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https://github.com/henrydcase/pqc.git
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700 lines
20 KiB
C
700 lines
20 KiB
C
/*
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* FFT code.
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*
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* ==========================(LICENSE BEGIN)============================
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*
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* Copyright (c) 2017-2019 Falcon Project
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*
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* Permission is hereby granted, free of charge, to any person obtaining
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* a copy of this software and associated documentation files (the
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* "Software"), to deal in the Software without restriction, including
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* without limitation the rights to use, copy, modify, merge, publish,
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* distribute, sublicense, and/or sell copies of the Software, and to
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* permit persons to whom the Software is furnished to do so, subject to
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* the following conditions:
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*
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* The above copyright notice and this permission notice shall be
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* included in all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
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* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
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* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
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* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
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* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
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* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
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*
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* ===========================(LICENSE END)=============================
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*
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* @author Thomas Pornin <thomas.pornin@nccgroup.com>
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*/
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#include "inner.h"
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/*
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* Rules for complex number macros:
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* --------------------------------
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*
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* Operand order is: destination, source1, source2...
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*
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* Each operand is a real and an imaginary part.
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*
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* All overlaps are allowed.
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*/
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/*
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* Addition of two complex numbers (d = a + b).
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*/
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#define FPC_ADD(d_re, d_im, a_re, a_im, b_re, b_im) do { \
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fpr fpct_re, fpct_im; \
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fpct_re = fpr_add(a_re, b_re); \
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fpct_im = fpr_add(a_im, b_im); \
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(d_re) = fpct_re; \
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(d_im) = fpct_im; \
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} while (0)
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/*
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* Subtraction of two complex numbers (d = a - b).
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*/
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#define FPC_SUB(d_re, d_im, a_re, a_im, b_re, b_im) do { \
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fpr fpct_re, fpct_im; \
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fpct_re = fpr_sub(a_re, b_re); \
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fpct_im = fpr_sub(a_im, b_im); \
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(d_re) = fpct_re; \
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(d_im) = fpct_im; \
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} while (0)
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/*
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* Multplication of two complex numbers (d = a * b).
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*/
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#define FPC_MUL(d_re, d_im, a_re, a_im, b_re, b_im) do { \
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fpr fpct_a_re, fpct_a_im; \
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fpr fpct_b_re, fpct_b_im; \
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fpr fpct_d_re, fpct_d_im; \
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fpct_a_re = (a_re); \
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fpct_a_im = (a_im); \
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fpct_b_re = (b_re); \
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fpct_b_im = (b_im); \
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fpct_d_re = fpr_sub( \
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fpr_mul(fpct_a_re, fpct_b_re), \
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fpr_mul(fpct_a_im, fpct_b_im)); \
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fpct_d_im = fpr_add( \
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fpr_mul(fpct_a_re, fpct_b_im), \
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fpr_mul(fpct_a_im, fpct_b_re)); \
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(d_re) = fpct_d_re; \
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(d_im) = fpct_d_im; \
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} while (0)
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/*
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* Squaring of a complex number (d = a * a).
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*/
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#define FPC_SQR(d_re, d_im, a_re, a_im) do { \
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fpr fpct_a_re, fpct_a_im; \
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fpr fpct_d_re, fpct_d_im; \
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fpct_a_re = (a_re); \
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fpct_a_im = (a_im); \
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fpct_d_re = fpr_sub(fpr_sqr(fpct_a_re), fpr_sqr(fpct_a_im)); \
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fpct_d_im = fpr_double(fpr_mul(fpct_a_re, fpct_a_im)); \
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(d_re) = fpct_d_re; \
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(d_im) = fpct_d_im; \
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} while (0)
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/*
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* Inversion of a complex number (d = 1 / a).
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*/
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#define FPC_INV(d_re, d_im, a_re, a_im) do { \
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fpr fpct_a_re, fpct_a_im; \
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fpr fpct_d_re, fpct_d_im; \
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fpr fpct_m; \
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fpct_a_re = (a_re); \
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fpct_a_im = (a_im); \
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fpct_m = fpr_add(fpr_sqr(fpct_a_re), fpr_sqr(fpct_a_im)); \
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fpct_m = fpr_inv(fpct_m); \
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fpct_d_re = fpr_mul(fpct_a_re, fpct_m); \
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fpct_d_im = fpr_mul(fpr_neg(fpct_a_im), fpct_m); \
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(d_re) = fpct_d_re; \
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(d_im) = fpct_d_im; \
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} while (0)
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/*
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* Division of complex numbers (d = a / b).
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*/
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#define FPC_DIV(d_re, d_im, a_re, a_im, b_re, b_im) do { \
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fpr fpct_a_re, fpct_a_im; \
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fpr fpct_b_re, fpct_b_im; \
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fpr fpct_d_re, fpct_d_im; \
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fpr fpct_m; \
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fpct_a_re = (a_re); \
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fpct_a_im = (a_im); \
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fpct_b_re = (b_re); \
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fpct_b_im = (b_im); \
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fpct_m = fpr_add(fpr_sqr(fpct_b_re), fpr_sqr(fpct_b_im)); \
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fpct_m = fpr_inv(fpct_m); \
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fpct_b_re = fpr_mul(fpct_b_re, fpct_m); \
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fpct_b_im = fpr_mul(fpr_neg(fpct_b_im), fpct_m); \
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fpct_d_re = fpr_sub( \
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fpr_mul(fpct_a_re, fpct_b_re), \
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fpr_mul(fpct_a_im, fpct_b_im)); \
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fpct_d_im = fpr_add( \
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fpr_mul(fpct_a_re, fpct_b_im), \
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fpr_mul(fpct_a_im, fpct_b_re)); \
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(d_re) = fpct_d_re; \
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(d_im) = fpct_d_im; \
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} while (0)
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/*
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* Let w = exp(i*pi/N); w is a primitive 2N-th root of 1. We define the
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* values w_j = w^(2j+1) for all j from 0 to N-1: these are the roots
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* of X^N+1 in the field of complex numbers. A crucial property is that
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* w_{N-1-j} = conj(w_j) = 1/w_j for all j.
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*
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* FFT representation of a polynomial f (taken modulo X^N+1) is the
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* set of values f(w_j). Since f is real, conj(f(w_j)) = f(conj(w_j)),
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* thus f(w_{N-1-j}) = conj(f(w_j)). We thus store only half the values,
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* for j = 0 to N/2-1; the other half can be recomputed easily when (if)
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* needed. A consequence is that FFT representation has the same size
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* as normal representation: N/2 complex numbers use N real numbers (each
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* complex number is the combination of a real and an imaginary part).
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*
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* We use a specific ordering which makes computations easier. Let rev()
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* be the bit-reversal function over log(N) bits. For j in 0..N/2-1, we
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* store the real and imaginary parts of f(w_j) in slots:
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*
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* Re(f(w_j)) -> slot rev(j)/2
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* Im(f(w_j)) -> slot rev(j)/2+N/2
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*
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* (Note that rev(j) is even for j < N/2.)
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*/
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_FFT(fpr *f, unsigned logn) {
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/*
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* FFT algorithm in bit-reversal order uses the following
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* iterative algorithm:
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*
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* t = N
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* for m = 1; m < N; m *= 2:
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* ht = t/2
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* for i1 = 0; i1 < m; i1 ++:
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* j1 = i1 * t
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* s = GM[m + i1]
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* for j = j1; j < (j1 + ht); j ++:
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* x = f[j]
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* y = s * f[j + ht]
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* f[j] = x + y
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* f[j + ht] = x - y
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* t = ht
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*
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* GM[k] contains w^rev(k) for primitive root w = exp(i*pi/N).
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*
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* In the description above, f[] is supposed to contain complex
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* numbers. In our in-memory representation, the real and
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* imaginary parts of f[k] are in array slots k and k+N/2.
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*
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* We only keep the first half of the complex numbers. We can
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* see that after the first iteration, the first and second halves
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* of the array of complex numbers have separate lives, so we
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* simply ignore the second part.
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*/
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unsigned u;
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size_t t, n, hn, m;
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/*
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* First iteration: compute f[j] + i * f[j+N/2] for all j < N/2
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* (because GM[1] = w^rev(1) = w^(N/2) = i).
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* In our chosen representation, this is a no-op: everything is
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* already where it should be.
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*/
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/*
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* Subsequent iterations are truncated to use only the first
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* half of values.
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*/
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n = (size_t)1 << logn;
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hn = n >> 1;
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t = hn;
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for (u = 1, m = 2; u < logn; u ++, m <<= 1) {
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size_t ht, hm, i1, j1;
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ht = t >> 1;
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hm = m >> 1;
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for (i1 = 0, j1 = 0; i1 < hm; i1 ++, j1 += t) {
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size_t j, j2;
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j2 = j1 + ht;
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fpr s_re, s_im;
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s_re = fpr_gm_tab[((m + i1) << 1) + 0];
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s_im = fpr_gm_tab[((m + i1) << 1) + 1];
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for (j = j1; j < j2; j ++) {
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fpr x_re, x_im, y_re, y_im;
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x_re = f[j];
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x_im = f[j + hn];
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y_re = f[j + ht];
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y_im = f[j + ht + hn];
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FPC_MUL(y_re, y_im, y_re, y_im, s_re, s_im);
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FPC_ADD(f[j], f[j + hn],
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x_re, x_im, y_re, y_im);
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FPC_SUB(f[j + ht], f[j + ht + hn],
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x_re, x_im, y_re, y_im);
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}
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}
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t = ht;
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_iFFT(fpr *f, unsigned logn) {
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/*
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* Inverse FFT algorithm in bit-reversal order uses the following
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* iterative algorithm:
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*
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* t = 1
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* for m = N; m > 1; m /= 2:
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* hm = m/2
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* dt = t*2
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* for i1 = 0; i1 < hm; i1 ++:
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* j1 = i1 * dt
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* s = iGM[hm + i1]
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* for j = j1; j < (j1 + t); j ++:
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* x = f[j]
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* y = f[j + t]
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* f[j] = x + y
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* f[j + t] = s * (x - y)
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* t = dt
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* for i1 = 0; i1 < N; i1 ++:
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* f[i1] = f[i1] / N
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*
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* iGM[k] contains (1/w)^rev(k) for primitive root w = exp(i*pi/N)
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* (actually, iGM[k] = 1/GM[k] = conj(GM[k])).
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*
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* In the main loop (not counting the final division loop), in
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* all iterations except the last, the first and second half of f[]
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* (as an array of complex numbers) are separate. In our chosen
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* representation, we do not keep the second half.
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*
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* The last iteration recombines the recomputed half with the
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* implicit half, and should yield only real numbers since the
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* target polynomial is real; moreover, s = i at that step.
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* Thus, when considering x and y:
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* y = conj(x) since the final f[j] must be real
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* Therefore, f[j] is filled with 2*Re(x), and f[j + t] is
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* filled with 2*Im(x).
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* But we already have Re(x) and Im(x) in array slots j and j+t
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* in our chosen representation. That last iteration is thus a
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* simple doubling of the values in all the array.
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*
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* We make the last iteration a no-op by tweaking the final
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* division into a division by N/2, not N.
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*/
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size_t u, n, hn, t, m;
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n = (size_t)1 << logn;
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t = 1;
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m = n;
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hn = n >> 1;
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for (u = logn; u > 1; u --) {
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size_t hm, dt, i1, j1;
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hm = m >> 1;
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dt = t << 1;
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for (i1 = 0, j1 = 0; j1 < hn; i1 ++, j1 += dt) {
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size_t j, j2;
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j2 = j1 + t;
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fpr s_re, s_im;
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s_re = fpr_gm_tab[((hm + i1) << 1) + 0];
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s_im = fpr_neg(fpr_gm_tab[((hm + i1) << 1) + 1]);
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for (j = j1; j < j2; j ++) {
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fpr x_re, x_im, y_re, y_im;
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x_re = f[j];
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x_im = f[j + hn];
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y_re = f[j + t];
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y_im = f[j + t + hn];
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FPC_ADD(f[j], f[j + hn],
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x_re, x_im, y_re, y_im);
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FPC_SUB(x_re, x_im, x_re, x_im, y_re, y_im);
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FPC_MUL(f[j + t], f[j + t + hn],
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x_re, x_im, s_re, s_im);
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}
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}
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t = dt;
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m = hm;
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}
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/*
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* Last iteration is a no-op, provided that we divide by N/2
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* instead of N. We need to make a special case for logn = 0.
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*/
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if (logn > 0) {
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fpr ni;
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ni = fpr_p2_tab[logn];
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for (u = 0; u < n; u ++) {
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f[u] = fpr_mul(f[u], ni);
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}
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_add(
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fpr *a, const fpr *b, unsigned logn) {
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size_t n, u;
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n = (size_t)1 << logn;
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for (u = 0; u < n; u ++) {
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a[u] = fpr_add(a[u], b[u]);
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_sub(
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fpr *a, const fpr *b, unsigned logn) {
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size_t n, u;
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n = (size_t)1 << logn;
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for (u = 0; u < n; u ++) {
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a[u] = fpr_sub(a[u], b[u]);
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_neg(fpr *a, unsigned logn) {
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size_t n, u;
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n = (size_t)1 << logn;
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for (u = 0; u < n; u ++) {
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a[u] = fpr_neg(a[u]);
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_adj_fft(fpr *a, unsigned logn) {
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size_t n, u;
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n = (size_t)1 << logn;
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for (u = (n >> 1); u < n; u ++) {
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a[u] = fpr_neg(a[u]);
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_mul_fft(
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fpr *a, const fpr *b, unsigned logn) {
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size_t n, hn, u;
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n = (size_t)1 << logn;
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hn = n >> 1;
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for (u = 0; u < hn; u ++) {
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fpr a_re, a_im, b_re, b_im;
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a_re = a[u];
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a_im = a[u + hn];
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b_re = b[u];
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b_im = b[u + hn];
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FPC_MUL(a[u], a[u + hn], a_re, a_im, b_re, b_im);
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_muladj_fft(
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fpr *a, const fpr *b, unsigned logn) {
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size_t n, hn, u;
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n = (size_t)1 << logn;
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hn = n >> 1;
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for (u = 0; u < hn; u ++) {
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fpr a_re, a_im, b_re, b_im;
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a_re = a[u];
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a_im = a[u + hn];
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b_re = b[u];
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b_im = fpr_neg(b[u + hn]);
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FPC_MUL(a[u], a[u + hn], a_re, a_im, b_re, b_im);
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}
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}
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/* see inner.h */
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void
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PQCLEAN_FALCON1024_CLEAN_poly_mulselfadj_fft(fpr *a, unsigned logn) {
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/*
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* Since each coefficient is multiplied with its own conjugate,
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* the result contains only real values.
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*/
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size_t n, hn, u;
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n = (size_t)1 << logn;
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hn = n >> 1;
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for (u = 0; u < hn; u ++) {
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fpr a_re, a_im;
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a_re = a[u];
|
|
a_im = a[u + hn];
|
|
a[u] = fpr_add(fpr_sqr(a_re), fpr_sqr(a_im));
|
|
a[u + hn] = fpr_zero;
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_mulconst(fpr *a, fpr x, unsigned logn) {
|
|
size_t n, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
for (u = 0; u < n; u ++) {
|
|
a[u] = fpr_mul(a[u], x);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_div_fft(
|
|
fpr *a, const fpr *b, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
fpr a_re, a_im, b_re, b_im;
|
|
|
|
a_re = a[u];
|
|
a_im = a[u + hn];
|
|
b_re = b[u];
|
|
b_im = b[u + hn];
|
|
FPC_DIV(a[u], a[u + hn], a_re, a_im, b_re, b_im);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_invnorm2_fft(fpr *d,
|
|
const fpr *a, const fpr *b, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
fpr a_re, a_im;
|
|
fpr b_re, b_im;
|
|
|
|
a_re = a[u];
|
|
a_im = a[u + hn];
|
|
b_re = b[u];
|
|
b_im = b[u + hn];
|
|
d[u] = fpr_inv(fpr_add(
|
|
fpr_add(fpr_sqr(a_re), fpr_sqr(a_im)),
|
|
fpr_add(fpr_sqr(b_re), fpr_sqr(b_im))));
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_add_muladj_fft(fpr *d,
|
|
const fpr *F, const fpr *G,
|
|
const fpr *f, const fpr *g, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
fpr F_re, F_im, G_re, G_im;
|
|
fpr f_re, f_im, g_re, g_im;
|
|
fpr a_re, a_im, b_re, b_im;
|
|
|
|
F_re = F[u];
|
|
F_im = F[u + hn];
|
|
G_re = G[u];
|
|
G_im = G[u + hn];
|
|
f_re = f[u];
|
|
f_im = f[u + hn];
|
|
g_re = g[u];
|
|
g_im = g[u + hn];
|
|
|
|
FPC_MUL(a_re, a_im, F_re, F_im, f_re, fpr_neg(f_im));
|
|
FPC_MUL(b_re, b_im, G_re, G_im, g_re, fpr_neg(g_im));
|
|
d[u] = fpr_add(a_re, b_re);
|
|
d[u + hn] = fpr_add(a_im, b_im);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_mul_autoadj_fft(
|
|
fpr *a, const fpr *b, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
a[u] = fpr_mul(a[u], b[u]);
|
|
a[u + hn] = fpr_mul(a[u + hn], b[u]);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_div_autoadj_fft(
|
|
fpr *a, const fpr *b, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
fpr ib;
|
|
|
|
ib = fpr_inv(b[u]);
|
|
a[u] = fpr_mul(a[u], ib);
|
|
a[u + hn] = fpr_mul(a[u + hn], ib);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_LDL_fft(
|
|
const fpr *g00,
|
|
fpr *g01, fpr *g11, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
fpr g00_re, g00_im, g01_re, g01_im, g11_re, g11_im;
|
|
fpr mu_re, mu_im;
|
|
|
|
g00_re = g00[u];
|
|
g00_im = g00[u + hn];
|
|
g01_re = g01[u];
|
|
g01_im = g01[u + hn];
|
|
g11_re = g11[u];
|
|
g11_im = g11[u + hn];
|
|
FPC_DIV(mu_re, mu_im, g01_re, g01_im, g00_re, g00_im);
|
|
FPC_MUL(g01_re, g01_im, mu_re, mu_im, g01_re, fpr_neg(g01_im));
|
|
FPC_SUB(g11[u], g11[u + hn], g11_re, g11_im, g01_re, g01_im);
|
|
g01[u] = mu_re;
|
|
g01[u + hn] = fpr_neg(mu_im);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_LDLmv_fft(
|
|
fpr *d11, fpr *l10,
|
|
const fpr *g00, const fpr *g01,
|
|
const fpr *g11, unsigned logn) {
|
|
size_t n, hn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
for (u = 0; u < hn; u ++) {
|
|
fpr g00_re, g00_im, g01_re, g01_im, g11_re, g11_im;
|
|
fpr mu_re, mu_im;
|
|
|
|
g00_re = g00[u];
|
|
g00_im = g00[u + hn];
|
|
g01_re = g01[u];
|
|
g01_im = g01[u + hn];
|
|
g11_re = g11[u];
|
|
g11_im = g11[u + hn];
|
|
FPC_DIV(mu_re, mu_im, g01_re, g01_im, g00_re, g00_im);
|
|
FPC_MUL(g01_re, g01_im, mu_re, mu_im, g01_re, fpr_neg(g01_im));
|
|
FPC_SUB(d11[u], d11[u + hn], g11_re, g11_im, g01_re, g01_im);
|
|
l10[u] = mu_re;
|
|
l10[u + hn] = fpr_neg(mu_im);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_split_fft(
|
|
fpr *f0, fpr *f1,
|
|
const fpr *f, unsigned logn) {
|
|
/*
|
|
* The FFT representation we use is in bit-reversed order
|
|
* (element i contains f(w^(rev(i))), where rev() is the
|
|
* bit-reversal function over the ring degree. This changes
|
|
* indexes with regards to the Falcon specification.
|
|
*/
|
|
size_t n, hn, qn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
qn = hn >> 1;
|
|
|
|
/*
|
|
* We process complex values by pairs. For logn = 1, there is only
|
|
* one complex value (the other one is the implicit conjugate),
|
|
* so we add the two lines below because the loop will be
|
|
* skipped.
|
|
*/
|
|
f0[0] = f[0];
|
|
f1[0] = f[hn];
|
|
|
|
for (u = 0; u < qn; u ++) {
|
|
fpr a_re, a_im, b_re, b_im;
|
|
fpr t_re, t_im;
|
|
|
|
a_re = f[(u << 1) + 0];
|
|
a_im = f[(u << 1) + 0 + hn];
|
|
b_re = f[(u << 1) + 1];
|
|
b_im = f[(u << 1) + 1 + hn];
|
|
|
|
FPC_ADD(t_re, t_im, a_re, a_im, b_re, b_im);
|
|
f0[u] = fpr_half(t_re);
|
|
f0[u + qn] = fpr_half(t_im);
|
|
|
|
FPC_SUB(t_re, t_im, a_re, a_im, b_re, b_im);
|
|
FPC_MUL(t_re, t_im, t_re, t_im,
|
|
fpr_gm_tab[((u + hn) << 1) + 0],
|
|
fpr_neg(fpr_gm_tab[((u + hn) << 1) + 1]));
|
|
f1[u] = fpr_half(t_re);
|
|
f1[u + qn] = fpr_half(t_im);
|
|
}
|
|
}
|
|
|
|
/* see inner.h */
|
|
void
|
|
PQCLEAN_FALCON1024_CLEAN_poly_merge_fft(
|
|
fpr *f,
|
|
const fpr *f0, const fpr *f1, unsigned logn) {
|
|
size_t n, hn, qn, u;
|
|
|
|
n = (size_t)1 << logn;
|
|
hn = n >> 1;
|
|
qn = hn >> 1;
|
|
|
|
/*
|
|
* An extra copy to handle the special case logn = 1.
|
|
*/
|
|
f[0] = f0[0];
|
|
f[hn] = f1[0];
|
|
|
|
for (u = 0; u < qn; u ++) {
|
|
fpr a_re, a_im, b_re, b_im;
|
|
fpr t_re, t_im;
|
|
|
|
a_re = f0[u];
|
|
a_im = f0[u + qn];
|
|
FPC_MUL(b_re, b_im, f1[u], f1[u + qn],
|
|
fpr_gm_tab[((u + hn) << 1) + 0],
|
|
fpr_gm_tab[((u + hn) << 1) + 1]);
|
|
FPC_ADD(t_re, t_im, a_re, a_im, b_re, b_im);
|
|
f[(u << 1) + 0] = t_re;
|
|
f[(u << 1) + 0 + hn] = t_im;
|
|
FPC_SUB(t_re, t_im, a_re, a_im, b_re, b_im);
|
|
f[(u << 1) + 1] = t_re;
|
|
f[(u << 1) + 1 + hn] = t_im;
|
|
}
|
|
}
|