247 lines
6.1 KiB
C
247 lines
6.1 KiB
C
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// Constantine
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// Copyright (c) 2018-2019 Status Research & Development GmbH
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// Copyright (c) 2020-Present Mamy André-Ratsimbazafy
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// Licensed and distributed under either of
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// * MIT license (license terms in the root directory or at http://opensource.org/licenses/MIT).
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// * Apache v2 license (license terms in the root directory or at http://www.apache.org/licenses/LICENSE-2.0).
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// at your option. This file may not be copied, modified, or distributed except according to those terms.
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#include <assert.h>
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#include <gmp.h>
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#include <constantine_bls12_381.h>
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#include <stdio.h>
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#include <stdlib.h>
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typedef unsigned char byte;
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// https://gmplib.org/manual/Integer-Import-and-Export.html
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const int GMP_WordLittleEndian = -1;
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const int GMP_WordNativeEndian = 0;
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const int GMP_WordBigEndian = 1;
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const int GMP_MostSignificantWordFirst = 1;
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const int GMP_LeastSignificantWordFirst = -1;
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#define Curve "BLS12_381"
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#define BitLength 381
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#define ByteLength ((BitLength + 7) / 8)
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#define Modulus "0x1a0111ea397fe69a4b1ba7b6434bacd764774b84f38512bf6730d2a0f6b0f6241eabfffeb153ffffb9feffffffffaaab"
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#define Iter 24
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void prologue(
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gmp_randstate_t gmp_rng,
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mpz_ptr a, mpz_ptr b,
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mpz_ptr p,
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bls12381_fp* a_ctt, bls12381_fp* b_ctt,
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byte a_buf[ByteLength], byte b_buf[ByteLength]) {
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// Generate random value in the range 0 ..< 2^(bits-1)
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mpz_urandomb(a, gmp_rng, BitLength);
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mpz_urandomb(b, gmp_rng, BitLength);
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// Set modulus to curve modulus
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mpz_set_str(p, Modulus, 0);
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// GMP -> Constantine
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size_t aW, bW;
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mpz_export(a_buf, &aW, GMP_MostSignificantWordFirst, 1, GMP_WordNativeEndian, 0, a);
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mpz_export(b_buf, &bW, GMP_MostSignificantWordFirst, 1, GMP_WordNativeEndian, 0, b);
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assert(ByteLength >= aW);
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assert(ByteLength >= bW);
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ctt_bls12381_fp_unmarshalBE(a_ctt, a_buf, aW);
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ctt_bls12381_fp_unmarshalBE(b_ctt, b_buf, bW);
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}
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void dump_hex(byte a[ByteLength]){
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printf("0x");
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for (int i = 0; i < ByteLength; ++i){
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printf("%.02x", a[i]);
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}
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}
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void epilogue(
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mpz_ptr r, mpz_ptr a, mpz_ptr b,
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bls12381_fp* r_ctt, bls12381_fp* a_ctt, bls12381_fp* b_ctt,
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char* operation) {
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byte r_raw_gmp[ByteLength];
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byte r_raw_ctt[ByteLength];
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// GMP -> Raw
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size_t rW; // number of words written
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mpz_export(r_raw_gmp, &rW, GMP_MostSignificantWordFirst, 1, GMP_WordNativeEndian, 0, r);
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// Constantine -> Raw
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ctt_bls12381_fp_marshalBE(r_raw_ctt, ByteLength, r_ctt);
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// Check
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for (int g = 0, c = ByteLength-rW; g < rW; g+=1, c+=1) {
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if (r_raw_gmp[g] != r_raw_ctt[c]) {
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// reexport for debugging
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byte a_buf[ByteLength], b_buf[ByteLength];
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size_t aW, bW;
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mpz_export(a_buf, &aW, GMP_MostSignificantWordFirst, 1, GMP_WordNativeEndian, 0, a);
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mpz_export(b_buf, &bW, GMP_MostSignificantWordFirst, 1, GMP_WordNativeEndian, 0, b);
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printf("\nModular %s on curve %s with operands", operation, Curve);
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printf("\n a: "); dump_hex(a_buf);
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printf("\n b: "); dump_hex(b_buf);
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printf("\nfailed:");
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printf("\n GMP: "); dump_hex(r_raw_gmp);
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printf("\n Constantine: "); dump_hex(r_raw_ctt);
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printf("\n(Note that GMP aligns bytes left while constantine aligns bytes right)\n");
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exit(1);
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}
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}
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printf(".");
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}
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int main(){
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// Initialize the runtime. For Constantine, it populates CPU runtime detection dispatch.
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ctt_bls12381_init_NimMain();
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gmp_randstate_t gmpRng;
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gmp_randinit_mt(gmpRng);
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// The GMP seed varies between run so that
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// test coverage increases as the library gets tested.
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// This requires to dump the seed in the console or the function inputs
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// to be able to reproduce a bug
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int seed = 0xDEADBEEF;
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printf("GMP seed: 0x%.04x\n", seed);
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gmp_randseed_ui(gmpRng, seed);
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mpz_t a, b, p, r;
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mpz_init(a);
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mpz_init(b);
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mpz_init(p);
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mpz_init(r);
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bls12381_fp a_ctt, b_ctt, r_ctt;
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byte a_buf[ByteLength], b_buf[ByteLength];
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for (int i = 0; i < Iter; ++i){
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prologue(
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gmpRng,
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a, b, p,
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&a_ctt, &b_ctt,
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a_buf, b_buf
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);
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mpz_neg(r, a);
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mpz_mod(r, r, p);
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ctt_bls12381_fp_neg(&r_ctt, &a_ctt);
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epilogue(
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r, a, b,
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&r_ctt, &a_ctt, &b_ctt,
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"negation"
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);
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}
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printf(" SUCCESS negation\n");
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for (int i = 0; i < Iter; ++i){
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prologue(
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gmpRng,
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a, b, p,
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&a_ctt, &b_ctt,
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a_buf, b_buf
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);
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mpz_add(r, a, b);
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mpz_mod(r, r, p);
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ctt_bls12381_fp_sum(&r_ctt, &a_ctt, &b_ctt);
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epilogue(
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r, a, b,
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&r_ctt, &a_ctt, &b_ctt,
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"addition"
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);
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}
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printf(" SUCCESS addition\n");
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for (int i = 0; i < Iter; ++i){
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prologue(
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gmpRng,
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a, b, p,
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&a_ctt, &b_ctt,
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a_buf, b_buf
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);
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mpz_mul(r, a, b);
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mpz_mod(r, r, p);
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ctt_bls12381_fp_prod(&r_ctt, &a_ctt, &b_ctt);
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epilogue(
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r, a, b,
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&r_ctt, &a_ctt, &b_ctt,
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"multiplication"
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);
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}
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printf(" SUCCESS multiplication\n");
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for (int i = 0; i < Iter; ++i){
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prologue(
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gmpRng,
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a, b, p,
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&a_ctt, &b_ctt,
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a_buf, b_buf
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);
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mpz_invert(r, a, p);
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ctt_bls12381_fp_inv(&r_ctt, &a_ctt);
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epilogue(
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r, a, b,
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&r_ctt, &a_ctt, &b_ctt,
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"inversion"
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);
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}
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printf(" SUCCESS inversion\n");
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for (int i = 0; i < Iter; ++i){
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prologue(
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gmpRng,
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a, b, p,
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&a_ctt, &b_ctt,
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a_buf, b_buf
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);
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int is_square_gmp = mpz_legendre(a, p) == -1 ? 0:1;
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int is_square_ctt = ctt_bls12381_fp_is_square(&a_ctt);
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assert(is_square_gmp == is_square_ctt);
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}
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printf(" SUCCESS Legendre symbol / is_square\n");
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// TODO: THere are a "positive" and "negative" square roots
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// for (int i = 0; i < Iter; ++i){
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// prologue(
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// gmpRng,
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// a, b, p,
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// &a_ctt, &b_ctt,
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// a_buf, b_buf
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// );
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// if (mpz_congruent_ui_p(p, 3, 4)) {
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// // a^((p+1)/4) (mod p)
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// mpz_add_ui(b, p, 1);
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// mpz_tdiv_q_2exp(b, b, 2);
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// mpz_powm(r, a, b, p);
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// } else {
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// assert(0);
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// }
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// ctt_bls12381_fp_prod(&r_ctt, &a_ctt, &b_ctt);
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// epilogue(
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// r, a, b,
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// &r_ctt, &a_ctt, &b_ctt,
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// "square root"
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// );
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// }
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// printf(" SUCCESS square root\n");
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return 0;
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}
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