/* ghmac.h - data hashing functions * * Copyright (C) 2011 Collabora Ltd. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. * * Author: Stef Walter */ #include "config.h" #include #include "ghmac.h" #include "glib/galloca.h" #include "gatomic.h" #include "gslice.h" #include "gmem.h" #include "gstrfuncs.h" #include "gtestutils.h" #include "gtypes.h" #include "glibintl.h" /** * SECTION:hmac * @title: Secure HMAC Digests * @short_description: computes the HMAC for data * * HMACs should be used when producing a cookie or hash based on data * and a key. Simple mechanisms for using SHA1 and other algorithms to * digest a key and data together are vulnerable to various security * issues. HMAC * uses algorithms like SHA1 in a secure way to produce a digest of a * key and data. * * Both the key and data are arbitrary byte arrays of bytes or characters. * * Support for HMAC Digests has been added in GLib 2.30. */ struct _GHmac { int ref_count; GChecksumType digest_type; GChecksum *digesti; GChecksum *digesto; }; /** * g_hmac_new: * @digest_type: the desired type of digest * @key: (array length=key_len): the key for the HMAC * @key_len: the length of the keys * * Creates a new #GHmac, using the digest algorithm @digest_type. * If the @digest_type is not known, %NULL is returned. * A #GHmac can be used to compute the HMAC of a key and an * arbitrary binary blob, using different hashing algorithms. * * A #GHmac works by feeding a binary blob through g_hmac_update() * until the data is complete; the digest can then be extracted * using g_hmac_get_string(), which will return the checksum as a * hexadecimal string; or g_hmac_get_digest(), which will return a * array of raw bytes. Once either g_hmac_get_string() or * g_hmac_get_digest() have been called on a #GHmac, the HMAC * will be closed and it won't be possible to call g_hmac_update() * on it anymore. * * Return value: the newly created #GHmac, or %NULL. * Use g_hmac_unref() to free the memory allocated by it. * * Since: 2.30 */ GHmac * g_hmac_new (GChecksumType digest_type, const guchar *key, gsize key_len) { GChecksum *checksum; GHmac *hmac; guchar *buffer; guchar *pad; gsize i, len; gsize block_size; checksum = g_checksum_new (digest_type); g_return_val_if_fail (checksum != NULL, NULL); switch (digest_type) { case G_CHECKSUM_MD5: case G_CHECKSUM_SHA1: block_size = 64; /* RFC 2104 */ break; case G_CHECKSUM_SHA256: block_size = 64; /* RFC draft-kelly-ipsec-ciph-sha2-01 */ break; default: g_return_val_if_reached (NULL); } hmac = g_slice_new0 (GHmac); hmac->ref_count = 1; hmac->digest_type = digest_type; hmac->digesti = checksum; hmac->digesto = g_checksum_new (digest_type); buffer = g_alloca (block_size); pad = g_alloca (block_size); memset (buffer, 0, block_size); /* If the key is too long, hash it */ if (key_len > block_size) { len = block_size; g_checksum_update (hmac->digesti, key, key_len); g_checksum_get_digest (hmac->digesti, buffer, &len); g_checksum_reset (hmac->digesti); } /* Otherwise pad it with zeros */ else { memcpy (buffer, key, key_len); } /* First pad */ for (i = 0; i < block_size; i++) pad[i] = 0x36 ^ buffer[i]; /* ipad value */ g_checksum_update (hmac->digesti, pad, block_size); /* Second pad */ for (i = 0; i < block_size; i++) pad[i] = 0x5c ^ buffer[i]; /* opad value */ g_checksum_update (hmac->digesto, pad, block_size); return hmac; } /** * g_hmac_copy: * @hmac: the #GHmac to copy * * Copies a #GHmac. If @hmac has been closed, by calling * g_hmac_get_string() or g_hmac_get_digest(), the copied * HMAC will be closed as well. * * Return value: the copy of the passed #GHmac. Use g_hmac_unref() * when finished using it. * * Since: 2.30 */ GHmac * g_hmac_copy (const GHmac *hmac) { GHmac *copy; g_return_val_if_fail (hmac != NULL, NULL); copy = g_slice_new (GHmac); copy->ref_count = 1; copy->digest_type = hmac->digest_type; copy->digesti = g_checksum_copy (hmac->digesti); copy->digesto = g_checksum_copy (hmac->digesto); return copy; } /** * g_hmac_ref: * @hmac: a valid #GHmac * * Atomically increments the reference count of @hmac by one. * * This function is MT-safe and may be called from any thread. * * Return value: the passed in #GHmac. * * Since: 2.30 **/ GHmac * g_hmac_ref (GHmac *hmac) { g_return_val_if_fail (hmac != NULL, NULL); g_atomic_int_inc (&hmac->ref_count); return hmac; } /** * g_hmac_unref: * @hmac: a #GHmac * * Atomically decrements the reference count of @hmac by one. * * If the reference count drops to 0, all keys and values will be * destroyed, and all memory allocated by the hash table is released. * This function is MT-safe and may be called from any thread. * Frees the memory allocated for @hmac. * * Since: 2.30 */ void g_hmac_unref (GHmac *hmac) { g_return_if_fail (hmac != NULL); if (g_atomic_int_dec_and_test (&hmac->ref_count)) { g_checksum_free (hmac->digesti); g_checksum_free (hmac->digesto); g_slice_free (GHmac, hmac); } } /** * g_hmac_update: * @hmac: a #GHmac * @data: (array length=length): buffer used to compute the checksum * @length: size of the buffer, or -1 if it is a nul-terminated string * * Feeds @data into an existing #GHmac. * * The HMAC must still be open, that is g_hmac_get_string() or * g_hmac_get_digest() must not have been called on @hmac. * * Since: 2.30 */ void g_hmac_update (GHmac *hmac, const guchar *data, gssize length) { g_return_if_fail (hmac != NULL); g_return_if_fail (length == 0 || data != NULL); g_checksum_update (hmac->digesti, data, length); } /** * g_hmac_get_string: * @hmac: a #GHmac * * Gets the HMAC as an hexadecimal string. * * Once this function has been called the #GHmac can no longer be * updated with g_hmac_update(). * * The hexadecimal characters will be lower case. * * Return value: the hexadecimal representation of the HMAC. The * returned string is owned by the HMAC and should not be modified * or freed. * * Since: 2.30 */ const gchar * g_hmac_get_string (GHmac *hmac) { guint8 *buffer; gsize digest_len; g_return_val_if_fail (hmac != NULL, NULL); digest_len = g_checksum_type_get_length (hmac->digest_type); buffer = g_alloca (digest_len); /* This is only called for its side-effect of updating hmac->digesto... */ g_hmac_get_digest (hmac, buffer, &digest_len); /* ... because we get the string from the checksum rather than * stringifying buffer ourselves */ return g_checksum_get_string (hmac->digesto); } /** * g_hmac_get_digest: * @hmac: a #GHmac * @buffer: output buffer * @digest_len: an inout parameter. The caller initializes it to the * size of @buffer. After the call it contains the length of the digest * * Gets the digest from @checksum as a raw binary array and places it * into @buffer. The size of the digest depends on the type of checksum. * * Once this function has been called, the #GHmac is closed and can * no longer be updated with g_checksum_update(). * * Since: 2.30 */ void g_hmac_get_digest (GHmac *hmac, guint8 *buffer, gsize *digest_len) { gsize len; g_return_if_fail (hmac != NULL); len = g_checksum_type_get_length (hmac->digest_type); g_return_if_fail (*digest_len >= len); /* Use the same buffer, because we can :) */ g_checksum_get_digest (hmac->digesti, buffer, &len); g_checksum_update (hmac->digesto, buffer, len); g_checksum_get_digest (hmac->digesto, buffer, digest_len); } /** * g_compute_hmac_for_data: * @digest_type: a #GChecksumType to use for the HMAC * @key: (array length=key_len): the key to use in the HMAC * @key_len: the length of the key * @data: binary blob to compute the HMAC of * @length: length of @data * * Computes the HMAC for a binary @data of @length. This is a * convenience wrapper for g_hmac_new(), g_hmac_get_string() * and g_hmac_unref(). * * The hexadecimal string returned will be in lower case. * * Return value: the HMAC of the binary data as a string in hexadecimal. * The returned string should be freed with g_free() when done using it. * * Since: 2.30 */ gchar * g_compute_hmac_for_data (GChecksumType digest_type, const guchar *key, gsize key_len, const guchar *data, gsize length) { GHmac *hmac; gchar *retval; g_return_val_if_fail (length == 0 || data != NULL, NULL); hmac = g_hmac_new (digest_type, key, key_len); if (!hmac) return NULL; g_hmac_update (hmac, data, length); retval = g_strdup (g_hmac_get_string (hmac)); g_hmac_unref (hmac); return retval; } /** * g_compute_hmac_for_string: * @digest_type: a #GChecksumType to use for the HMAC * @key: (array length=key_len): the key to use in the HMAC * @key_len: the length of the key * @str: the string to compute the HMAC for * @length: the length of the string, or -1 if the string is nul-terminated * * Computes the HMAC for a string. * * The hexadecimal string returned will be in lower case. * * Return value: the HMAC as a hexadecimal string. * The returned string should be freed with g_free() * when done using it. * * Since: 2.30 */ gchar * g_compute_hmac_for_string (GChecksumType digest_type, const guchar *key, gsize key_len, const gchar *str, gssize length) { g_return_val_if_fail (length == 0 || str != NULL, NULL); if (length < 0) length = strlen (str); return g_compute_hmac_for_data (digest_type, key, key_len, (const guchar *) str, length); }