#include #include #include "params.h" #include "poly.h" #include "ntt.h" #include "reduce.h" #include "cbd.h" #include "symmetric.h" #include "../../../internal.h" /************************************************* * Name: poly_compress * * Description: Compression and subsequent serialization of a polynomial * * Arguments: - uint8_t *r: pointer to output byte array * (of length KYBER_POLYCOMPRESSEDBYTES) * - const poly *a: pointer to input polynomial **************************************************/ void poly_compress(ml_kem_params *params, uint8_t *r, const poly *a) { unsigned int i,j; int32_t u; uint32_t d0; uint8_t t[8]; assert((params->poly_compressed_bytes == 128) || (params->poly_compressed_bytes == 160)); if (params->poly_compressed_bytes == 128) { for(i=0;icoeffs[8*i+j]; u += (u >> 15) & KYBER_Q; // t[j] = ((((uint16_t)u << 4) + KYBER_Q/2)/KYBER_Q) & 15; d0 = u << 4; d0 += 1665; d0 *= 80635; d0 >>= 28; t[j] = d0 & 0xf; } r[0] = t[0] | (t[1] << 4); r[1] = t[2] | (t[3] << 4); r[2] = t[4] | (t[5] << 4); r[3] = t[6] | (t[7] << 4); r += 4; } } else { for(i=0;icoeffs[8*i+j]; u += (u >> 15) & KYBER_Q; // t[j] = ((((uint32_t)u << 5) + KYBER_Q/2)/KYBER_Q) & 31; d0 = u << 5; d0 += 1664; d0 *= 40318; d0 >>= 27; t[j] = d0 & 0x1f; } r[0] = (t[0] >> 0) | (t[1] << 5); r[1] = (t[1] >> 3) | (t[2] << 2) | (t[3] << 7); r[2] = (t[3] >> 1) | (t[4] << 4); r[3] = (t[4] >> 4) | (t[5] << 1) | (t[6] << 6); r[4] = (t[6] >> 2) | (t[7] << 3); r += 5; } } } /************************************************* * Name: poly_decompress * * Description: De-serialization and subsequent decompression of a polynomial; * approximate inverse of poly_compress * * Arguments: - poly *r: pointer to output polynomial * - const uint8_t *a: pointer to input byte array * (of length KYBER_POLYCOMPRESSEDBYTES bytes) **************************************************/ void poly_decompress(ml_kem_params *params, poly *r, const uint8_t *a) { unsigned int i; assert((params->poly_compressed_bytes == 128) || (params->poly_compressed_bytes == 160)); if (params->poly_compressed_bytes == 128) { for(i=0;icoeffs[2*i+0] = (((uint16_t)(a[0] & 15)*KYBER_Q) + 8) >> 4; r->coeffs[2*i+1] = (((uint16_t)(a[0] >> 4)*KYBER_Q) + 8) >> 4; a += 1; } } else { unsigned int j; uint8_t t[8]; for(i=0;i> 0); t[1] = (a[0] >> 5) | (a[1] << 3); t[2] = (a[1] >> 2); t[3] = (a[1] >> 7) | (a[2] << 1); t[4] = (a[2] >> 4) | (a[3] << 4); t[5] = (a[3] >> 1); t[6] = (a[3] >> 6) | (a[4] << 2); t[7] = (a[4] >> 3); a += 5; for(j=0;j<8;j++) r->coeffs[8*i+j] = ((uint32_t)(t[j] & 31)*KYBER_Q + 16) >> 5; } } } /************************************************* * Name: poly_tobytes * * Description: Serialization of a polynomial * * Arguments: - uint8_t *r: pointer to output byte array * (needs space for KYBER_POLYBYTES bytes) * - const poly *a: pointer to input polynomial **************************************************/ void poly_tobytes(uint8_t r[KYBER_POLYBYTES], const poly *a) { unsigned int i; uint16_t t0, t1; for(i=0;icoeffs[2*i]; t0 += ((int16_t)t0 >> 15) & KYBER_Q; t1 = a->coeffs[2*i+1]; t1 += ((int16_t)t1 >> 15) & KYBER_Q; r[3*i+0] = (t0 >> 0); r[3*i+1] = (t0 >> 8) | (t1 << 4); r[3*i+2] = (t1 >> 4); } } /************************************************* * Name: poly_frombytes * * Description: De-serialization of a polynomial; * inverse of poly_tobytes * * Arguments: - poly *r: pointer to output polynomial * - const uint8_t *a: pointer to input byte array * (of KYBER_POLYBYTES bytes) **************************************************/ void poly_frombytes(poly *r, const uint8_t a[KYBER_POLYBYTES]) { unsigned int i; for(i=0;icoeffs[2*i] = ((a[3*i+0] >> 0) | ((uint16_t)a[3*i+1] << 8)) & 0xFFF; r->coeffs[2*i+1] = ((a[3*i+1] >> 4) | ((uint16_t)a[3*i+2] << 4)) & 0xFFF; } } /************************************************* * Name: poly_frommsg * * Description: Convert 32-byte message to polynomial * * Arguments: - poly *r: pointer to output polynomial * - const uint8_t *msg: pointer to input message **************************************************/ void poly_frommsg(poly *r, const uint8_t msg[KYBER_INDCPA_MSGBYTES]) { unsigned int i,j; crypto_word_t mask; #if (KYBER_INDCPA_MSGBYTES != KYBER_N/8) #error "KYBER_INDCPA_MSGBYTES must be equal to KYBER_N/8 bytes!" #endif for(i=0;i> j) & 1); // We cast the result of constant_time_select_w, which is a crypto_word_t, // to int16_t. The constants must be within the range of int16_t. OPENSSL_STATIC_ASSERT(((KYBER_Q+1)/2) <= INT16_MAX, value_exceeds_int16_max); r->coeffs[8*i+j] = (int16_t) constant_time_select_w(mask, 0, ((KYBER_Q+1)/2)); } } } /************************************************* * Name: poly_tomsg * * Description: Convert polynomial to 32-byte message * * Arguments: - uint8_t *msg: pointer to output message * - const poly *a: pointer to input polynomial **************************************************/ void poly_tomsg(uint8_t msg[KYBER_INDCPA_MSGBYTES], const poly *a) { unsigned int i,j; uint32_t t; for(i=0;icoeffs[8*i+j]; // t += ((int16_t)t >> 15) & KYBER_Q; // t = (((t << 1) + KYBER_Q/2)/KYBER_Q) & 1; t <<= 1; t += 1665; t *= 80635; t >>= 28; t &= 1; msg[i] |= t << j; } } } /************************************************* * Name: poly_getnoise_eta1 * * Description: Sample a polynomial deterministically from a seed and a nonce, * with output polynomial close to centered binomial distribution * with parameter KYBER_ETA1 * * Arguments: - poly *r: pointer to output polynomial * - const uint8_t *seed: pointer to input seed * (of length KYBER_SYMBYTES bytes) * - uint8_t nonce: one-byte input nonce **************************************************/ void poly_getnoise_eta1(ml_kem_params *params, poly *r, const uint8_t seed[KYBER_SYMBYTES], uint8_t nonce) { uint8_t buf[KYBER_ETA1_MAX*KYBER_N/4]; prf(buf, sizeof(buf), seed, nonce); poly_cbd_eta1(params, r, buf); } /************************************************* * Name: poly_getnoise_eta2 * * Description: Sample a polynomial deterministically from a seed and a nonce, * with output polynomial close to centered binomial distribution * with parameter KYBER_ETA2 * * Arguments: - poly *r: pointer to output polynomial * - const uint8_t *seed: pointer to input seed * (of length KYBER_SYMBYTES bytes) * - uint8_t nonce: one-byte input nonce **************************************************/ void poly_getnoise_eta2(poly *r, const uint8_t seed[KYBER_SYMBYTES], uint8_t nonce) { uint8_t buf[KYBER_ETA2*KYBER_N/4]; prf(buf, sizeof(buf), seed, nonce); poly_cbd_eta2(r, buf); } /************************************************* * Name: poly_ntt * * Description: Computes negacyclic number-theoretic transform (NTT) of * a polynomial in place; * inputs assumed to be in normal order, output in bitreversed order * * Arguments: - uint16_t *r: pointer to in/output polynomial **************************************************/ void poly_ntt(poly *r) { ntt(r->coeffs); poly_reduce(r); } /************************************************* * Name: poly_invntt_tomont * * Description: Computes inverse of negacyclic number-theoretic transform (NTT) * of a polynomial in place; * inputs assumed to be in bitreversed order, output in normal order * * Arguments: - uint16_t *a: pointer to in/output polynomial **************************************************/ void poly_invntt_tomont(poly *r) { invntt(r->coeffs); } /************************************************* * Name: poly_basemul_montgomery * * Description: Multiplication of two polynomials in NTT domain * * Arguments: - poly *r: pointer to output polynomial * - const poly *a: pointer to first input polynomial * - const poly *b: pointer to second input polynomial **************************************************/ void poly_basemul_montgomery(poly *r, const poly *a, const poly *b) { unsigned int i; for(i=0;icoeffs[4*i], &a->coeffs[4*i], &b->coeffs[4*i], zetas[64+i]); basemul(&r->coeffs[4*i+2], &a->coeffs[4*i+2], &b->coeffs[4*i+2], -zetas[64+i]); } } /************************************************* * Name: poly_tomont * * Description: Inplace conversion of all coefficients of a polynomial * from normal domain to Montgomery domain * * Arguments: - poly *r: pointer to input/output polynomial **************************************************/ void poly_tomont(poly *r) { unsigned int i; const int16_t f = (1ULL << 32) % KYBER_Q; for(i=0;icoeffs[i] = montgomery_reduce((int32_t)r->coeffs[i]*f); } /************************************************* * Name: poly_reduce * * Description: Applies Barrett reduction to all coefficients of a polynomial * for details of the Barrett reduction see comments in reduce.c * * Arguments: - poly *r: pointer to input/output polynomial **************************************************/ void poly_reduce(poly *r) { unsigned int i; for(i=0;icoeffs[i] = barrett_reduce(r->coeffs[i]); } /************************************************* * Name: poly_add * * Description: Add two polynomials; no modular reduction is performed * * Arguments: - poly *r: pointer to output polynomial * - const poly *a: pointer to first input polynomial * - const poly *b: pointer to second input polynomial **************************************************/ void poly_add(poly *r, const poly *a, const poly *b) { unsigned int i; for(i=0;icoeffs[i] = a->coeffs[i] + b->coeffs[i]; } /************************************************* * Name: poly_sub * * Description: Subtract two polynomials; no modular reduction is performed * * Arguments: - poly *r: pointer to output polynomial * - const poly *a: pointer to first input polynomial * - const poly *b: pointer to second input polynomial **************************************************/ void poly_sub(poly *r, const poly *a, const poly *b) { unsigned int i; for(i=0;icoeffs[i] = a->coeffs[i] - b->coeffs[i]; }