); }; #ifndef BR_DOXYGEN_IGNORE #define BR_HASHDESC_ID(id) ((uint32_t)(id) << BR_HASHDESC_ID_OFF) #define BR_HASHDESC_ID_OFF 0 #define BR_HASHDESC_ID_MASK 0xFF #define BR_HASHDESC_OUT(size) ((uint32_t)(size) << BR_HASHDESC_OUT_OFF) #define BR_HASHDESC_OUT_OFF 8 #define BR_HASHDESC_OUT_MASK 0x7F #define BR_HASHDESC_STATE(size) ((uint32_t)(size) << BR_HASHDESC_STATE_OFF) #define BR_HASHDESC_STATE_OFF 15 #define BR_HASHDESC_STATE_MASK 0xFF #define BR_HASHDESC_LBLEN(ls) ((uint32_t)(ls) << BR_HASHDESC_LBLEN_OFF) #define BR_HASHDESC_LBLEN_OFF 23 #define BR_HASHDESC_LBLEN_MASK 0x0F #define BR_HASHDESC_MD_PADDING ((uint32_t)1 << 28) #define BR_HASHDESC_MD_PADDING_128 ((uint32_t)1 << 29) #define BR_HASHDESC_MD_PADDING_BE ((uint32_t)1 << 30) #endif /* * Specific hash functions. * * Rules for contexts: * -- No interior pointer. * -- No pointer to external dynamically allocated resources. * -- First field is called 'vtable' and is a pointer to a * const-qualified br_hash_class instance (pointer is set by init()). * -- SHA-224 and SHA-256 contexts are identical. * -- SHA-384 and SHA-512 contexts are identical. * * Thus, contexts can be moved and cloned to capture the hash function * current state; and there is no need for any explicit "release" function. */ /** * \brief Symbolic identifier for MD5. */ #define br_md5_ID 1 /** * \brief MD5 output size (in bytes). */ #define br_md5_SIZE 16 /** * \brief Constant vtable for MD5. */ extern const br_hash_class br_md5_vtable; /** * \brief MD5 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; #ifndef BR_DOXYGEN_IGNORE unsigned char buf[64]; uint64_t count; uint32_t val[4]; #endif } br_md5_context; /** * \brief MD5 context initialisation. * * This function initialises or resets a context for a new MD5 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_md5_init(br_md5_context *ctx); /** * \brief Inject some data bytes in a running MD5 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_md5_update(br_md5_context *ctx, const void *data, size_t len); /** * \brief Compute MD5 output. * * The MD5 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_md5_out(const br_md5_context *ctx, void *out); /** * \brief Save MD5 running state. * * The running state for MD5 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_md5_state(const br_md5_context *ctx, void *out); /** * \brief Restore MD5 running state. * * The running state for MD5 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_md5_set_state(br_md5_context *ctx, const void *stb, uint64_t count); /** * \brief Symbolic identifier for SHA-1. */ #define br_sha1_ID 2 /** * \brief SHA-1 output size (in bytes). */ #define br_sha1_SIZE 20 /** * \brief Constant vtable for SHA-1. */ extern const br_hash_class br_sha1_vtable; /** * \brief SHA-1 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; #ifndef BR_DOXYGEN_IGNORE unsigned char buf[64]; uint64_t count; uint32_t val[5]; #endif } br_sha1_context; /** * \brief SHA-1 context initialisation. * * This function initialises or resets a context for a new SHA-1 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_sha1_init(br_sha1_context *ctx); /** * \brief Inject some data bytes in a running SHA-1 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_sha1_update(br_sha1_context *ctx, const void *data, size_t len); /** * \brief Compute SHA-1 output. * * The SHA-1 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_sha1_out(const br_sha1_context *ctx, void *out); /** * \brief Save SHA-1 running state. * * The running state for SHA-1 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_sha1_state(const br_sha1_context *ctx, void *out); /** * \brief Restore SHA-1 running state. * * The running state for SHA-1 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_sha1_set_state(br_sha1_context *ctx, const void *stb, uint64_t count); /** * \brief Symbolic identifier for SHA-224. */ #define br_sha224_ID 3 /** * \brief SHA-224 output size (in bytes). */ #define br_sha224_SIZE 28 /** * \brief Constant vtable for SHA-224. */ extern const br_hash_class br_sha224_vtable; /** * \brief SHA-224 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; #ifndef BR_DOXYGEN_IGNORE unsigned char buf[64]; uint64_t count; uint32_t val[8]; #endif } br_sha224_context; /** * \brief SHA-224 context initialisation. * * This function initialises or resets a context for a new SHA-224 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_sha224_init(br_sha224_context *ctx); /** * \brief Inject some data bytes in a running SHA-224 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_sha224_update(br_sha224_context *ctx, const void *data, size_t len); /** * \brief Compute SHA-224 output. * * The SHA-224 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_sha224_out(const br_sha224_context *ctx, void *out); /** * \brief Save SHA-224 running state. * * The running state for SHA-224 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_sha224_state(const br_sha224_context *ctx, void *out); /** * \brief Restore SHA-224 running state. * * The running state for SHA-224 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_sha224_set_state(br_sha224_context *ctx, const void *stb, uint64_t count); /** * \brief Symbolic identifier for SHA-256. */ #define br_sha256_ID 4 /** * \brief SHA-256 output size (in bytes). */ #define br_sha256_SIZE 32 /** * \brief Constant vtable for SHA-256. */ extern const br_hash_class br_sha256_vtable; #ifdef BR_DOXYGEN_IGNORE /** * \brief SHA-256 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; } br_sha256_context; #else typedef br_sha224_context br_sha256_context; #endif /** * \brief SHA-256 context initialisation. * * This function initialises or resets a context for a new SHA-256 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_sha256_init(br_sha256_context *ctx); #ifdef BR_DOXYGEN_IGNORE /** * \brief Inject some data bytes in a running SHA-256 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_sha256_update(br_sha256_context *ctx, const void *data, size_t len); #else #define br_sha256_update br_sha224_update #endif /** * \brief Compute SHA-256 output. * * The SHA-256 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_sha256_out(const br_sha256_context *ctx, void *out); #ifdef BR_DOXYGEN_IGNORE /** * \brief Save SHA-256 running state. * * The running state for SHA-256 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_sha256_state(const br_sha256_context *ctx, void *out); #else #define br_sha256_state br_sha224_state #endif #ifdef BR_DOXYGEN_IGNORE /** * \brief Restore SHA-256 running state. * * The running state for SHA-256 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_sha256_set_state(br_sha256_context *ctx, const void *stb, uint64_t count); #else #define br_sha256_set_state br_sha224_set_state #endif /** * \brief Symbolic identifier for SHA-384. */ #define br_sha384_ID 5 /** * \brief SHA-384 output size (in bytes). */ #define br_sha384_SIZE 48 /** * \brief Constant vtable for SHA-384. */ extern const br_hash_class br_sha384_vtable; /** * \brief SHA-384 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; #ifndef BR_DOXYGEN_IGNORE unsigned char buf[128]; uint64_t count; uint64_t val[8]; #endif } br_sha384_context; /** * \brief SHA-384 context initialisation. * * This function initialises or resets a context for a new SHA-384 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_sha384_init(br_sha384_context *ctx); /** * \brief Inject some data bytes in a running SHA-384 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_sha384_update(br_sha384_context *ctx, const void *data, size_t len); /** * \brief Compute SHA-384 output. * * The SHA-384 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_sha384_out(const br_sha384_context *ctx, void *out); /** * \brief Save SHA-384 running state. * * The running state for SHA-384 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_sha384_state(const br_sha384_context *ctx, void *out); /** * \brief Restore SHA-384 running state. * * The running state for SHA-384 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_sha384_set_state(br_sha384_context *ctx, const void *stb, uint64_t count); /** * \brief Symbolic identifier for SHA-512. */ #define br_sha512_ID 6 /** * \brief SHA-512 output size (in bytes). */ #define br_sha512_SIZE 64 /** * \brief Constant vtable for SHA-512. */ extern const br_hash_class br_sha512_vtable; #ifdef BR_DOXYGEN_IGNORE /** * \brief SHA-512 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; } br_sha512_context; #else typedef br_sha384_context br_sha512_context; #endif /** * \brief SHA-512 context initialisation. * * This function initialises or resets a context for a new SHA-512 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_sha512_init(br_sha512_context *ctx); #ifdef BR_DOXYGEN_IGNORE /** * \brief Inject some data bytes in a running SHA-512 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_sha512_update(br_sha512_context *ctx, const void *data, size_t len); #else #define br_sha512_update br_sha384_update #endif /** * \brief Compute SHA-512 output. * * The SHA-512 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_sha512_out(const br_sha512_context *ctx, void *out); #ifdef BR_DOXYGEN_IGNORE /** * \brief Save SHA-512 running state. * * The running state for SHA-512 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_sha512_state(const br_sha512_context *ctx, void *out); #else #define br_sha512_state br_sha384_state #endif #ifdef BR_DOXYGEN_IGNORE /** * \brief Restore SHA-512 running state. * * The running state for SHA-512 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_sha512_set_state(br_sha512_context *ctx, const void *stb, uint64_t count); #else #define br_sha512_set_state br_sha384_set_state #endif /* * "md5sha1" is a special hash function that computes both MD5 and SHA-1 * on the same input, and produces a 36-byte output (MD5 and SHA-1 * concatenation, in that order). State size is also 36 bytes. */ /** * \brief Symbolic identifier for MD5+SHA-1. * * MD5+SHA-1 is the concatenation of MD5 and SHA-1, computed over the * same input. It is not one of the functions identified in TLS, so * we give it a symbolic identifier of value 0. */ #define br_md5sha1_ID 0 /** * \brief MD5+SHA-1 output size (in bytes). */ #define br_md5sha1_SIZE 36 /** * \brief Constant vtable for MD5+SHA-1. */ extern const br_hash_class br_md5sha1_vtable; /** * \brief MD5+SHA-1 context. * * First field is a pointer to the vtable; it is set by the initialisation * function. Other fields are not supposed to be accessed by user code. */ typedef struct { /** * \brief Pointer to vtable for this context. */ const br_hash_class *vtable; #ifndef BR_DOXYGEN_IGNORE unsigned char buf[64]; uint64_t count; uint32_t val_md5[4]; uint32_t val_sha1[5]; #endif } br_md5sha1_context; /** * \brief MD5+SHA-1 context initialisation. * * This function initialises or resets a context for a new SHA-512 * computation. It also sets the vtable pointer. * * \param ctx pointer to the context structure. */ void br_md5sha1_init(br_md5sha1_context *ctx); /** * \brief Inject some data bytes in a running MD5+SHA-1 computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_md5sha1_update(br_md5sha1_context *ctx, const void *data, size_t len); /** * \brief Compute MD5+SHA-1 output. * * The MD5+SHA-1 output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `out`. The context * itself is not modified, so extra bytes may be injected afterwards * to continue that computation. * * \param ctx pointer to the context structure. * \param out destination buffer for the hash output. */ void br_md5sha1_out(const br_md5sha1_context *ctx, void *out); /** * \brief Save MD5+SHA-1 running state. * * The running state for MD5+SHA-1 (output of the last internal block * processing) is written in the buffer pointed to by `out`. The * number of bytes injected since the last initialisation or reset * call is returned. The context is not modified. * * \param ctx pointer to the context structure. * \param out destination buffer for the running state. * \return the injected total byte length. */ uint64_t br_md5sha1_state(const br_md5sha1_context *ctx, void *out); /** * \brief Restore MD5+SHA-1 running state. * * The running state for MD5+SHA-1 is set to the provided values. * * \param ctx pointer to the context structure. * \param stb source buffer for the running state. * \param count the injected total byte length. */ void br_md5sha1_set_state(br_md5sha1_context *ctx, const void *stb, uint64_t count); /** * \brief Aggregate context for configurable hash function support. * * The `br_hash_compat_context` type is a type which is large enough to * serve as context for all standard hash functions defined above. */ typedef union { const br_hash_class *vtable; br_md5_context md5; br_sha1_context sha1; br_sha224_context sha224; br_sha256_context sha256; br_sha384_context sha384; br_sha512_context sha512; br_md5sha1_context md5sha1; } br_hash_compat_context; /* * The multi-hasher is a construct that handles hashing of the same input * data with several hash functions, with a single shared input buffer. * It can handle MD5, SHA-1, SHA-224, SHA-256, SHA-384 and SHA-512 * simultaneously, though which functions are activated depends on * the set implementation pointers. */ /** * \brief Multi-hasher context structure. * * The multi-hasher runs up to six hash functions in the standard TLS list * (MD5, SHA-1, SHA-224, SHA-256, SHA-384 and SHA-512) in parallel, over * the same input. * * The multi-hasher does _not_ follow the OOP structure with a vtable. * Instead, it is configured with the vtables of the hash functions it * should run. Structure fields are not supposed to be accessed directly. */ typedef struct { #ifndef BR_DOXYGEN_IGNORE unsigned char buf[128]; uint64_t count; uint32_t val_32[25]; uint64_t val_64[16]; const br_hash_class *impl[6]; #endif } br_multihash_context; /** * \brief Clear a multi-hasher context. * * This should always be called once on a given context, _before_ setting * the implementation pointers. * * \param ctx the multi-hasher context. */ void br_multihash_zero(br_multihash_context *ctx); /** * \brief Set a hash function implementation. * * Implementations shall be set _after_ clearing the context (with * `br_multihash_zero()`) but _before_ initialising the computation * (with `br_multihash_init()`). The hash function implementation * MUST be one of the standard hash functions (MD5, SHA-1, SHA-224, * SHA-256, SHA-384 or SHA-512); it may also be `NULL` to remove * an implementation from the multi-hasher. * * \param ctx the multi-hasher context. * \param id the hash function symbolic identifier. * \param impl the hash function vtable, or `NULL`. */ static inline void br_multihash_setimpl(br_multihash_context *ctx, int id, const br_hash_class *impl) { /* * This code relies on hash functions ID being values 1 to 6, * in the MD5 to SHA-512 order. */ ctx->impl[id - 1] = impl; } /** * \brief Get a hash function implementation. * * This function returns the currently configured vtable for a given * hash function (by symbolic ID). If no such function was configured in * the provided multi-hasher context, then this function returns `NULL`. * * \param ctx the multi-hasher context. * \param id the hash function symbolic identifier. * \return the hash function vtable, or `NULL`. */ static inline const br_hash_class * br_multihash_getimpl(const br_multihash_context *ctx, int id) { return ctx->impl[id - 1]; } /** * \brief Reset a multi-hasher context. * * This function prepares the context for a new hashing computation, * for all implementations configured at that point. * * \param ctx the multi-hasher context. */ void br_multihash_init(br_multihash_context *ctx); /** * \brief Inject some data bytes in a running multi-hashing computation. * * The provided context is updated with some data bytes. If the number * of bytes (`len`) is zero, then the data pointer (`data`) is ignored * and may be `NULL`, and this function does nothing. * * \param ctx pointer to the context structure. * \param data pointer to the injected data. * \param len injected data length (in bytes). */ void br_multihash_update(br_multihash_context *ctx, const void *data, size_t len); /** * \brief Compute a hash output from a multi-hasher. * * The hash output for the concatenation of all bytes injected in the * provided context since the last initialisation or reset call, is * computed and written in the buffer pointed to by `dst`. The hash * function to use is identified by `id` and must be one of the standard * hash functions. If that hash function was indeed configured in the * multi-hasher context, the corresponding hash value is written in * `dst` and its length (in bytes) is returned. If the hash function * was _not_ configured, then nothing is written in `dst` and 0 is * returned. * * The context itself is not modified, so extra bytes may be injected * afterwards to continue the hash computations. * * \param ctx pointer to the context structure. * \param id the hash function symbolic identifier. * \param dst destination buffer for the hash output. * \return the hash output length (in bytes), or 0. */ size_t br_multihash_out(const br_multihash_context *ctx, int id, void *dst); /** * \brief Type for a GHASH implementation. * * GHASH is a sort of keyed hash meant to be used to implement GCM in * combination with a block cipher (with 16-byte blocks). * * The `y` array has length 16 bytes and is used for input and output; in * a complete GHASH run, it starts with an all-zero value. `h` is a 16-byte * value that serves as key (it is derived from the encryption key in GCM, * using the block cipher). The data length (`len`) is expressed in bytes. * The `y` array is updated. * * If the data length is not a multiple of 16, then the data is implicitly * padded with zeros up to the next multiple of 16. Thus, when using GHASH * in GCM, this method may be called twice, for the associated data and * for the ciphertext, respectively; the zero-padding implements exactly * the GCM rules. * * \param y the array to update. * \param h the GHASH key. * \param data the input data (may be `NULL` if `len` is zero). * \param len the input data length (in bytes). */ typedef void (*br_ghash)(void *y, const void *h, const void *data, size_t len); /** * \brief GHASH implementation using multiplications (mixed 32-bit). * * This implementation uses multiplications of 32-bit values, with a * 64-bit result. It is constant-time (if multiplications are * constant-time). * * \param y the array to update. * \param h the GHASH key. * \param data the input data (may be `NULL` if `len` is zero). * \param len the input data length (in bytes). */ void br_ghash_ctmul(void *y, const void *h, const void *data, size_t len); /** * \brief GHASH implementation using multiplications (strict 32-bit). * * This implementation uses multiplications of 32-bit values, with a * 32-bit result. It is usually somewhat slower than `br_ghash_ctmul()`, * but it is expected to be faster on architectures for which the * 32-bit multiplication opcode does not yield the upper 32 bits of the * product. It is constant-time (if multiplications are constant-time). * * \param y the array to update. * \param h the GHASH key. * \param data the input data (may be `NULL` if `len` is zero). * \param len the input data length (in bytes). */ void br_ghash_ctmul32(void *y, const void *h, const void *data, size_t len); /** * \brief GHASH implementation using multiplications (64-bit). * * This implementation uses multiplications of 64-bit values, with a * 64-bit result. It is constant-time (if multiplications are * constant-time). It is substantially faster than `br_ghash_ctmul()` * and `br_ghash_ctmul32()` on most 64-bit architectures. * * \param y the array to update. * \param h the GHASH key. * \param data the input data (may be `NULL` if `len` is zero). * \param len the input data length (in bytes). */ void br_ghash_ctmul64(void *y, const void *h, const void *data, size_t len); /** * \brief GHASH implementation using the `pclmulqdq` opcode (part of the * AES-NI instructions). * * This implementation is available only on x86 platforms where the * compiler supports the relevant intrinsic functions. Even if the * compiler supports these functions, the local CPU might not support * the `pclmulqdq` opcode, meaning that a call will fail with an * illegal instruction exception. To safely obtain a pointer to this * function when supported (or 0 otherwise), use `br_ghash_pclmul_get()`. * * \param y the array to update. * \param h the GHASH key. * \param data the input data (may be `NULL` if `len` is zero). * \param len the input data length (in bytes). */ void br_ghash_pclmul(void *y, const void *h, const void *data, size_t len); /** * \brief Obtain the `pclmul` GHASH implementation, if available. * * If the `pclmul` implementation was compiled in the library (depending * on the compiler abilities) _and_ the local CPU appears to support the * opcode, then this function will return a pointer to the * `br_ghash_pclmul()` function. Otherwise, it will return `0`. * * \return the `pclmul` GHASH implementation, or `0`. */ br_ghash br_ghash_pclmul_get(void); /** * \brief GHASH implementation using the POWER8 opcodes. * * This implementation is available only on POWER8 platforms (and later). * To safely obtain a pointer to this function when supported (or 0 * otherwise), use `br_ghash_pwr8_get()`. * * \param y the array to update. * \param h the GHASH key. * \param data the input data (may be `NULL` if `len` is zero). * \param len the input data length (in bytes). */ void br_ghash_pwr8(void *y, const void *h, const void *data, size_t len); /** * \brief Obtain the `pwr8` GHASH implementation, if available. * * If the `pwr8` implementation was compiled in the library (depending * on the compiler abilities) _and_ the local CPU appears to support the * opcode, then this function will return a pointer to the * `br_ghash_pwr8()` function. Otherwise, it will return `0`. * * \return the `pwr8` GHASH implementation, or `0`. */ br_ghash br_ghash_pwr8_get(void); #ifdef __cplusplus } #endif #endif