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512 lines
20 KiB
C
512 lines
20 KiB
C
/******************************************************************************
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*
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* THIS SOURCE CODE IS HEREBY PLACED INTO THE PUBLIC DOMAIN FOR THE GOOD OF ALL
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*
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* This is a simple and straightforward implementation of AES-GCM authenticated
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* encryption. The focus of this work was correctness & accuracy. It is written
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* in straight 'C' without any particular focus upon optimization or speed. It
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* should be endian (memory byte order) neutral since the few places that care
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* are handled explicitly.
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*
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* This implementation of AES-GCM was created by Steven M. Gibson of GRC.com.
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*
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* It is intended for general purpose use, but was written in support of GRC's
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* reference implementation of the SQRL (Secure Quick Reliable Login) client.
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*
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* See: http://csrc.nist.gov/publications/nistpubs/800-38D/SP-800-38D.pdf
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* http://csrc.nist.gov/groups/ST/toolkit/BCM/documents/proposedmodes/
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* gcm/gcm-revised-spec.pdf
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*
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* NO COPYRIGHT IS CLAIMED IN THIS WORK, HOWEVER, NEITHER IS ANY WARRANTY MADE
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* REGARDING ITS FITNESS FOR ANY PARTICULAR PURPOSE. USE IT AT YOUR OWN RISK.
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*
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*******************************************************************************/
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#include "gcm.h"
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#include "aes.h"
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/******************************************************************************
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* ==== IMPLEMENTATION WARNING ====
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*
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* This code was developed for use within SQRL's fixed environmnent. Thus, it
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* is somewhat less "general purpose" than it would be if it were designed as
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* a general purpose AES-GCM library. Specifically, it bothers with almost NO
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* error checking on parameter limits, buffer bounds, etc. It assumes that it
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* is being invoked by its author or by someone who understands the values it
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* expects to receive. Its behavior will be undefined otherwise.
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*
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* All functions that might fail are defined to return 'ints' to indicate a
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* problem. Most do not do so now. But this allows for error propagation out
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* of internal functions if robust error checking should ever be desired.
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*
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******************************************************************************/
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/* Calculating the "GHASH"
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*
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* There are many ways of calculating the so-called GHASH in software, each with
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* a traditional size vs performance tradeoff. The GHASH (Galois field hash) is
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* an intriguing construction which takes two 128-bit strings (also the cipher's
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* block size and the fundamental operation size for the system) and hashes them
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* into a third 128-bit result.
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*
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* Many implementation solutions have been worked out that use large precomputed
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* table lookups in place of more time consuming bit fiddling, and this approach
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* can be scaled easily upward or downward as needed to change the time/space
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* tradeoff. It's been studied extensively and there's a solid body of theory and
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* practice. For example, without using any lookup tables an implementation
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* might obtain 119 cycles per byte throughput, whereas using a simple, though
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* large, key-specific 64 kbyte 8-bit lookup table the performance jumps to 13
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* cycles per byte.
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*
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* And Intel's processors have, since 2010, included an instruction which does
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* the entire 128x128->128 bit job in just several 64x64->128 bit pieces.
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*
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* Since SQRL is interactive, and only processing a few 128-bit blocks, I've
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* settled upon a relatively slower but appealing small-table compromise which
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* folds a bunch of not only time consuming but also bit twiddling into a simple
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* 16-entry table which is attributed to Victor Shoup's 1996 work while at
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* Bellcore: "On Fast and Provably Secure MessageAuthentication Based on
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* Universal Hashing." See: http://www.shoup.net/papers/macs.pdf
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* See, also section 4.1 of the "gcm-revised-spec" cited above.
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*/
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/*
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* This 16-entry table of pre-computed constants is used by the
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* GHASH multiplier to improve over a strictly table-free but
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* significantly slower 128x128 bit multiple within GF(2^128).
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*/
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static const uint64_t last4[16] = {
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0x0000, 0x1c20, 0x3840, 0x2460, 0x7080, 0x6ca0, 0x48c0, 0x54e0,
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0xe100, 0xfd20, 0xd940, 0xc560, 0x9180, 0x8da0, 0xa9c0, 0xb5e0 };
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/*
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* Platform Endianness Neutralizing Load and Store Macro definitions
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* GCM wants platform-neutral Big Endian (BE) byte ordering
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*/
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#define GET_UINT32_BE(n,b,i) { \
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(n) = ( (uint32_t) (b)[(i) ] << 24 ) \
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| ( (uint32_t) (b)[(i) + 1] << 16 ) \
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| ( (uint32_t) (b)[(i) + 2] << 8 ) \
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| ( (uint32_t) (b)[(i) + 3] ); }
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#define PUT_UINT32_BE(n,b,i) { \
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(b)[(i) ] = (uchar) ( (n) >> 24 ); \
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(b)[(i) + 1] = (uchar) ( (n) >> 16 ); \
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(b)[(i) + 2] = (uchar) ( (n) >> 8 ); \
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(b)[(i) + 3] = (uchar) ( (n) ); }
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/******************************************************************************
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*
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* GCM_INITIALIZE
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*
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* Must be called once to initialize the GCM library.
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*
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* At present, this only calls the AES keygen table generator, which expands
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* the AES keying tables for use. This is NOT A THREAD-SAFE function, so it
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* MUST be called during system initialization before a multi-threading
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* environment is running.
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*
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******************************************************************************/
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int gcm_initialize(void)
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{
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aes_init_keygen_tables();
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return(0);
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}
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/******************************************************************************
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*
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* GCM_MULT
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*
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* Performs a GHASH operation on the 128-bit input vector 'x', setting
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* the 128-bit output vector to 'x' times H using our precomputed tables.
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* 'x' and 'output' are seen as elements of GCM's GF(2^128) Galois field.
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*
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******************************************************************************/
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static void gcm_mult(gcm_context *ctx, // pointer to established context
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const uchar x[16], // pointer to 128-bit input vector
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uchar output[16]) // pointer to 128-bit output vector
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{
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int i;
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uchar lo, hi, rem;
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uint64_t zh, zl;
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lo = (uchar)(x[15] & 0x0f);
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hi = (uchar)(x[15] >> 4);
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zh = ctx->HH[lo];
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zl = ctx->HL[lo];
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for (i = 15; i >= 0; i--) {
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lo = (uchar)(x[i] & 0x0f);
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hi = (uchar)(x[i] >> 4);
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if (i != 15) {
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rem = (uchar)(zl & 0x0f);
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zl = (zh << 60) | (zl >> 4);
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zh = (zh >> 4);
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zh ^= (uint64_t)last4[rem] << 48;
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zh ^= ctx->HH[lo];
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zl ^= ctx->HL[lo];
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}
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rem = (uchar)(zl & 0x0f);
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zl = (zh << 60) | (zl >> 4);
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zh = (zh >> 4);
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zh ^= (uint64_t)last4[rem] << 48;
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zh ^= ctx->HH[hi];
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zl ^= ctx->HL[hi];
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}
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PUT_UINT32_BE(zh >> 32, output, 0);
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PUT_UINT32_BE(zh, output, 4);
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PUT_UINT32_BE(zl >> 32, output, 8);
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PUT_UINT32_BE(zl, output, 12);
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}
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/******************************************************************************
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*
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* GCM_SETKEY
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*
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* This is called to set the AES-GCM key. It initializes the AES key
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* and populates the gcm context's pre-calculated HTables.
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*
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******************************************************************************/
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int gcm_setkey(gcm_context *ctx, // pointer to caller-provided gcm context
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const uchar *key, // pointer to the AES encryption key
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const uint keysize) // size in bytes (must be 16, 24, 32 for
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// 128, 192 or 256-bit keys respectively)
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{
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int ret, i, j;
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uint64_t hi, lo;
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uint64_t vl, vh;
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unsigned char h[16];
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memset(ctx, 0, sizeof(gcm_context)); // zero caller-provided GCM context
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memset(h, 0, 16); // initialize the block to encrypt
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// encrypt the null 128-bit block to generate a key-based value
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// which is then used to initialize our GHASH lookup tables
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if ((ret = aes_setkey(&ctx->aes_ctx, ENCRYPT, key, keysize)) != 0)
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return(ret);
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if ((ret = aes_cipher(&ctx->aes_ctx, h, h)) != 0)
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return(ret);
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GET_UINT32_BE(hi, h, 0); // pack h as two 64-bit ints, big-endian
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GET_UINT32_BE(lo, h, 4);
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vh = (uint64_t)hi << 32 | lo;
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GET_UINT32_BE(hi, h, 8);
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GET_UINT32_BE(lo, h, 12);
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vl = (uint64_t)hi << 32 | lo;
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ctx->HL[8] = vl; // 8 = 1000 corresponds to 1 in GF(2^128)
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ctx->HH[8] = vh;
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ctx->HH[0] = 0; // 0 corresponds to 0 in GF(2^128)
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ctx->HL[0] = 0;
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for (i = 4; i > 0; i >>= 1) {
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uint32_t T = (uint32_t)(vl & 1) * 0xe1000000U;
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vl = (vh << 63) | (vl >> 1);
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vh = (vh >> 1) ^ ((uint64_t)T << 32);
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ctx->HL[i] = vl;
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ctx->HH[i] = vh;
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}
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for (i = 2; i < 16; i <<= 1) {
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uint64_t *HiL = ctx->HL + i, *HiH = ctx->HH + i;
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vh = *HiH;
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vl = *HiL;
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for (j = 1; j < i; j++) {
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HiH[j] = vh ^ ctx->HH[j];
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HiL[j] = vl ^ ctx->HL[j];
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}
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}
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return(0);
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}
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/******************************************************************************
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*
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* GCM processing occurs four phases: SETKEY, START, UPDATE and FINISH.
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*
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* SETKEY:
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*
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* START: Sets the Encryption/Decryption mode.
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* Accepts the initialization vector and additional data.
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*
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* UPDATE: Encrypts or decrypts the plaintext or ciphertext.
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*
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* FINISH: Performs a final GHASH to generate the authentication tag.
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*
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******************************************************************************
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*
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* GCM_START
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*
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* Given a user-provided GCM context, this initializes it, sets the encryption
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* mode, and preprocesses the initialization vector and additional AEAD data.
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*
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******************************************************************************/
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int gcm_start(gcm_context *ctx, // pointer to user-provided GCM context
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int mode, // GCM_ENCRYPT or GCM_DECRYPT
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const uchar *iv, // pointer to initialization vector
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size_t iv_len, // IV length in bytes (should == 12)
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const uchar *add, // ptr to additional AEAD data (NULL if none)
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size_t add_len) // length of additional AEAD data (bytes)
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{
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int ret; // our error return if the AES encrypt fails
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uchar work_buf[16]; // XOR source built from provided IV if len != 16
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const uchar *p; // general purpose array pointer
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size_t use_len; // byte count to process, up to 16 bytes
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size_t i; // local loop iterator
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// since the context might be reused under the same key
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// we zero the working buffers for this next new process
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memset(ctx->y, 0x00, sizeof(ctx->y));
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memset(ctx->buf, 0x00, sizeof(ctx->buf));
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ctx->len = 0;
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ctx->add_len = 0;
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ctx->mode = mode; // set the GCM encryption/decryption mode
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ctx->aes_ctx.mode = ENCRYPT; // GCM *always* runs AES in ENCRYPTION mode
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if (iv_len == 12) { // GCM natively uses a 12-byte, 96-bit IV
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memcpy(ctx->y, iv, iv_len); // copy the IV to the top of the 'y' buff
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ctx->y[15] = 1; // start "counting" from 1 (not 0)
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}
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else // if we don't have a 12-byte IV, we GHASH whatever we've been given
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{
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memset(work_buf, 0x00, 16); // clear the working buffer
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PUT_UINT32_BE(iv_len * 8, work_buf, 12); // place the IV into buffer
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p = iv;
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while (iv_len > 0) {
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use_len = (iv_len < 16) ? iv_len : 16;
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for (i = 0; i < use_len; i++) ctx->y[i] ^= p[i];
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gcm_mult(ctx, ctx->y, ctx->y);
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iv_len -= use_len;
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p += use_len;
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}
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for (i = 0; i < 16; i++) ctx->y[i] ^= work_buf[i];
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gcm_mult(ctx, ctx->y, ctx->y);
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}
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if ((ret = aes_cipher(&ctx->aes_ctx, ctx->y, ctx->base_ectr)) != 0)
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return(ret);
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ctx->add_len = add_len;
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p = add;
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while (add_len > 0) {
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use_len = (add_len < 16) ? add_len : 16;
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for (i = 0; i < use_len; i++) ctx->buf[i] ^= p[i];
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gcm_mult(ctx, ctx->buf, ctx->buf);
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add_len -= use_len;
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p += use_len;
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}
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return(0);
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}
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/******************************************************************************
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*
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* GCM_UPDATE
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*
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* This is called once or more to process bulk plaintext or ciphertext data.
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* We give this some number of bytes of input and it returns the same number
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* of output bytes. If called multiple times (which is fine) all but the final
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* invocation MUST be called with length mod 16 == 0. (Only the final call can
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* have a partial block length of < 128 bits.)
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*
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******************************************************************************/
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int gcm_update(gcm_context *ctx, // pointer to user-provided GCM context
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size_t length, // length, in bytes, of data to process
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const uchar *input, // pointer to source data
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uchar *output) // pointer to destination data
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{
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int ret; // our error return if the AES encrypt fails
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uchar ectr[16]; // counter-mode cipher output for XORing
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size_t use_len; // byte count to process, up to 16 bytes
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size_t i; // local loop iterator
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ctx->len += length; // bump the GCM context's running length count
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while (length > 0) {
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// clamp the length to process at 16 bytes
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use_len = (length < 16) ? length : 16;
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// increment the context's 128-bit IV||Counter 'y' vector
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for (i = 16; i > 12; i--) if (++ctx->y[i - 1] != 0) break;
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// encrypt the context's 'y' vector under the established key
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if ((ret = aes_cipher(&ctx->aes_ctx, ctx->y, ectr)) != 0)
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return(ret);
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// encrypt or decrypt the input to the output
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if (ctx->mode == ENCRYPT)
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{
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for (i = 0; i < use_len; i++) {
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// XOR the cipher's ouptut vector (ectr) with our input
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output[i] = (uchar)(ectr[i] ^ input[i]);
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// now we mix in our data into the authentication hash.
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// if we're ENcrypting we XOR in the post-XOR (output)
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// results, but if we're DEcrypting we XOR in the input
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// data
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ctx->buf[i] ^= output[i];
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}
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}
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else
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{
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for (i = 0; i < use_len; i++) {
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// but if we're DEcrypting we XOR in the input data first,
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// i.e. before saving to ouput data, otherwise if the input
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// and output buffer are the same (inplace decryption) we
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// would not get the correct auth tag
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ctx->buf[i] ^= input[i];
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// XOR the cipher's ouptut vector (ectr) with our input
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output[i] = (uchar)(ectr[i] ^ input[i]);
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}
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}
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gcm_mult(ctx, ctx->buf, ctx->buf); // perform a GHASH operation
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length -= use_len; // drop the remaining byte count to process
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input += use_len; // bump our input pointer forward
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output += use_len; // bump our output pointer forward
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}
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return(0);
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}
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/******************************************************************************
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*
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* GCM_FINISH
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*
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* This is called once after all calls to GCM_UPDATE to finalize the GCM.
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* It performs the final GHASH to produce the resulting authentication TAG.
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*
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******************************************************************************/
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int gcm_finish(gcm_context *ctx, // pointer to user-provided GCM context
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uchar *tag, // pointer to buffer which receives the tag
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size_t tag_len) // length, in bytes, of the tag-receiving buf
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{
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uchar work_buf[16];
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uint64_t orig_len = ctx->len * 8;
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uint64_t orig_add_len = ctx->add_len * 8;
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size_t i;
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if (tag_len != 0) memcpy(tag, ctx->base_ectr, tag_len);
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if (orig_len || orig_add_len) {
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memset(work_buf, 0x00, 16);
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PUT_UINT32_BE((orig_add_len >> 32), work_buf, 0);
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PUT_UINT32_BE((orig_add_len), work_buf, 4);
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PUT_UINT32_BE((orig_len >> 32), work_buf, 8);
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PUT_UINT32_BE((orig_len), work_buf, 12);
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for (i = 0; i < 16; i++) ctx->buf[i] ^= work_buf[i];
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gcm_mult(ctx, ctx->buf, ctx->buf);
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for (i = 0; i < tag_len; i++) tag[i] ^= ctx->buf[i];
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}
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return(0);
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}
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/******************************************************************************
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*
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* GCM_CRYPT_AND_TAG
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*
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* This either encrypts or decrypts the user-provided data and, either
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* way, generates an authentication tag of the requested length. It must be
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* called with a GCM context whose key has already been set with GCM_SETKEY.
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*
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* The user would typically call this explicitly to ENCRYPT a buffer of data
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* and optional associated data, and produce its an authentication tag.
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*
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* To reverse the process the user would typically call the companion
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* GCM_AUTH_DECRYPT function to decrypt data and verify a user-provided
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* authentication tag. The GCM_AUTH_DECRYPT function calls this function
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* to perform its decryption and tag generation, which it then compares.
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*
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******************************************************************************/
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int gcm_crypt_and_tag(
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gcm_context *ctx, // gcm context with key already setup
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int mode, // cipher direction: GCM_ENCRYPT or GCM_DECRYPT
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const uchar *iv, // pointer to the 12-byte initialization vector
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size_t iv_len, // byte length if the IV. should always be 12
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const uchar *add, // pointer to the non-ciphered additional data
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size_t add_len, // byte length of the additional AEAD data
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const uchar *input, // pointer to the cipher data source
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uchar *output, // pointer to the cipher data destination
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size_t length, // byte length of the cipher data
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uchar *tag, // pointer to the tag to be generated
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size_t tag_len) // byte length of the tag to be generated
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{ /*
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assuming that the caller has already invoked gcm_setkey to
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prepare the gcm context with the keying material, we simply
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invoke each of the three GCM sub-functions in turn...
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*/
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gcm_start(ctx, mode, iv, iv_len, add, add_len);
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gcm_update(ctx, length, input, output);
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gcm_finish(ctx, tag, tag_len);
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return(0);
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}
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/******************************************************************************
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*
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* GCM_AUTH_DECRYPT
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*
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* This DECRYPTS a user-provided data buffer with optional associated data.
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* It then verifies a user-supplied authentication tag against the tag just
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* re-created during decryption to verify that the data has not been altered.
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*
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* This function calls GCM_CRYPT_AND_TAG (above) to perform the decryption
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* and authentication tag generation.
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*
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******************************************************************************/
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int gcm_auth_decrypt(
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gcm_context *ctx, // gcm context with key already setup
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const uchar *iv, // pointer to the 12-byte initialization vector
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size_t iv_len, // byte length if the IV. should always be 12
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const uchar *add, // pointer to the non-ciphered additional data
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size_t add_len, // byte length of the additional AEAD data
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const uchar *input, // pointer to the cipher data source
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uchar *output, // pointer to the cipher data destination
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size_t length, // byte length of the cipher data
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const uchar *tag, // pointer to the tag to be authenticated
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size_t tag_len) // byte length of the tag <= 16
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{
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uchar check_tag[16]; // the tag generated and returned by decryption
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int diff; // an ORed flag to detect authentication errors
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size_t i; // our local iterator
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/*
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we use GCM_DECRYPT_AND_TAG (above) to perform our decryption
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(which is an identical XORing to reverse the previous one)
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and also to re-generate the matching authentication tag
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*/
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gcm_crypt_and_tag(ctx, DECRYPT, iv, iv_len, add, add_len,
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input, output, length, check_tag, tag_len);
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// now we verify the authentication tag in 'constant time'
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for (diff = 0, i = 0; i < tag_len; i++)
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diff |= tag[i] ^ check_tag[i];
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if (diff != 0) { // see whether any bits differed?
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memset(output, 0, length); // if so... wipe the output data
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return(GCM_AUTH_FAILURE); // return GCM_AUTH_FAILURE
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}
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return(0);
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}
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/******************************************************************************
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*
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* GCM_ZERO_CTX
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*
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* The GCM context contains both the GCM context and the AES context.
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* This includes keying and key-related material which is security-
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* sensitive, so it MUST be zeroed after use. This function does that.
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*
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******************************************************************************/
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void gcm_zero_ctx(gcm_context *ctx)
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{
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// zero the context originally provided to us
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memset(ctx, 0, sizeof(gcm_context));
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}
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