gcc/gmp/tests/mpn/t-matrix22.c - native_client/nacl-toolchain - Git at Google

 /* Tests matrix22_mul.

 Copyright 2008 Free Software Foundation, Inc.

 This file is part of the GNU MP Library.

 The GNU MP Library is free software; you can redistribute it and/or modify
 it under the terms of the GNU Lesser General Public License as published by
 the Free Software Foundation; either version 3 of the License, or (at your
 option) any later version.

 The GNU MP Library is distributed in the hope that it will be useful, but
 WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
 or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Lesser General Public
 License for more details.

 You should have received a copy of the GNU Lesser General Public License
 along with the GNU MP Library.  If not, see http://www.gnu.org/licenses/.  */

 #include <stdio.h>
 #include <stdlib.h>

 #include "gmp.h"
 #include "gmp-impl.h"
 #include "tests.h"

 struct matrix {
   mp_size_t alloc;
   mp_size_t n;
   mp_ptr e00, e01, e10, e11;
 };

 static void
 matrix_init (struct matrix *M, mp_size_t n)
 {
   mp_ptr p = refmpn_malloc_limbs (4*(n+1));
   M->e00 = p; p += n+1;
   M->e01 = p; p += n+1;
   M->e10 = p; p += n+1;
   M->e11 = p;
   M->alloc = n + 1;
   M->n = 0;
 }

 static void
 matrix_clear (struct matrix *M)
 {
   refmpn_free_limbs (M->e00);
 }

 static void
 matrix_copy (struct matrix *R, const struct matrix *M)
 {
   R->n = M->n;
   MPN_COPY (R->e00, M->e00, M->n);
   MPN_COPY (R->e01, M->e01, M->n);
   MPN_COPY (R->e10, M->e10, M->n);
   MPN_COPY (R->e11, M->e11, M->n);
 }

 /* Used with same size, so no need for normalization. */
 static int
 matrix_equal_p (const struct matrix *A, const struct matrix *B)
 {
   return (A->n == B->n
 	  && mpn_cmp (A->e00, B->e00, A->n) == 0
 	  && mpn_cmp (A->e01, B->e01, A->n) == 0
 	  && mpn_cmp (A->e10, B->e10, A->n) == 0
 	  && mpn_cmp (A->e11, B->e11, A->n) == 0);
 }

 static void
 matrix_random(struct matrix *M, mp_size_t n, gmp_randstate_ptr rands)
 {
   M->n = n;
   mpn_random (M->e00, n);
   mpn_random (M->e01, n);
   mpn_random (M->e10, n);
   mpn_random (M->e11, n);
 }

 #define MUL(rp, ap, an, bp, bn) do { \
     if (an > bn)		     \
       mpn_mul (rp, ap, an, bp, bn);  \
     else			     \
       mpn_mul (rp, bp, bn, ap, an);  \
   } while(0)

 static void
 ref_matrix22_mul (struct matrix *R,
 		  const struct matrix *A,
 		  const struct matrix *B, mp_ptr tp)
 {
   mp_size_t an, bn, n;
   mp_ptr r00, r01, r10, r11, a00, a01, a10, a11, b00, b01, b10, b11;

   if (A->n >= B->n)
     {
       r00 = R->e00; a00 = A->e00; b00 = B->e00;
       r01 = R->e01; a01 = A->e01; b01 = B->e01;
       r10 = R->e10; a10 = A->e10; b10 = B->e10;
       r11 = R->e11; a11 = A->e11; b11 = B->e11;
       an = A->n, bn = B->n;
     }
   else
     {
       /* Transpose */
       r00 = R->e00; a00 = B->e00; b00 = A->e00;
       r01 = R->e10; a01 = B->e10; b01 = A->e10;
       r10 = R->e01; a10 = B->e01; b10 = A->e01;
       r11 = R->e11; a11 = B->e11; b11 = A->e11;
       an = B->n, bn = A->n;
     }
   n = an + bn;
   R->n = n + 1;

   mpn_mul (r00, a00, an, b00, bn);
   mpn_mul (tp, a01, an, b10, bn);
   r00[n] = mpn_add_n (r00, r00, tp, n);

   mpn_mul (r01, a00, an, b01, bn);
   mpn_mul (tp, a01, an, b11, bn);
   r01[n] = mpn_add_n (r01, r01, tp, n);

   mpn_mul (r10, a10, an, b00, bn);
   mpn_mul (tp, a11, an, b10, bn);
   r10[n] = mpn_add_n (r10, r10, tp, n);

   mpn_mul (r11, a10, an, b01, bn);
   mpn_mul (tp, a11, an, b11, bn);
   r11[n] = mpn_add_n (r11, r11, tp, n);
 }

 static void
 one_test (const struct matrix *A, const struct matrix *B, int i)
 {
   struct matrix R;
   struct matrix P;
   mp_ptr tp;

   matrix_init (&R, A->n + B->n + 1);
   matrix_init (&P, A->n + B->n + 1);

   tp = refmpn_malloc_limbs (mpn_matrix22_mul_itch (A->n, B->n));

   ref_matrix22_mul (&R, A, B, tp);
   matrix_copy (&P, A);
   mpn_matrix22_mul (P.e00, P.e01, P.e10, P.e11, A->n,
 		    B->e00, B->e01, B->e10, B->e11, B->n, tp);
   P.n = A->n + B->n + 1;
   if (!matrix_equal_p (&R, &P))
     {
       fprintf (stderr, "ERROR in test %d\n", i);
       gmp_fprintf (stderr, "A = (%Nx, %Nx\n      %Nx, %Nx)\n"
 		   "B = (%Nx, %Nx\n      %Nx, %Nx)\n"
 		   "R = (%Nx, %Nx (expected)\n      %Nx, %Nx)\n"
 		   "P = (%Nx, %Nx (incorrect)\n      %Nx, %Nx)\n",
 		   A->e00, A->n, A->e01, A->n, A->e10, A->n, A->e11, A->n,
 		   B->e00, B->n, B->e01, B->n, B->e10, B->n, B->e11, B->n,
 		   R.e00, R.n, R.e01, R.n, R.e10, R.n, R.e11, R.n,
 		   P.e00, P.n, P.e01, P.n, P.e10, P.n, P.e11, P.n);
       abort();
     }
   refmpn_free_limbs (tp);
   matrix_clear (&R);
   matrix_clear (&P);
 }

 #define MAX_SIZE (2+2*MATRIX22_STRASSEN_THRESHOLD)

 int
 main (int argc, char **argv)
 {
   struct matrix A;
   struct matrix B;

   gmp_randstate_ptr rands;
   mpz_t bs;
   int i;

   tests_start ();
   rands = RANDS;

   matrix_init (&A, MAX_SIZE);
   matrix_init (&B, MAX_SIZE);
   mpz_init (bs);

   for (i = 0; i < 17; i++)
     {
       mp_size_t an, bn;
       mpz_urandomb (bs, rands, 32);
       an = 1 + mpz_get_ui (bs) % MAX_SIZE;
       mpz_urandomb (bs, rands, 32);
       bn = 1 + mpz_get_ui (bs) % MAX_SIZE;

       matrix_random (&A, an, rands);
       matrix_random (&B, bn, rands);

       one_test (&A, &B, i);
     }
   mpz_clear (bs);
   matrix_clear (&A);
   matrix_clear (&B);

   return 0;
 }
	/* Tests matrix22_mul.

	Copyright 2008 Free Software Foundation, Inc.

	This file is part of the GNU MP Library.

	The GNU MP Library is free software; you can redistribute it and/or modify
	it under the terms of the GNU Lesser General Public License as published by
	the Free Software Foundation; either version 3 of the License, or (at your
	option) any later version.

	The GNU MP Library is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
	or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
	License for more details.

	You should have received a copy of the GNU Lesser General Public License
	along with the GNU MP Library. If not, see http://www.gnu.org/licenses/. */

	#include <stdio.h>
	#include <stdlib.h>

	#include "gmp.h"
	#include "gmp-impl.h"
	#include "tests.h"

	struct matrix {
	mp_size_t alloc;
	mp_size_t n;
	mp_ptr e00, e01, e10, e11;
	};

	static void
	matrix_init (struct matrix *M, mp_size_t n)
	{
	mp_ptr p = refmpn_malloc_limbs (4*(n+1));
	M->e00 = p; p += n+1;
	M->e01 = p; p += n+1;
	M->e10 = p; p += n+1;
	M->e11 = p;
	M->alloc = n + 1;
	M->n = 0;
	}

	static void
	matrix_clear (struct matrix *M)
	{
	refmpn_free_limbs (M->e00);
	}

	static void
	matrix_copy (struct matrix R, const struct matrix M)
	{
	R->n = M->n;
	MPN_COPY (R->e00, M->e00, M->n);
	MPN_COPY (R->e01, M->e01, M->n);
	MPN_COPY (R->e10, M->e10, M->n);
	MPN_COPY (R->e11, M->e11, M->n);
	}

	/* Used with same size, so no need for normalization. */
	static int
	matrix_equal_p (const struct matrix A, const struct matrix B)
	{
	return (A->n == B->n
	&& mpn_cmp (A->e00, B->e00, A->n) == 0
	&& mpn_cmp (A->e01, B->e01, A->n) == 0
	&& mpn_cmp (A->e10, B->e10, A->n) == 0
	&& mpn_cmp (A->e11, B->e11, A->n) == 0);
	}

	static void
	matrix_random(struct matrix *M, mp_size_t n, gmp_randstate_ptr rands)
	{
	M->n = n;
	mpn_random (M->e00, n);
	mpn_random (M->e01, n);
	mpn_random (M->e10, n);
	mpn_random (M->e11, n);
	}

	#define MUL(rp, ap, an, bp, bn) do { \
	if (an > bn) \
	mpn_mul (rp, ap, an, bp, bn); \
	else \
	mpn_mul (rp, bp, bn, ap, an); \
	} while(0)

	static void
	ref_matrix22_mul (struct matrix *R,
	const struct matrix *A,
	const struct matrix *B, mp_ptr tp)
	{
	mp_size_t an, bn, n;
	mp_ptr r00, r01, r10, r11, a00, a01, a10, a11, b00, b01, b10, b11;

	if (A->n >= B->n)
	{
	r00 = R->e00; a00 = A->e00; b00 = B->e00;
	r01 = R->e01; a01 = A->e01; b01 = B->e01;
	r10 = R->e10; a10 = A->e10; b10 = B->e10;
	r11 = R->e11; a11 = A->e11; b11 = B->e11;
	an = A->n, bn = B->n;
	}
	else
	{
	/* Transpose */
	r00 = R->e00; a00 = B->e00; b00 = A->e00;
	r01 = R->e10; a01 = B->e10; b01 = A->e10;
	r10 = R->e01; a10 = B->e01; b10 = A->e01;
	r11 = R->e11; a11 = B->e11; b11 = A->e11;
	an = B->n, bn = A->n;
	}
	n = an + bn;
	R->n = n + 1;

	mpn_mul (r00, a00, an, b00, bn);
	mpn_mul (tp, a01, an, b10, bn);
	r00[n] = mpn_add_n (r00, r00, tp, n);

	mpn_mul (r01, a00, an, b01, bn);
	mpn_mul (tp, a01, an, b11, bn);
	r01[n] = mpn_add_n (r01, r01, tp, n);

	mpn_mul (r10, a10, an, b00, bn);
	mpn_mul (tp, a11, an, b10, bn);
	r10[n] = mpn_add_n (r10, r10, tp, n);

	mpn_mul (r11, a10, an, b01, bn);
	mpn_mul (tp, a11, an, b11, bn);
	r11[n] = mpn_add_n (r11, r11, tp, n);
	}

	static void
	one_test (const struct matrix A, const struct matrix B, int i)
	{
	struct matrix R;
	struct matrix P;
	mp_ptr tp;

	matrix_init (&R, A->n + B->n + 1);
	matrix_init (&P, A->n + B->n + 1);

	tp = refmpn_malloc_limbs (mpn_matrix22_mul_itch (A->n, B->n));

	ref_matrix22_mul (&R, A, B, tp);
	matrix_copy (&P, A);
	mpn_matrix22_mul (P.e00, P.e01, P.e10, P.e11, A->n,
	B->e00, B->e01, B->e10, B->e11, B->n, tp);
	P.n = A->n + B->n + 1;
	if (!matrix_equal_p (&R, &P))
	{
	fprintf (stderr, "ERROR in test %d\n", i);
	gmp_fprintf (stderr, "A = (%Nx, %Nx\n %Nx, %Nx)\n"
	"B = (%Nx, %Nx\n %Nx, %Nx)\n"
	"R = (%Nx, %Nx (expected)\n %Nx, %Nx)\n"
	"P = (%Nx, %Nx (incorrect)\n %Nx, %Nx)\n",
	A->e00, A->n, A->e01, A->n, A->e10, A->n, A->e11, A->n,
	B->e00, B->n, B->e01, B->n, B->e10, B->n, B->e11, B->n,
	R.e00, R.n, R.e01, R.n, R.e10, R.n, R.e11, R.n,
	P.e00, P.n, P.e01, P.n, P.e10, P.n, P.e11, P.n);
	abort();
	}
	refmpn_free_limbs (tp);
	matrix_clear (&R);
	matrix_clear (&P);
	}

	#define MAX_SIZE (2+2*MATRIX22_STRASSEN_THRESHOLD)

	int
	main (int argc, char **argv)
	{
	struct matrix A;
	struct matrix B;

	gmp_randstate_ptr rands;
	mpz_t bs;
	int i;

	tests_start ();
	rands = RANDS;

	matrix_init (&A, MAX_SIZE);
	matrix_init (&B, MAX_SIZE);
	mpz_init (bs);

	for (i = 0; i < 17; i++)
	{
	mp_size_t an, bn;
	mpz_urandomb (bs, rands, 32);
	an = 1 + mpz_get_ui (bs) % MAX_SIZE;
	mpz_urandomb (bs, rands, 32);
	bn = 1 + mpz_get_ui (bs) % MAX_SIZE;

	matrix_random (&A, an, rands);
	matrix_random (&B, bn, rands);

	one_test (&A, &B, i);
	}
	mpz_clear (bs);
	matrix_clear (&A);
	matrix_clear (&B);

	return 0;
	}