var_eq_times.c
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/*
* var_eq_times.c
*
* Created on: 27/01/2017
* Author: pedro
*/
#ifndef __OPENCL_VERSION__
#include <stddef.h>
#include <stdio.h>
#include <math.h>
#include "var_eq_times.h"
#include "../bitmaps.h"
#include "../config.h"
#include "../variables.h"
#endif
#include "../kernels/cl_aux_functions.h"
#if CL_D_TYPE == CL_BITMAP
#include "../kernels/cl_bitmaps.h"
#elif CL_D_TYPE == CL_INTERVAL
#include "../kernels/cl_intervals.h"
#endif
#include "../kernels/cl_constraints.h"
#include "../kernels/cl_variables.h"
#include "../kernels/cl_ttl.h"
#ifndef __OPENCL_VERSION__
/*
* Creates a new constraint of the var_eq_times type and return the constraint ID
* x = y × z
* x_id - ID of variable x
* y_id - ID of variable y
* z_id - ID of variable z
*/
unsigned int c_var_eq_times(unsigned int x_id, unsigned int y_id, unsigned int z_id) {
// set to include in kernel compilation
USE_CS[VAR_EQ_TIMES] = 1;
USE_NON_CS_REIFI[VAR_EQ_TIMES] = 1;
REV = 1;
unsigned int c_vs[3];
c_vs[0] = x_id;
c_vs[1] = y_id;
c_vs[2] = z_id;
// creates a new generic constraint
unsigned int c_id = c_new(c_vs, 3, NULL, 0, -1);
// pointers to this type of constraint functions
CS[c_id].kind = VAR_EQ_TIMES;
CS[c_id].check_sol_f = &var_eq_times_check;
CS[c_id].constant_val = 0;
return c_id;
}
/*
* Creates a new reified constraint of the var_eq_times type and return the constraint ID
* x = y × z
* x_id - ID of variable x
* y_id - ID of variable y
* z_id - ID of variable z
* reif_v_id - ID of the reification variable
*/
unsigned int c_var_eq_times_reif(unsigned int x_id, unsigned int y_id, unsigned int z_id, int reif_v_id) {
if (VS[reif_v_id].max > 1) {
v_del_gt(&VS[reif_v_id], 1);
if (VS[reif_v_id].n_vals == 0) {
fprintf(stderr, "\nError: Constraint VAR_EQ_TIMES_REIF makes model inconsistent at creation:\n");
exit(-1);
}
}
// set to include in kernel compilation
USE_CS[VAR_EQ_TIMES] = 1;
USE_CS_REIFI[VAR_EQ_TIMES] = 1;
REV = 1;
unsigned int c_vs[3];
c_vs[0] = x_id;
c_vs[1] = y_id;
c_vs[2] = z_id;
// creates a new generic constraint
unsigned int c_id = c_new(c_vs, 3, NULL, 0, reif_v_id);
// pointers to this type of constraint functions
CS[c_id].kind = VAR_EQ_TIMES;
CS[c_id].check_sol_f = &var_eq_times_check;
CS[c_id].constant_val = 0;
return c_id;
}
/*
* Return true if the var_eq_times constraint is respected or false if not
* x = y × z
* c - constraint to check if is respected
* explored - if the CSP was already explored, which mean that all the variables must already be singletons
* */
bool var_eq_times_check(constr* c, bool explored) {
// check if any variable inside same a_eq_b_plus_c constraint has domain 0, more than one value
// or if the sum is not correct. If so, return false. Else return true.
if (c->c_vs[0]->min != c->c_vs[1]->min * c->c_vs[2]->min
#if CHECK_SOL_N_VALS
|| (c->c_vs[0]->to_label && c->c_vs[0]->n_vals != 1) || (c->c_vs[1]->to_label && c->c_vs[1]->n_vals != 1) || (c->c_vs[2]->to_label && c->c_vs[2]->n_vals != 1)
#endif
) {
if (explored) {
fprintf(stderr, "\nError: Constraint VAR_EQ_TIMES (%d) not respected:\n", c->c_id);
fprintf(stderr, "Variable ID=%u -> minimum=%u, maximum=%u, number of values=%u\n\n", c->c_vs[0]->v_id, b_get_min_val(&c->c_vs[0]->domain_b),
b_get_max_val(&c->c_vs[0]->domain_b), b_cnt_vals(&c->c_vs[0]->domain_b));
fprintf(stderr, "Variable ID=%u -> minimum=%u, maximum=%u, number of values=%u\n\n", c->c_vs[1]->v_id, b_get_min_val(&c->c_vs[1]->domain_b),
b_get_max_val(&c->c_vs[1]->domain_b), b_cnt_vals(&c->c_vs[1]->domain_b));
fprintf(stderr, "Variable ID=%u -> minimum=%u, maximum=%u, number of values=%u\n\n", c->c_vs[2]->v_id, b_get_min_val(&c->c_vs[2]->domain_b),
b_get_max_val(&c->c_vs[2]->domain_b), b_cnt_vals(&c->c_vs[2]->domain_b));
}
return false;
}
return true;
}
#endif
#if CS_VAR_EQ_TIMES == 1
/*
* Propagate the domain of the variable with the ID prop_v_id through all the other variables on the same c_numb ID var_eq_times constrain
* x = y * z
* prop_ok will be set to 1 if success or to 0 if any domain became empty
* vs_per_c_idx - vector with all constrained variables ID per constraint, per constraint ID order
* vs_prop_ - all CSP variables with current step values
* prop_v_id - variable ID to propagate
* current_cs - constraint that should be propagated for the variable with prop_v_id ID
* vs_id_to_prop_ - circular vector with the ids of the variables to propagate
*/
#ifndef __OPENCL_VERSION__
#if CS_IGNORE == 0
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
#endif
#endif
CUDA_FUNC void var_eq_times_prop(CL_INTS_MEM int* vs_per_c_idx, CL_MEMORY VARS_PROP* vs_prop_, unsigned int prop_v_id, CL_CS_MEM cl_constr* current_cs, CL_MEMORY unsigned short* vs_id_to_prop_,
bool* prop_ok CS_IGNORE_FUNC TTL_CTR) {
int x_id = vs_per_c_idx[0];
int y_id = vs_per_c_idx[1];
int z_id = vs_per_c_idx[2];
bool changed_x1 = 0;
bool changed_y1 = 0;
bool changed_z1 = 0;
bool changed_x2 = 0;
bool changed_y2 = 0;
bool changed_z2 = 0;
if (prop_v_id == (unsigned int)x_id) {
if (V_MAX(vs_prop_[z_id]) > 0) {
cl_v_del_lt_m(&changed_y1, &vs_prop_[y_id], convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[z_id]))) TTL_CTR_V);
if (changed_y1) {
if (V_IS_EMPTY(vs_prop_[y_id])) {
*prop_ok = 0;
return;
}
}
}
if (V_MIN(vs_prop_[z_id]) > 0) {
cl_v_del_gt_m(&changed_y2, &vs_prop_[y_id], V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (changed_y2) {
if (V_IS_EMPTY(vs_prop_[y_id])) {
*prop_ok = 0;
return;
}
}
}
if (V_MAX(vs_prop_[y_id]) > 0) {
cl_v_del_lt_m(&changed_z1, &vs_prop_[z_id], convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[y_id]))) TTL_CTR_V);
if (changed_z1) {
if (V_IS_EMPTY(vs_prop_[z_id])) {
*prop_ok = 0;
return;
}
}
}
if (V_MIN(vs_prop_[y_id]) > 0) {
cl_v_del_gt_m(&changed_z2, &vs_prop_[z_id], V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[y_id]) TTL_CTR_V);
if (changed_z2) {
if (V_IS_EMPTY(vs_prop_[z_id])) {
*prop_ok = 0;
return;
}
}
}
if (changed_y1 || changed_y2) {
v_add_to_prop(vs_id_to_prop_, vs_prop_, y_id);
}
if (changed_z1 || changed_z2) {
v_add_to_prop(vs_id_to_prop_, vs_prop_, z_id);
}
#if CL_CS_IGNORE
if (V_N_VALS(vs_prop_[x_id]) == 1 && V_N_VALS(vs_prop_[y_id]) == 1 && V_N_VALS(vs_prop_[z_id]) == 1) {
cs_ignore[current_cs->c_id] = 1;
}
#endif
return;
}
if (prop_v_id == (unsigned int)y_id) {
cl_v_del_lt_m(&changed_x1, &vs_prop_[x_id], V_MIN(vs_prop_[y_id]) * V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (changed_x1) {
if (V_IS_EMPTY(vs_prop_[x_id])) {
*prop_ok = 0;
return;
}
}
cl_v_del_gt_m(&changed_x2, &vs_prop_[x_id], V_MAX(vs_prop_[y_id]) * V_MAX(vs_prop_[z_id]) TTL_CTR_V);
if (changed_x2) {
if (V_IS_EMPTY(vs_prop_[x_id])) {
*prop_ok = 0;
return;
}
}
if (V_MAX(vs_prop_[y_id]) > 0) {
cl_v_del_lt_m(&changed_z1, &vs_prop_[z_id], convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[y_id]))) TTL_CTR_V);
if (changed_z1) {
if (V_IS_EMPTY(vs_prop_[z_id])) {
*prop_ok = 0;
return;
}
}
}
if (V_MIN(vs_prop_[y_id]) > 0) {
cl_v_del_gt_m(&changed_z2, &vs_prop_[z_id], V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[y_id]) TTL_CTR_V);
if (changed_z2) {
if (V_IS_EMPTY(vs_prop_[z_id])) {
*prop_ok = 0;
return;
}
}
}
if (changed_x1 || changed_x2) {
v_add_to_prop(vs_id_to_prop_, vs_prop_, x_id);
}
if (changed_z1 || changed_z2) {
v_add_to_prop(vs_id_to_prop_, vs_prop_, z_id);
}
#if CL_CS_IGNORE
if (V_N_VALS(vs_prop_[x_id]) == 1 && V_N_VALS(vs_prop_[y_id]) == 1 && V_N_VALS(vs_prop_[z_id]) == 1) {
cs_ignore[current_cs->c_id] = 1;
}
#endif
return;
}
// prop_v_id == z_id
cl_v_del_lt_m(&changed_x1, &vs_prop_[x_id], V_MIN(vs_prop_[y_id]) * V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (changed_x1) {
if (V_IS_EMPTY(vs_prop_[x_id])) {
*prop_ok = 0;
return;
}
}
cl_v_del_gt_m(&changed_x2, &vs_prop_[x_id], V_MAX(vs_prop_[y_id]) * V_MAX(vs_prop_[z_id]) TTL_CTR_V);
if (changed_x2) {
if (V_IS_EMPTY(vs_prop_[x_id])) {
*prop_ok = 0;
return;
}
}
if (V_MAX(vs_prop_[z_id]) > 0) {
cl_v_del_lt_m(&changed_y1, &vs_prop_[y_id], convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[z_id]))) TTL_CTR_V);
if (changed_y1) {
if (V_IS_EMPTY(vs_prop_[y_id])) {
*prop_ok = 0;
return;
}
}
}
if (V_MIN(vs_prop_[z_id]) > 0) {
cl_v_del_gt_m(&changed_y2, &vs_prop_[y_id], V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (changed_y2) {
if (V_IS_EMPTY(vs_prop_[y_id])) {
*prop_ok = 0;
return;
}
}
}
if (changed_x1 || changed_x2) {
v_add_to_prop(vs_id_to_prop_, vs_prop_, x_id);
}
if (changed_y1 || changed_y2) {
v_add_to_prop(vs_id_to_prop_, vs_prop_, y_id);
}
#if CL_CS_IGNORE
if (V_N_VALS(vs_prop_[x_id]) == 1 && V_N_VALS(vs_prop_[y_id]) == 1 && V_N_VALS(vs_prop_[z_id]) == 1) {
cs_ignore[current_cs->c_id] = 1;
}
#endif
}
#ifndef __OPENCL_VERSION__
#if CS_IGNORE == 0
#pragma GCC diagnostic pop
#endif
#endif
#if CS_R_VAR_EQ_TIMES == 1
/*
* Validate var_eq_plus constraint to be normally propagated, when reified
* x = y * z
* vs_per_c_idx - vector with all constrained variables ID per constraint, per constraint ID order
* vs_prop_ - all CSP variables with current step values
* current_cs - constraint that should be propagated for the variable with prop_v_id ID
* vs_id_to_prop_ - circular vector with the ids of the variables to propagate
*/
CUDA_FUNC void var_eq_times_reif( CL_INTS_MEM int* vs_per_c_idx, CL_MEMORY VARS_PROP* vs_prop_, unsigned int prop_v_id, CL_CS_MEM cl_constr* current_cs,
CL_MEMORY unsigned short* vs_id_to_prop_ CS_IGNORE_FUNC TTL_CTR) {
int x_id = vs_per_c_idx[0];
int y_id = vs_per_c_idx[1];
int z_id = vs_per_c_idx[2];
bool changed = 0;
if (V_N_VALS(vs_prop_[x_id]) == 1 && V_N_VALS(vs_prop_[y_id]) == 1 && V_N_VALS(vs_prop_[z_id]) == 1
&& V_MIN(vs_prop_[x_id]) == V_MIN(vs_prop_[y_id]) * V_MIN(vs_prop_[z_id])) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 0 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
if (prop_v_id == (unsigned int)x_id) {
VARS_PROP y;
cl_v_copy_pm(&y, &vs_prop_[y_id] TTL_CTR_V);
if (V_MAX(vs_prop_[z_id]) > 0) {
cl_v_del_lt_n(&changed, &y, convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[z_id]))) TTL_CTR_V);
if (V_IS_EMPTY(y)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
}
if (V_MIN(vs_prop_[z_id]) > 0) {
cl_v_del_gt_n(&changed, &y, V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (V_IS_EMPTY(y)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
}
VARS_PROP z;
cl_v_copy_pm(&z, &vs_prop_[z_id] TTL_CTR_V);
if (V_MAX(vs_prop_[y_id]) > 0) {
cl_v_del_lt_n(&changed, &z, convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[y_id]))) TTL_CTR_V);
if (V_IS_EMPTY(z)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
}
if (V_MIN(vs_prop_[y_id]) > 0) {
cl_v_del_gt_n(&changed, &z, V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[y_id]) TTL_CTR_V);
if (V_IS_EMPTY(z)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
}
}
return;
}
if (prop_v_id == (unsigned int)y_id) {
VARS_PROP x;
cl_v_copy_pm(&x, &vs_prop_[x_id] TTL_CTR_V);
cl_v_del_lt_n(&changed, &x, V_MIN(vs_prop_[y_id]) * V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (V_IS_EMPTY(x)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
cl_v_del_gt_n(&changed, &x, V_MAX(vs_prop_[y_id]) * V_MAX(vs_prop_[z_id]) TTL_CTR_V);
if (V_IS_EMPTY(x)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
VARS_PROP z;
cl_v_copy_pm(&z, &vs_prop_[z_id] TTL_CTR_V);
if (V_MAX(vs_prop_[y_id]) > 0) {
cl_v_del_lt_n(&changed, &z, convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[y_id]))) TTL_CTR_V);
if (V_IS_EMPTY(z)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
}
if (V_MIN(vs_prop_[y_id]) > 0) {
cl_v_del_gt_n(&changed, &z, V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[y_id]) TTL_CTR_V);
if (V_IS_EMPTY(z)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
}
}
return;
}
// prop_v_id == z_id
VARS_PROP x;
cl_v_copy_pm(&x, &vs_prop_[x_id] TTL_CTR_V);
cl_v_del_lt_n(&changed, &x, V_MIN(vs_prop_[y_id]) * V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (V_IS_EMPTY(x)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
cl_v_del_gt_n(&changed, &x, V_MAX(vs_prop_[y_id]) * V_MAX(vs_prop_[z_id]) TTL_CTR_V);
if (V_IS_EMPTY(x)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
VARS_PROP y;
cl_v_copy_pm(&y, &vs_prop_[y_id] TTL_CTR_V);
if (V_MAX(vs_prop_[z_id]) > 0) {
cl_v_del_lt_n(&changed, &y, convert_int(ceil(V_MIN(vs_prop_[x_id]) * 1.0 / V_MAX(vs_prop_[z_id]))) TTL_CTR_V);
if (V_IS_EMPTY(y)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
}
if (V_MIN(vs_prop_[z_id]) > 0) {
cl_v_del_gt_n(&changed, &y, V_MAX(vs_prop_[x_id]) / V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (V_IS_EMPTY(y)) {
cl_v_bool_del_val_m(&vs_prop_[current_cs->reif_var_id], 1 TTL_CTR_V);
v_add_to_prop(vs_id_to_prop_, vs_prop_, convert_int(current_cs->reif_var_id));
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
return;
}
}
}
/*
* Propagate the domain of the variable with the ID prop_v_id through all the other variables on the same c_numb ID var_eq_times opposite constrain
* x != y * z
* vs_per_c_idx - vector with all constrained variables ID per constraint, per constraint ID order
* vs_prop_ - all CSP variables with current step values
* prop_v_id - variable ID to propagate
* current_cs - constraint that should be propagated for the variable with prop_v_id ID
* vs_id_to_prop_ - circular vector with the ids of the variables to propagate
*/
#ifndef __OPENCL_VERSION__
#if CS_IGNORE == 0
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
#endif
#endif
CUDA_FUNC void var_eq_times_prop_opposite ( CL_INTS_MEM int* vs_per_c_idx, CL_MEMORY VARS_PROP* vs_prop_, CL_CS_MEM cl_constr* current_cs,
bool* prop_ok CS_IGNORE_FUNC TTL_CTR) {
int x_id = vs_per_c_idx[0];
int y_id = vs_per_c_idx[1];
int z_id = vs_per_c_idx[2];
bool changed;
if (V_N_VALS(vs_prop_[x_id]) == 1 && V_N_VALS(vs_prop_[y_id]) == 1 && V_MIN(vs_prop_[x_id]) % V_MIN(vs_prop_[y_id]) == 0) {
cl_v_del_val_m(&changed, &vs_prop_[z_id], V_MIN(vs_prop_[x_id]) / V_MIN(vs_prop_[y_id]) TTL_CTR_V);
if (changed) {
if (V_IS_EMPTY(vs_prop_[z_id])) {
*prop_ok = 0;
return;
}
}
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
}
if (V_N_VALS(vs_prop_[x_id]) == 1 && V_N_VALS(vs_prop_[z_id]) == 1 && V_MIN(vs_prop_[x_id]) % V_MIN(vs_prop_[z_id]) == 0) {
cl_v_del_val_m(&changed, &vs_prop_[y_id], V_MIN(vs_prop_[x_id]) / V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (changed) {
if (V_IS_EMPTY(vs_prop_[y_id])) {
*prop_ok = 0;
return;
}
}
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
}
if (V_N_VALS(vs_prop_[y_id]) == 1 && V_N_VALS(vs_prop_[z_id]) == 1) {
cl_v_del_lt_m(&changed, &vs_prop_[x_id], V_MIN(vs_prop_[y_id]) * V_MIN(vs_prop_[z_id]) TTL_CTR_V);
if (changed) {
if (V_IS_EMPTY(vs_prop_[x_id])) {
*prop_ok = 0;
return;
}
}
#if CL_CS_IGNORE
cs_ignore[current_cs->c_id] = 1;
#endif
}
}
#ifndef __OPENCL_VERSION__
#if CS_IGNORE == 0
#pragma GCC diagnostic pop
#endif
#endif
#endif
CUDA_FUNC void var_eq_times_propagate(CL_INTS_MEM int* vs_per_c_idx, CL_MEMORY VARS_PROP* vs_prop_, unsigned int prop_v_id, CL_CS_MEM cl_constr* current_cs,
CL_MEMORY unsigned short* vs_id_to_prop_, bool* prop_ok PROPAGATED_FUNC CS_IGNORE_FUNC TTL_CTR) {
#if CS_R_VAR_EQ_TIMES == 0
var_eq_times_prop(vs_per_c_idx, vs_prop_, prop_v_id, current_cs, vs_id_to_prop_, prop_ok CS_IGNORE_CALL TTL_CTR_V);
#if CL_STATS == 1
*propagated = true;
#endif
#elif CS_R_VAR_EQ_TIMES == 1
if (current_cs->reified == 1) {
if (prop_v_id != current_cs->reif_var_id) {
if (V_N_VALS(vs_prop_[current_cs->reif_var_id]) > 1) {
var_eq_times_reif(vs_per_c_idx, vs_prop_, prop_v_id, current_cs, vs_id_to_prop_ CS_IGNORE_CALL TTL_CTR_V);
} else {
if (V_MIN(vs_prop_[current_cs->reif_var_id]) == 1) {
var_eq_times_prop(vs_per_c_idx, vs_prop_, prop_v_id, current_cs, vs_id_to_prop_, prop_ok CS_IGNORE_CALL TTL_CTR_V);
} else {
var_eq_times_prop_opposite(vs_per_c_idx, vs_prop_, current_cs, prop_ok CS_IGNORE_CALL TTL_CTR_V);
}
#if CL_STATS == 1
*propagated = true;
#endif
}
}
} else {
var_eq_times_prop(vs_per_c_idx, vs_prop_, prop_v_id, current_cs, vs_id_to_prop_, prop_ok CS_IGNORE_CALL TTL_CTR_V);
#if CL_STATS == 1
*propagated = true;
#endif
}
#endif
}
#endif