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- // SPDX-License-Identifier: GPL-2.0-or-later
- /*
- * Support for verifying ML-DSA signatures
- *
- * Copyright 2025 Google LLC
- */
- #include <crypto/mldsa.h>
- #include <crypto/sha3.h>
- #include <kunit/visibility.h>
- #include <linux/export.h>
- #include <linux/module.h>
- #include <linux/slab.h>
- #include <linux/string.h>
- #include <linux/unaligned.h>
- #include "fips-mldsa.h"
- #define Q 8380417 /* The prime q = 2^23 - 2^13 + 1 */
- #define QINV_MOD_2_32 58728449 /* Multiplicative inverse of q mod 2^32 */
- #define N 256 /* Number of components per ring element */
- #define D 13 /* Number of bits dropped from the public key vector t */
- #define RHO_LEN 32 /* Length of the public random seed in bytes */
- #define MAX_W1_ENCODED_LEN 192 /* Max encoded length of one element of w'_1 */
- /*
- * The zetas array in Montgomery form, i.e. with extra factor of 2^32.
- * Reference: FIPS 204 Section 7.5 "NTT and NTT^-1"
- * Generated by the following Python code:
- * q=8380417; [a%q - q*(a%q > q//2) for a in [1753**(int(f'{i:08b}'[::-1], 2)) << 32 for i in range(256)]]
- */
- static const s32 zetas_times_2_32[N] = {
- -4186625, 25847, -2608894, -518909, 237124, -777960, -876248,
- 466468, 1826347, 2353451, -359251, -2091905, 3119733, -2884855,
- 3111497, 2680103, 2725464, 1024112, -1079900, 3585928, -549488,
- -1119584, 2619752, -2108549, -2118186, -3859737, -1399561, -3277672,
- 1757237, -19422, 4010497, 280005, 2706023, 95776, 3077325,
- 3530437, -1661693, -3592148, -2537516, 3915439, -3861115, -3043716,
- 3574422, -2867647, 3539968, -300467, 2348700, -539299, -1699267,
- -1643818, 3505694, -3821735, 3507263, -2140649, -1600420, 3699596,
- 811944, 531354, 954230, 3881043, 3900724, -2556880, 2071892,
- -2797779, -3930395, -1528703, -3677745, -3041255, -1452451, 3475950,
- 2176455, -1585221, -1257611, 1939314, -4083598, -1000202, -3190144,
- -3157330, -3632928, 126922, 3412210, -983419, 2147896, 2715295,
- -2967645, -3693493, -411027, -2477047, -671102, -1228525, -22981,
- -1308169, -381987, 1349076, 1852771, -1430430, -3343383, 264944,
- 508951, 3097992, 44288, -1100098, 904516, 3958618, -3724342,
- -8578, 1653064, -3249728, 2389356, -210977, 759969, -1316856,
- 189548, -3553272, 3159746, -1851402, -2409325, -177440, 1315589,
- 1341330, 1285669, -1584928, -812732, -1439742, -3019102, -3881060,
- -3628969, 3839961, 2091667, 3407706, 2316500, 3817976, -3342478,
- 2244091, -2446433, -3562462, 266997, 2434439, -1235728, 3513181,
- -3520352, -3759364, -1197226, -3193378, 900702, 1859098, 909542,
- 819034, 495491, -1613174, -43260, -522500, -655327, -3122442,
- 2031748, 3207046, -3556995, -525098, -768622, -3595838, 342297,
- 286988, -2437823, 4108315, 3437287, -3342277, 1735879, 203044,
- 2842341, 2691481, -2590150, 1265009, 4055324, 1247620, 2486353,
- 1595974, -3767016, 1250494, 2635921, -3548272, -2994039, 1869119,
- 1903435, -1050970, -1333058, 1237275, -3318210, -1430225, -451100,
- 1312455, 3306115, -1962642, -1279661, 1917081, -2546312, -1374803,
- 1500165, 777191, 2235880, 3406031, -542412, -2831860, -1671176,
- -1846953, -2584293, -3724270, 594136, -3776993, -2013608, 2432395,
- 2454455, -164721, 1957272, 3369112, 185531, -1207385, -3183426,
- 162844, 1616392, 3014001, 810149, 1652634, -3694233, -1799107,
- -3038916, 3523897, 3866901, 269760, 2213111, -975884, 1717735,
- 472078, -426683, 1723600, -1803090, 1910376, -1667432, -1104333,
- -260646, -3833893, -2939036, -2235985, -420899, -2286327, 183443,
- -976891, 1612842, -3545687, -554416, 3919660, -48306, -1362209,
- 3937738, 1400424, -846154, 1976782
- };
- /* Reference: FIPS 204 Section 4 "Parameter Sets" */
- static const struct mldsa_parameter_set {
- u8 k; /* num rows in the matrix A */
- u8 l; /* num columns in the matrix A */
- u8 ctilde_len; /* length of commitment hash ctilde in bytes; lambda/4 */
- u8 omega; /* max num of 1's in the hint vector h */
- u8 tau; /* num of +-1's in challenge c */
- u8 beta; /* tau times eta */
- u16 pk_len; /* length of public keys in bytes */
- u16 sig_len; /* length of signatures in bytes */
- s32 gamma1; /* coefficient range of y */
- } mldsa_parameter_sets[] = {
- [MLDSA44] = {
- .k = 4,
- .l = 4,
- .ctilde_len = 32,
- .omega = 80,
- .tau = 39,
- .beta = 78,
- .pk_len = MLDSA44_PUBLIC_KEY_SIZE,
- .sig_len = MLDSA44_SIGNATURE_SIZE,
- .gamma1 = 1 << 17,
- },
- [MLDSA65] = {
- .k = 6,
- .l = 5,
- .ctilde_len = 48,
- .omega = 55,
- .tau = 49,
- .beta = 196,
- .pk_len = MLDSA65_PUBLIC_KEY_SIZE,
- .sig_len = MLDSA65_SIGNATURE_SIZE,
- .gamma1 = 1 << 19,
- },
- [MLDSA87] = {
- .k = 8,
- .l = 7,
- .ctilde_len = 64,
- .omega = 75,
- .tau = 60,
- .beta = 120,
- .pk_len = MLDSA87_PUBLIC_KEY_SIZE,
- .sig_len = MLDSA87_SIGNATURE_SIZE,
- .gamma1 = 1 << 19,
- },
- };
- /*
- * An element of the ring R_q (normal form) or the ring T_q (NTT form). It
- * consists of N integers mod q: either the polynomial coefficients of the R_q
- * element or the components of the T_q element. In either case, whether they
- * are fully reduced to [0, q - 1] varies in the different parts of the code.
- */
- struct mldsa_ring_elem {
- s32 x[N];
- };
- struct mldsa_verification_workspace {
- /* SHAKE context for computing c, mu, and ctildeprime */
- struct shake_ctx shake;
- /* The fields in this union are used in their order of declaration. */
- union {
- /* The hash of the public key */
- u8 tr[64];
- /* The message representative mu */
- u8 mu[64];
- /* Temporary space for rej_ntt_poly() */
- u8 block[SHAKE128_BLOCK_SIZE + 1];
- /* Encoded element of w'_1 */
- u8 w1_encoded[MAX_W1_ENCODED_LEN];
- /* The commitment hash. Real length is params->ctilde_len */
- u8 ctildeprime[64];
- };
- /* SHAKE context for generating elements of the matrix A */
- struct shake_ctx a_shake;
- /*
- * An element of the matrix A generated from the public seed, or an
- * element of the vector t_1 decoded from the public key and pre-scaled
- * by 2^d. Both are in NTT form. To reduce memory usage, we generate
- * or decode these elements only as needed.
- */
- union {
- struct mldsa_ring_elem a;
- struct mldsa_ring_elem t1_scaled;
- };
- /* The challenge c, generated from ctilde */
- struct mldsa_ring_elem c;
- /* A temporary element used during calculations */
- struct mldsa_ring_elem tmp;
- /* The following fields are variable-length: */
- /* The signer's response vector */
- struct mldsa_ring_elem z[/* l */];
- /* The signer's hint vector */
- /* u8 h[k * N]; */
- };
- /*
- * Compute a * b * 2^-32 mod q. a * b must be in the range [-2^31 * q, 2^31 * q
- * - 1] before reduction. The return value is in the range [-q + 1, q - 1].
- *
- * To reduce mod q efficiently, this uses Montgomery reduction with R=2^32.
- * That's where the factor of 2^-32 comes from. The caller must include a
- * factor of 2^32 at some point to compensate for that.
- *
- * To keep the input and output ranges very close to symmetric, this
- * specifically does a "signed" Montgomery reduction. That is, when computing
- * d = c * q^-1 mod 2^32, this chooses a representative in [S32_MIN, S32_MAX]
- * rather than [0, U32_MAX], i.e. s32 rather than u32. This matters in the
- * wider multiplication d * Q when d keeps its value via sign extension.
- *
- * Reference: FIPS 204 Appendix A "Montgomery Multiplication". But, it doesn't
- * explain it properly: it has an off-by-one error in the upper end of the input
- * range, it doesn't clarify that the signed version should be used, and it
- * gives an unnecessarily large output range. A better citation is perhaps the
- * Dilithium reference code, which functionally matches the below code and
- * merely has the (benign) off-by-one error in its documentation.
- */
- static inline s32 Zq_mult(s32 a, s32 b)
- {
- /* Compute the unreduced product c. */
- s64 c = (s64)a * b;
- /*
- * Compute d = c * q^-1 mod 2^32. Generate a signed result, as
- * explained above, but do the actual multiplication using an unsigned
- * type to avoid signed integer overflow which is undefined behavior.
- */
- s32 d = (u32)c * QINV_MOD_2_32;
- /*
- * Compute e = c - d * q. This makes the low 32 bits zero, since
- * c - (c * q^-1) * q mod 2^32
- * = c - c * (q^-1 * q) mod 2^32
- * = c - c * 1 mod 2^32
- * = c - c mod 2^32
- * = 0 mod 2^32
- */
- s64 e = c - (s64)d * Q;
- /* Finally, return e * 2^-32. */
- return e >> 32;
- }
- /*
- * Convert @w to its number-theoretically-transformed representation in-place.
- * Reference: FIPS 204 Algorithm 41, NTT
- *
- * To prevent intermediate overflows, all input coefficients must have absolute
- * value < q. All output components have absolute value < 9*q.
- */
- static void ntt(struct mldsa_ring_elem *w)
- {
- int m = 0; /* index in zetas_times_2_32 */
- for (int len = 128; len >= 1; len /= 2) {
- for (int start = 0; start < 256; start += 2 * len) {
- const s32 z = zetas_times_2_32[++m];
- for (int j = start; j < start + len; j++) {
- s32 t = Zq_mult(z, w->x[j + len]);
- w->x[j + len] = w->x[j] - t;
- w->x[j] += t;
- }
- }
- }
- }
- /*
- * Convert @w from its number-theoretically-transformed representation in-place.
- * Reference: FIPS 204 Algorithm 42, NTT^-1
- *
- * This also multiplies the coefficients by 2^32, undoing an extra factor of
- * 2^-32 introduced earlier, and reduces the coefficients to [0, q - 1].
- */
- static void invntt_and_mul_2_32(struct mldsa_ring_elem *w)
- {
- int m = 256; /* index in zetas_times_2_32 */
- /* Prevent intermediate overflows. */
- for (int j = 0; j < 256; j++)
- w->x[j] %= Q;
- for (int len = 1; len < 256; len *= 2) {
- for (int start = 0; start < 256; start += 2 * len) {
- const s32 z = -zetas_times_2_32[--m];
- for (int j = start; j < start + len; j++) {
- s32 t = w->x[j];
- w->x[j] = t + w->x[j + len];
- w->x[j + len] = Zq_mult(z, t - w->x[j + len]);
- }
- }
- }
- /*
- * Multiply by 2^32 * 256^-1. 2^32 cancels the factor of 2^-32 from
- * earlier Montgomery multiplications. 256^-1 is for NTT^-1. This
- * itself uses Montgomery multiplication, so *another* 2^32 is needed.
- * Thus the actual multiplicand is 2^32 * 2^32 * 256^-1 mod q = 41978.
- *
- * Finally, also reduce from [-q + 1, q - 1] to [0, q - 1].
- */
- for (int j = 0; j < 256; j++) {
- w->x[j] = Zq_mult(w->x[j], 41978);
- w->x[j] += (w->x[j] >> 31) & Q;
- }
- }
- /*
- * Decode an element of t_1, i.e. the high d bits of t = A*s_1 + s_2.
- * Reference: FIPS 204 Algorithm 23, pkDecode.
- * Also multiply it by 2^d and convert it to NTT form.
- */
- static const u8 *decode_t1_elem(struct mldsa_ring_elem *out,
- const u8 *t1_encoded)
- {
- for (int j = 0; j < N; j += 4, t1_encoded += 5) {
- u32 v = get_unaligned_le32(t1_encoded);
- out->x[j + 0] = ((v >> 0) & 0x3ff) << D;
- out->x[j + 1] = ((v >> 10) & 0x3ff) << D;
- out->x[j + 2] = ((v >> 20) & 0x3ff) << D;
- out->x[j + 3] = ((v >> 30) | (t1_encoded[4] << 2)) << D;
- static_assert(0x3ff << D < Q); /* All coefficients < q. */
- }
- ntt(out);
- return t1_encoded; /* Return updated pointer. */
- }
- /*
- * Decode the signer's response vector 'z' from the signature.
- * Reference: FIPS 204 Algorithm 27, sigDecode.
- *
- * This also validates that the coefficients of z are in range, corresponding
- * the infinity norm check at the end of Algorithm 8, ML-DSA.Verify_internal.
- *
- * Finally, this also converts z to NTT form.
- */
- static bool decode_z(struct mldsa_ring_elem z[/* l */], int l, s32 gamma1,
- int beta, const u8 **sig_ptr)
- {
- const u8 *sig = *sig_ptr;
- for (int i = 0; i < l; i++) {
- if (l == 4) { /* ML-DSA-44? */
- /* 18-bit coefficients: decode 4 from 9 bytes. */
- for (int j = 0; j < N; j += 4, sig += 9) {
- u64 v = get_unaligned_le64(sig);
- z[i].x[j + 0] = (v >> 0) & 0x3ffff;
- z[i].x[j + 1] = (v >> 18) & 0x3ffff;
- z[i].x[j + 2] = (v >> 36) & 0x3ffff;
- z[i].x[j + 3] = (v >> 54) | (sig[8] << 10);
- }
- } else {
- /* 20-bit coefficients: decode 4 from 10 bytes. */
- for (int j = 0; j < N; j += 4, sig += 10) {
- u64 v = get_unaligned_le64(sig);
- z[i].x[j + 0] = (v >> 0) & 0xfffff;
- z[i].x[j + 1] = (v >> 20) & 0xfffff;
- z[i].x[j + 2] = (v >> 40) & 0xfffff;
- z[i].x[j + 3] =
- (v >> 60) |
- (get_unaligned_le16(&sig[8]) << 4);
- }
- }
- for (int j = 0; j < N; j++) {
- z[i].x[j] = gamma1 - z[i].x[j];
- if (z[i].x[j] <= -(gamma1 - beta) ||
- z[i].x[j] >= gamma1 - beta)
- return false;
- }
- ntt(&z[i]);
- }
- *sig_ptr = sig; /* Return updated pointer. */
- return true;
- }
- /*
- * Decode the signer's hint vector 'h' from the signature.
- * Reference: FIPS 204 Algorithm 21, HintBitUnpack
- *
- * Note that there are several ways in which the hint vector can be malformed.
- */
- static bool decode_hint_vector(u8 h[/* k * N */], int k, int omega, const u8 *y)
- {
- int index = 0;
- memset(h, 0, k * N);
- for (int i = 0; i < k; i++) {
- int count = y[omega + i]; /* num 1's in elems 0 through i */
- int prev = -1;
- /* Cumulative count mustn't decrease or exceed omega. */
- if (count < index || count > omega)
- return false;
- for (; index < count; index++) {
- if (prev >= y[index]) /* Coefficients out of order? */
- return false;
- prev = y[index];
- h[i * N + y[index]] = 1;
- }
- }
- return mem_is_zero(&y[index], omega - index);
- }
- /*
- * Expand @seed into an element of R_q @c with coefficients in {-1, 0, 1},
- * exactly @tau of them nonzero. Reference: FIPS 204 Algorithm 29, SampleInBall
- */
- static void sample_in_ball(struct mldsa_ring_elem *c, const u8 *seed,
- size_t seed_len, int tau, struct shake_ctx *shake)
- {
- u64 signs;
- u8 j;
- shake256_init(shake);
- shake_update(shake, seed, seed_len);
- shake_squeeze(shake, (u8 *)&signs, sizeof(signs));
- le64_to_cpus(&signs);
- *c = (struct mldsa_ring_elem){};
- for (int i = N - tau; i < N; i++, signs >>= 1) {
- do {
- shake_squeeze(shake, &j, 1);
- } while (j > i);
- c->x[i] = c->x[j];
- c->x[j] = 1 - 2 * (s32)(signs & 1);
- }
- }
- /*
- * Expand the public seed @rho and @row_and_column into an element of T_q @out.
- * Reference: FIPS 204 Algorithm 30, RejNTTPoly
- *
- * @shake and @block are temporary space used by the expansion. @block has
- * space for one SHAKE128 block, plus an extra byte to allow reading a u32 from
- * the final 3-byte group without reading out-of-bounds.
- */
- static void rej_ntt_poly(struct mldsa_ring_elem *out, const u8 rho[RHO_LEN],
- __le16 row_and_column, struct shake_ctx *shake,
- u8 block[SHAKE128_BLOCK_SIZE + 1])
- {
- shake128_init(shake);
- shake_update(shake, rho, RHO_LEN);
- shake_update(shake, (u8 *)&row_and_column, sizeof(row_and_column));
- for (int i = 0; i < N;) {
- shake_squeeze(shake, block, SHAKE128_BLOCK_SIZE);
- block[SHAKE128_BLOCK_SIZE] = 0; /* for KMSAN */
- static_assert(SHAKE128_BLOCK_SIZE % 3 == 0);
- for (int j = 0; j < SHAKE128_BLOCK_SIZE && i < N; j += 3) {
- u32 x = get_unaligned_le32(&block[j]) & 0x7fffff;
- if (x < Q) /* Ignore values >= q. */
- out->x[i++] = x;
- }
- }
- }
- /*
- * Return the HighBits of r adjusted according to hint h
- * Reference: FIPS 204 Algorithm 40, UseHint
- *
- * This is needed because of the public key compression in ML-DSA.
- *
- * h is either 0 or 1, r is in [0, q - 1], and gamma2 is either (q - 1) / 88 or
- * (q - 1) / 32. Except when invoked via the unit test interface, gamma2 is a
- * compile-time constant, so compilers will optimize the code accordingly.
- */
- static __always_inline s32 use_hint(u8 h, s32 r, const s32 gamma2)
- {
- const s32 m = (Q - 1) / (2 * gamma2); /* 44 or 16, compile-time const */
- s32 r1;
- /*
- * Handle the special case where r - (r mod+- (2 * gamma2)) == q - 1,
- * i.e. r >= q - gamma2. This is also exactly where the computation of
- * r1 below would produce 'm' and would need a correction.
- */
- if (r >= Q - gamma2)
- return h == 0 ? 0 : m - 1;
- /*
- * Compute the (non-hint-adjusted) HighBits r1 as:
- *
- * r1 = (r - (r mod+- (2 * gamma2))) / (2 * gamma2)
- * = floor((r + gamma2 - 1) / (2 * gamma2))
- *
- * Note that when '2 * gamma2' is a compile-time constant, compilers
- * optimize the division to a reciprocal multiplication and shift.
- */
- r1 = (u32)(r + gamma2 - 1) / (2 * gamma2);
- /*
- * Return the HighBits r1:
- * + 0 if the hint is 0;
- * + 1 (mod m) if the hint is 1 and the LowBits are positive;
- * - 1 (mod m) if the hint is 1 and the LowBits are negative or 0.
- *
- * r1 is in (and remains in) [0, m - 1]. Note that when 'm' is a
- * compile-time constant, compilers optimize the '% m' accordingly.
- */
- if (h == 0)
- return r1;
- if (r > r1 * (2 * gamma2))
- return (u32)(r1 + 1) % m;
- return (u32)(r1 + m - 1) % m;
- }
- static __always_inline void use_hint_elem(struct mldsa_ring_elem *w,
- const u8 h[N], const s32 gamma2)
- {
- for (int j = 0; j < N; j++)
- w->x[j] = use_hint(h[j], w->x[j], gamma2);
- }
- #if IS_ENABLED(CONFIG_CRYPTO_LIB_MLDSA_KUNIT_TEST)
- /* Allow the __always_inline function use_hint() to be unit-tested. */
- s32 mldsa_use_hint(u8 h, s32 r, s32 gamma2)
- {
- return use_hint(h, r, gamma2);
- }
- EXPORT_SYMBOL_IF_KUNIT(mldsa_use_hint);
- #endif
- /*
- * Encode one element of the commitment vector w'_1 into a byte string.
- * Reference: FIPS 204 Algorithm 28, w1Encode.
- * Return the number of bytes used: 192 for ML-DSA-44 and 128 for the others.
- */
- static size_t encode_w1(u8 out[MAX_W1_ENCODED_LEN],
- const struct mldsa_ring_elem *w1, int k)
- {
- size_t pos = 0;
- static_assert(N * 6 / 8 == MAX_W1_ENCODED_LEN);
- if (k == 4) { /* ML-DSA-44? */
- /* 6 bits per coefficient. Pack 4 at a time. */
- for (int j = 0; j < N; j += 4) {
- u32 v = (w1->x[j + 0] << 0) | (w1->x[j + 1] << 6) |
- (w1->x[j + 2] << 12) | (w1->x[j + 3] << 18);
- out[pos++] = v >> 0;
- out[pos++] = v >> 8;
- out[pos++] = v >> 16;
- }
- } else {
- /* 4 bits per coefficient. Pack 2 at a time. */
- for (int j = 0; j < N; j += 2)
- out[pos++] = w1->x[j] | (w1->x[j + 1] << 4);
- }
- return pos;
- }
- int mldsa_verify(enum mldsa_alg alg, const u8 *sig, size_t sig_len,
- const u8 *msg, size_t msg_len, const u8 *pk, size_t pk_len)
- {
- const struct mldsa_parameter_set *params = &mldsa_parameter_sets[alg];
- const int k = params->k, l = params->l;
- /* For now this just does pure ML-DSA with an empty context string. */
- static const u8 msg_prefix[2] = { /* dom_sep= */ 0, /* ctx_len= */ 0 };
- const u8 *ctilde; /* The signer's commitment hash */
- const u8 *t1_encoded = &pk[RHO_LEN]; /* Next encoded element of t_1 */
- u8 *h; /* The signer's hint vector, length k * N */
- size_t w1_enc_len;
- /* Validate the public key and signature lengths. */
- if (pk_len != params->pk_len || sig_len != params->sig_len)
- return -EBADMSG;
- /*
- * Allocate the workspace, including variable-length fields. Its size
- * depends only on the ML-DSA parameter set, not the other inputs.
- *
- * For freeing it, use kfree_sensitive() rather than kfree(). This is
- * mainly to comply with FIPS 204 Section 3.6.3 "Intermediate Values".
- * In reality it's a bit gratuitous, as this is a public key operation.
- */
- struct mldsa_verification_workspace *ws __free(kfree_sensitive) =
- kmalloc(sizeof(*ws) + (l * sizeof(ws->z[0])) + (k * N),
- GFP_KERNEL);
- if (!ws)
- return -ENOMEM;
- h = (u8 *)&ws->z[l];
- /* Decode the signature. Reference: FIPS 204 Algorithm 27, sigDecode */
- ctilde = sig;
- sig += params->ctilde_len;
- if (!decode_z(ws->z, l, params->gamma1, params->beta, &sig))
- return -EBADMSG;
- if (!decode_hint_vector(h, k, params->omega, sig))
- return -EBADMSG;
- /* Recreate the challenge c from the signer's commitment hash. */
- sample_in_ball(&ws->c, ctilde, params->ctilde_len, params->tau,
- &ws->shake);
- ntt(&ws->c);
- /* Compute the message representative mu. */
- shake256(pk, pk_len, ws->tr, sizeof(ws->tr));
- shake256_init(&ws->shake);
- shake_update(&ws->shake, ws->tr, sizeof(ws->tr));
- shake_update(&ws->shake, msg_prefix, sizeof(msg_prefix));
- shake_update(&ws->shake, msg, msg_len);
- shake_squeeze(&ws->shake, ws->mu, sizeof(ws->mu));
- /* Start computing ctildeprime = H(mu || w1Encode(w'_1)). */
- shake256_init(&ws->shake);
- shake_update(&ws->shake, ws->mu, sizeof(ws->mu));
- /*
- * Compute the commitment w'_1 from A, z, c, t_1, and h.
- *
- * The computation is the same for each of the k rows. Just do each row
- * before moving on to the next, resulting in only one loop over k.
- */
- for (int i = 0; i < k; i++) {
- /*
- * tmp = NTT(A) * NTT(z) * 2^-32
- * To reduce memory use, generate each element of NTT(A)
- * on-demand. Note that each element is used only once.
- */
- ws->tmp = (struct mldsa_ring_elem){};
- for (int j = 0; j < l; j++) {
- rej_ntt_poly(&ws->a, pk /* rho is first field of pk */,
- cpu_to_le16((i << 8) | j), &ws->a_shake,
- ws->block);
- for (int n = 0; n < N; n++)
- ws->tmp.x[n] +=
- Zq_mult(ws->a.x[n], ws->z[j].x[n]);
- }
- /* All components of tmp now have abs value < l*q. */
- /* Decode the next element of t_1. */
- t1_encoded = decode_t1_elem(&ws->t1_scaled, t1_encoded);
- /*
- * tmp -= NTT(c) * NTT(t_1 * 2^d) * 2^-32
- *
- * Taking a conservative bound for the output of ntt(), the
- * multiplicands can have absolute value up to 9*q. That
- * corresponds to a product with absolute value 81*q^2. That is
- * within the limits of Zq_mult() which needs < ~256*q^2.
- */
- for (int j = 0; j < N; j++)
- ws->tmp.x[j] -= Zq_mult(ws->c.x[j], ws->t1_scaled.x[j]);
- /* All components of tmp now have abs value < (l+1)*q. */
- /* tmp = w'_Approx = NTT^-1(tmp) * 2^32 */
- invntt_and_mul_2_32(&ws->tmp);
- /* All coefficients of tmp are now in [0, q - 1]. */
- /*
- * tmp = w'_1 = UseHint(h, w'_Approx)
- * For efficiency, set gamma2 to a compile-time constant.
- */
- if (k == 4)
- use_hint_elem(&ws->tmp, &h[i * N], (Q - 1) / 88);
- else
- use_hint_elem(&ws->tmp, &h[i * N], (Q - 1) / 32);
- /* Encode and hash the next element of w'_1. */
- w1_enc_len = encode_w1(ws->w1_encoded, &ws->tmp, k);
- shake_update(&ws->shake, ws->w1_encoded, w1_enc_len);
- }
- /* Finish computing ctildeprime. */
- shake_squeeze(&ws->shake, ws->ctildeprime, params->ctilde_len);
- /* Verify that ctilde == ctildeprime. */
- if (memcmp(ws->ctildeprime, ctilde, params->ctilde_len) != 0)
- return -EKEYREJECTED;
- /* ||z||_infinity < gamma1 - beta was already checked in decode_z(). */
- return 0;
- }
- EXPORT_SYMBOL_GPL(mldsa_verify);
- #ifdef CONFIG_CRYPTO_FIPS
- static int __init mldsa_mod_init(void)
- {
- if (fips_enabled) {
- /*
- * FIPS cryptographic algorithm self-test. As per the FIPS
- * Implementation Guidance, testing any ML-DSA parameter set
- * satisfies the test requirement for all of them, and only a
- * positive test is required.
- */
- int err = mldsa_verify(MLDSA65, fips_test_mldsa65_signature,
- sizeof(fips_test_mldsa65_signature),
- fips_test_mldsa65_message,
- sizeof(fips_test_mldsa65_message),
- fips_test_mldsa65_public_key,
- sizeof(fips_test_mldsa65_public_key));
- if (err)
- panic("mldsa: FIPS self-test failed; err=%pe\n",
- ERR_PTR(err));
- }
- return 0;
- }
- subsys_initcall(mldsa_mod_init);
- static void __exit mldsa_mod_exit(void)
- {
- }
- module_exit(mldsa_mod_exit);
- #endif /* CONFIG_CRYPTO_FIPS */
- MODULE_DESCRIPTION("ML-DSA signature verification");
- MODULE_LICENSE("GPL");
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