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5e68873d22
Make all the drawing ops be based on the constants. This way we can change the fixed size at least at compile time.
363 lines
11 KiB
C
363 lines
11 KiB
C
/* Karatsuba convolution
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*
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* Copyright (C) 1999 Ralph Loader <suckfish@ihug.co.nz>
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*
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Library General Public
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* License as published by the Free Software Foundation; either
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* version 2 of the License, or (at your option) any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Library General Public License for more details.
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*
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* You should have received a copy of the GNU Library General Public
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* License along with this library; if not, write to the
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* Free Software Foundation, Inc., 51 Franklin St, Fifth Floor,
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* Boston, MA 02110-1301, USA.
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*
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*
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* Note: 7th December 2004: This file used to be licensed under the GPL,
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* but we got permission from Ralp Loader to relicense it to LGPL.
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*
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* $Id$
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*
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*/
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/* The algorithm is based on the following. For the convolution of a pair
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* of pairs, (a,b) * (c,d) = (0, a.c, a.d+b.c, b.d), we can reduce the four
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* multiplications to three, by the formulae a.d+b.c = (a+b).(c+d) - a.c -
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* b.d. A similar relation enables us to compute a 2n by 2n convolution
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* using 3 n by n convolutions, and thus a 2^n by 2^n convolution using 3^n
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* multiplications (as opposed to the 4^n that the quadratic algorithm
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* takes. */
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/* For large n, this is slower than the O(n log n) that the FFT method
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* takes, but we avoid using complex numbers, and we only have to compute
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* one convolution, as opposed to 3 FFTs. We have good locality-of-
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* reference as well, which will help on CPUs with tiny caches. */
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/* E.g., for a 512 x 512 convolution, the FFT method takes 55 * 512 = 28160
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* (real) multiplications, as opposed to 3^9 = 19683 for the Karatsuba
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* algorithm. We actually want 257 outputs of a 256 x 512 convolution;
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* that doesn't appear to give an easy advantage for the FFT algorithm, but
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* for the Karatsuba algorithm, it's easy to use two 256 x 256
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* convolutions, taking 2 x 3^8 = 12312 multiplications. [This difference
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* is that the FFT method "wraps" the arrays, doing a 2^n x 2^n -> 2^n,
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* while the Karatsuba algorithm pads with zeros, doing 2^n x 2^n -> 2.2^n
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* - 1]. */
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/* There's a big lie above, actually... for a 4x4 convolution, it's quicker
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* to do it using 16 multiplications than the more complex Karatsuba
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* algorithm... So the recursion bottoms out at 4x4s. This increases the
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* number of multiplications by a factor of 16/9, but reduces the overheads
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* dramatically. */
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/* The convolution algorithm is implemented as a stack machine. We have a
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* stack of commands, each in one of the forms "do a 2^n x 2^n
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* convolution", or "combine these three length 2^n outputs into one
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* 2^{n+1} output." */
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include <stdlib.h>
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#include "convolve.h"
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typedef union stack_entry_s
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{
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struct
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{
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const double *left, *right;
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double *out;
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}
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v;
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struct
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{
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double *main, *null;
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}
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b;
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}
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stack_entry;
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struct _struct_convolve_state
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{
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int depth, small, big, stack_size;
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double *left;
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double *right;
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double *scratch;
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stack_entry *stack;
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};
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/*
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* Initialisation routine - sets up tables and space to work in.
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* Returns a pointer to internal state, to be used when performing calls.
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* On error, returns NULL.
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* The pointer should be freed when it is finished with, by convolve_close().
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*/
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convolve_state *
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convolve_init (int depth)
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{
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convolve_state *state;
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state = malloc (sizeof (convolve_state));
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state->depth = depth;
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state->small = (1 << depth);
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state->big = (2 << depth);
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state->stack_size = depth * 3;
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state->left = calloc (state->big, sizeof (double));
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state->right = calloc (state->small * 3, sizeof (double));
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state->scratch = calloc (state->small * 3, sizeof (double));
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state->stack = calloc (state->stack_size + 1, sizeof (stack_entry));
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return state;
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}
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/*
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* Free the state allocated with convolve_init().
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*/
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void
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convolve_close (convolve_state * state)
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{
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free (state->left);
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free (state->right);
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free (state->scratch);
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free (state->stack);
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free (state);
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}
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static void
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convolve_4 (double *out, const double *left, const double *right)
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/* This does a 4x4 -> 7 convolution. For what it's worth, the slightly odd
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* ordering gives about a 1% speed up on my Pentium II. */
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{
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double l0, l1, l2, l3, r0, r1, r2, r3;
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double a;
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l0 = left[0];
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r0 = right[0];
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a = l0 * r0;
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l1 = left[1];
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r1 = right[1];
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out[0] = a;
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a = (l0 * r1) + (l1 * r0);
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l2 = left[2];
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r2 = right[2];
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out[1] = a;
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a = (l0 * r2) + (l1 * r1) + (l2 * r0);
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l3 = left[3];
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r3 = right[3];
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out[2] = a;
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out[3] = (l0 * r3) + (l1 * r2) + (l2 * r1) + (l3 * r0);
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out[4] = (l1 * r3) + (l2 * r2) + (l3 * r1);
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out[5] = (l2 * r3) + (l3 * r2);
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out[6] = l3 * r3;
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}
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static void
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convolve_run (stack_entry * top, unsigned size, double *scratch)
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/* Interpret a stack of commands. The stack starts with two entries; the
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* convolution to do, and an illegal entry used to mark the stack top. The
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* size is the number of entries in each input, and must be a power of 2,
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* and at least 8. It is OK to have out equal to left and/or right.
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* scratch must have length 3*size. The number of stack entries needed is
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* 3n-4 where size=2^n. */
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{
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do {
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const double *left;
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const double *right;
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double *out;
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/* When we get here, the stack top is always a convolve,
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* with size > 4. So we will split it. We repeatedly split
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* the top entry until we get to size = 4. */
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left = top->v.left;
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right = top->v.right;
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out = top->v.out;
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top++;
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do {
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double *s_left, *s_right;
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int i;
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/* Halve the size. */
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size >>= 1;
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/* Allocate the scratch areas. */
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s_left = scratch + size * 3;
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/* s_right is a length 2*size buffer also used for
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* intermediate output. */
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s_right = scratch + size * 4;
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/* Create the intermediate factors. */
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for (i = 0; i < size; i++) {
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double l = left[i] + left[i + size];
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double r = right[i] + right[i + size];
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s_left[i + size] = r;
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s_left[i] = l;
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}
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/* Push the combine entry onto the stack. */
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top -= 3;
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top[2].b.main = out;
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top[2].b.null = NULL;
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/* Push the low entry onto the stack. This must be
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* the last of the three sub-convolutions, because
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* it may overwrite the arguments. */
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top[1].v.left = left;
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top[1].v.right = right;
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top[1].v.out = out;
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/* Push the mid entry onto the stack. */
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top[0].v.left = s_left;
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top[0].v.right = s_right;
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top[0].v.out = s_right;
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/* Leave the high entry in variables. */
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left += size;
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right += size;
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out += size * 2;
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} while (size > 4);
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/* When we get here, the stack top is a group of 3
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* convolves, with size = 4, followed by some combines. */
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convolve_4 (out, left, right);
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convolve_4 (top[0].v.out, top[0].v.left, top[0].v.right);
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convolve_4 (top[1].v.out, top[1].v.left, top[1].v.right);
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top += 2;
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/* Now process combines. */
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do {
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/* b.main is the output buffer, mid is the middle
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* part which needs to be adjusted in place, and
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* then folded back into the output. We do this in
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* a slightly strange way, so as to avoid having
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* two loops. */
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double *out = top->b.main;
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double *mid = scratch + size * 4;
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unsigned int i;
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top++;
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out[size * 2 - 1] = 0;
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for (i = 0; i < size - 1; i++) {
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double lo;
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double hi;
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lo = mid[0] - (out[0] + out[2 * size]) + out[size];
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hi = mid[size] - (out[size] + out[3 * size]) + out[2 * size];
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out[size] = lo;
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out[2 * size] = hi;
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out++;
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mid++;
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}
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size <<= 1;
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} while (top->b.null == NULL);
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} while (top->b.main != NULL);
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}
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/*
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* convolve_match:
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* @lastchoice: an array of size SMALL.
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* @input: an array of size BIG (2*SMALL)
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* @state: a (non-NULL) pointer returned by convolve_init.
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*
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* We find the contiguous SMALL-size sub-array of input that best matches
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* lastchoice. A measure of how good a sub-array is compared with the lastchoice
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* is given by the sum of the products of each pair of entries. We maximise
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* that, by taking an appropriate convolution, and then finding the maximum
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* entry in the convolutions.
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*
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* Return: the position of the best match
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*/
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int
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convolve_match (const int *lastchoice, const short *input,
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convolve_state * state)
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{
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double avg = 0;
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double best;
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int p = 0;
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int i;
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double *left = state->left;
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double *right = state->right;
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double *scratch = state->scratch;
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stack_entry *top = state->stack + (state->stack_size - 1);
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for (i = 0; i < state->big; i++)
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left[i] = input[i];
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for (i = 0; i < state->small; i++) {
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double a = lastchoice[(state->small - 1) - i];
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right[i] = a;
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avg += a;
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}
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/* We adjust the smaller of the two input arrays to have average
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* value 0. This makes the eventual result insensitive to both
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* constant offsets and positive multipliers of the inputs. */
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avg /= state->small;
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for (i = 0; i < state->small; i++)
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right[i] -= avg;
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/* End-of-stack marker. */
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top[1].b.null = scratch;
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top[1].b.main = NULL;
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/* The low (small x small) part, of which we want the high outputs. */
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top->v.left = left;
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top->v.right = right;
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top->v.out = right + state->small;
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convolve_run (top, state->small, scratch);
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/* The high (small x small) part, of which we want the low outputs. */
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top->v.left = left + state->small;
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top->v.right = right;
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top->v.out = right;
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convolve_run (top, state->small, scratch);
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/* Now find the best position amoungs this. Apart from the first
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* and last, the required convolution outputs are formed by adding
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* outputs from the two convolutions above. */
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best = right[state->big - 1];
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right[state->big + state->small - 1] = 0;
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p = -1;
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for (i = 0; i < state->small; i++) {
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double a = right[i] + right[i + state->big];
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if (a > best) {
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best = a;
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p = i;
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}
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}
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p++;
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#if 0
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{
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/* This is some debugging code... */
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best = 0;
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for (i = 0; i < state->small; i++)
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best += ((double) input[i + p]) * ((double) lastchoice[i] - avg);
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for (i = 0; i <= state->small; i++) {
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double tot = 0;
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unsigned int j;
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for (j = 0; j < state->small; j++)
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tot += ((double) input[i + j]) * ((double) lastchoice[j] - avg);
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if (tot > best)
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printf ("(%i)", i);
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if (tot != left[i + (state->small - 1)])
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printf ("!");
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}
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printf ("%i\n", p);
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}
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#endif
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return p;
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}
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