/**
- * Minimizing copies with an exact algorithm using mixed integer programming (MIP).
- * Problem statement as a 'quadratic 0-1 program with linear constraints' with
- * n binary variables. Constraints are knapsack (enforce color for each node) and
- * cliques of ifg (interference constraints).
- * Transformation into a 'mixed integer program' with n binary variables and
- * additional 2n real variables. Constraints are the above the transformed
- * objective function and 'complementary conditions' for two var classes.
- * @author Daniel Grund
+ * Author: Daniel Grund
+ * Date: 28.02.2006
+ * Copyright: (c) Universitaet Karlsruhe
+ * Licence: This file protected by GPL - GNU GENERAL PUBLIC LICENSE.
+ * $Id$
+ *
+ * Common stuff used by all ILP fomulations.
*
- * NOTE: Unfortunately no good solver is available locally (or even for linking)
- * We use CPLEX 9.0 which runs on a machine residing at the Rechenzentrum.
- * @date 12.04.2005
*/
-#include "becopyopt.h"
-#include "becopystat.h"
+#ifdef HAVE_CONFIG_H
+#include "config.h"
+#endif
-#undef DUMP_MATRICES /**< dumps all matrices completely. only recommended for small problems */
-#define DUMP_MILP /**< dumps the problem as Mixed Integer Linear Programming in "CPLEX"-MPS format. NOT fixed-column-MPS. */
-#undef DO_SOLVE /**< solve the MPS output with CPLEX */
-#undef DELETE_FILES /**< deletes all dumped files after use */
+#ifdef WITH_ILP
-/* CPLEX-account related stuff */
-#define SSH_USER_HOST "kb61@sp-smp.rz.uni-karlsruhe.de"
-#define SSH_PASSWD_FILE "/ben/daniel/.smppw"
-#define EXPECT_FILENAME "runme" /** name of the expect-script */
+#include "becopyilp_t.h"
+#include "beifg_t.h"
-#define DEBUG_LVL 0 //SET_LEVEL_1
-static firm_dbg_module_t *dbg = NULL;
+/******************************************************************************
+ _____ _ _ _ _
+ / ____(_) | | | | (_)
+ | (___ _ _______ _ __ ___ __| |_ _ ___| |_ _ ___ _ __
+ \___ \| |_ / _ \ | '__/ _ \/ _` | | | |/ __| __| |/ _ \| '_ \
+ ____) | |/ / __/ | | | __/ (_| | |_| | (__| |_| | (_) | | | |
+ |_____/|_/___\___| |_| \___|\__,_|\__,_|\___|\__|_|\___/|_| |_|
-#define SLOTS_NUM2POS 256
-#define SLOTS_LIVING 32
+ *****************************************************************************/
-/* get_weight represents the _gain_ if node n and m have the same color. */
-#define get_weight(n,m) 1
-/**
- * A type storing names of the x variables in the form x[NUMBER]_[COLOR]
- */
-typedef struct _x_name_t {
- int n, c;
-} x_name_t;
+size_red_t *new_size_red(copy_opt_t *co) {
+ size_red_t *res = malloc(sizeof(*res));
-/**
- * For each node taking part in the opt-problem its position in the
- * x-variable-vector is stored in a set. This set maps the node-nr (given by
- * benumb) to the position in the vector.
- */
-typedef struct _num2pos_t {
- int num, pos;
-} num2pos_t;
+ res->co = co;
+ res->all_removed = pset_new_ptr_default();
+ res->col_suff = NULL;
+ obstack_init(&res->ob);
-/**
- * A type storing the unmodified '0-1 quadratic program' of the form
- * min f = xQx
- * udN: Ax = e
- * Bx <= e
- * x \in {0, 1}
- *
- * This problem is called the original problem
- */
-typedef struct _problem_instance_t {
- const copy_opt_t *co; /** the original copy_opt problem */
- int x_dim, A_dim, B_dim; /**< number of: x variables (equals Q_dim), rows in A, rows in B */
- x_name_t *x; /**< stores the names of the x variables. all possible colors for a node are ordered and occupy consecutive entries. lives in obstack ob. */
- set *num2pos; /**< maps node numbers to positions in x. */
- sp_matrix_t *Q, *A, *B; /**< the (sparse) matrices of this problem */
-
- /* needed only for linearizations */
- int bigM, maxQij, minQij;
-
- /* overhead needed to build this */
- struct obstack ob;
- int curr_color;
- int curr_row;
-} problem_instance_t;
-
-/* Nodes have consecutive numbers so this hash shoud be fine */
-#define HASH_NUM(num) num
-
-static int set_cmp_num2pos(const void *x, const void *y, size_t size) {
- return ((num2pos_t *)x)->num != ((num2pos_t *)y)->num;
+ return res;
}
/**
- * Sets the first position of node with number num to pos.
- * See x_name_t *x in _problem_instance_t.
+ * Checks if a node is simplicial in the graph heeding the already removed nodes.
*/
-static INLINE void pi_set_first_pos(problem_instance_t *pi, int num, int pos) {
- num2pos_t find;
- find.num = num;
- find.pos = pos;
- set_insert(pi->num2pos, &find, sizeof(find), HASH_NUM(num));
-}
+static INLINE int sr_is_simplicial(size_red_t *sr, const ir_node *ifn) {
+ int i, o, size = 0;
+ ir_node **all, *curr;
+ be_ifg_t *ifg = sr->co->cenv->ifg;
+ void *iter = be_ifg_neighbours_iter_alloca(ifg);
-/**
- * Get position by number. (First possible color)
- * returns -1 if not found.
- */
-static INLINE int pi_get_first_pos(problem_instance_t *pi, int num) {
- num2pos_t find, *found;
- find.num = num;
- found = set_find(pi->num2pos, &find, sizeof(find), HASH_NUM(num));
- if (found) {
- assert(pi->x[found->pos].n == num && (found->pos == 0 || pi->x[found->pos-1].n != num) && "pi->num2pos is broken!");
- return found->pos;
- } else
- return -1;
-}
+ all = alloca(be_ifg_degree(ifg, ifn) * sizeof(*all));
-/**
- * Get position by number and color.
- * returns -1 if not found.
- */
-static INLINE int pi_get_pos(problem_instance_t *pi, int num, int col) {
- num2pos_t find, *found;
- find.num = num;
- int pos;
- found = set_find(pi->num2pos, &find, sizeof(find), HASH_NUM(num));
- if (!found)
- return -1;
- pos = found->pos;
- while (pos < pi->x_dim && pi->x[pos].n == num && pi->x[pos].c < col)
- pos++;
-
- if (pi->x[pos].n == num && pi->x[pos].c == col)
- return pos;
- else
- return -1;
-}
+ /* get all non-removed neighbors */
+ be_ifg_foreach_neighbour(ifg, iter, ifn, curr)
+ if (!sr_is_removed(sr, curr))
+ all[size++] = curr;
-#ifdef DUMP_MATRICES
-/**
- * Dump the raw matrices of the problem to a file for debugging.
- */
-static void pi_dump_matrices(problem_instance_t *pi) {
- int i;
- FILE *out = ffopen(pi->co->name, "matrix", "wt");
+ /* check if these form a clique */
+ for (i=0; i<size; ++i)
+ for (o=i+1; o<size; ++o)
+ if (!be_ifg_connected(ifg, all[i], all[o]))
+ return 0;
- DBG((dbg, LEVEL_1, "Dumping raw...\n"));
- fprintf(out, "\n\nx-names =\n");
- for (i=0; i<pi->x_dim; ++i)
- fprintf(out, "%5d %2d\n", pi->x[i].n, pi->x[i].c);
+ /* all edges exist so this is a clique */
+ return 1;
+}
- fprintf(out, "\n\n-Q =\n");
- matrix_dump(pi->Q, out, -1);
+void sr_remove(size_red_t *sr) {
+ ir_node *irn;
+ int redo = 1;
+ int n_nodes = 0;
+ const be_ifg_t *ifg = sr->co->cenv->ifg;
+ void *iter = be_ifg_neighbours_iter_alloca(ifg);
- fprintf(out, "\n\nA =\n");
- matrix_dump(pi->A, out, 1);
+ while (redo) {
+ redo = 0;
+ be_ifg_foreach_node(ifg, iter, irn) {
+ if (!sr_is_removed(sr, irn) && !co_is_optimizable_root(sr->co, irn) && !co_is_optimizable_arg(sr->co, irn)) {
+ if (sr_is_simplicial(sr, irn)) {
+ coloring_suffix_t *cs = obstack_alloc(&sr->ob, sizeof(*cs));
- fprintf(out, "\n\nB =\n");
- matrix_dump(pi->B, out, 1);
+ cs->irn = irn;
+ cs->next = sr->col_suff;
+ sr->col_suff = cs;
- fclose(out);
-}
-#endif
+ pset_insert_ptr(sr->all_removed, irn);
-#ifdef DUMP_MILP
-/**
- * Dumps an mps file representing the problem. This is NOT the old-style,
- * fixed-column format. Some white spaces are important, in general spaces
- * are separators, MARKER-lines are used in COLUMN section to define binaries.
- */
-//BETTER use last 2 fields in COLUMNS section. See MPS docu for details
-static void pi_dump_milp(problem_instance_t *pi) {
- int i, max_abs_Qij;
- const matrix_elem_t *e;
- FILE *out = ffopen(pi->co->name, "milp", "wt");
-
- DBG((dbg, LEVEL_1, "Dumping milp...\n"));
- max_abs_Qij = pi->maxQij;
- if (-pi->minQij > max_abs_Qij)
- max_abs_Qij = -pi->minQij;
- pi->bigM = pi->A_dim * max_abs_Qij;
- DBG((dbg, LEVEL_2, "BigM = %d\n", pi->bigM));
-
- matrix_optimize(pi->Q);
- bitset_t *good_row = bitset_alloca(pi->x_dim);
- for (i=0; i<pi->x_dim; ++i)
- if (matrix_row_first(pi->Q, i))
- bitset_set(good_row, i);
-
- fprintf(out, "NAME %s\n", pi->co->name);
-
- fprintf(out, "ROWS\n");
- fprintf(out, " N obj\n");
- for (i=0; i<pi->x_dim; ++i)
- if (bitset_is_set(good_row, i))
- fprintf(out, " E cQ%d\n", i);
- for (i=0; i<pi->A_dim; ++i)
- fprintf(out, " E cA%d\n", i);
- for (i=0; i<pi->B_dim; ++i)
- fprintf(out, " L cB%d\n", i);
- for (i=0; i<pi->x_dim; ++i)
- if (bitset_is_set(good_row, i))
- fprintf(out, " L cy%d\n", i);
-
- fprintf(out, "COLUMNS\n");
- /* the x vars come first */
- /* mark them as binaries */
- fprintf(out, " MARKI0\t'MARKER'\t'INTORG'\n");
- for (i=0; i<pi->x_dim; ++i) {
- /* participation in objective */
- if (bitset_is_set(good_row, i))
- fprintf(out, " x%d_%d\tobj\t%d\n", pi->x[i].n, pi->x[i].c, -pi->bigM);
- /* in Q */
- matrix_foreach_in_col(pi->Q, i, e)
- fprintf(out, " x%d_%d\tcQ%d\t%d\n", pi->x[i].n, pi->x[i].c, e->row, e->val);
- /* in A */
- matrix_foreach_in_col(pi->A, i, e)
- fprintf(out, " x%d_%d\tcA%d\t%d\n", pi->x[i].n, pi->x[i].c, e->row, e->val);
- /* in B */
- matrix_foreach_in_col(pi->B, i, e)
- fprintf(out, " x%d_%d\tcB%d\t%d\n", pi->x[i].n, pi->x[i].c, e->row, e->val);
- /* in y */
- if (bitset_is_set(good_row, i))
- fprintf(out, " x%d_%d\tcy%d\t%d\n", pi->x[i].n, pi->x[i].c, i, 2*pi->bigM);
+ redo = 1;
+ }
+ }
+ }
}
+}
- fprintf(out, " MARKI1\t'MARKER'\t'INTEND'\n"); /* end of marking */
+void sr_reinsert(size_red_t *sr) {
+ coloring_suffix_t *cs;
+ be_ifg_t *ifg = sr->co->cenv->ifg;
+ bitset_t *used_cols = bitset_alloca(arch_register_class_n_regs(sr->co->cls));
+ void *iter = be_ifg_neighbours_iter_alloca(ifg);
- /* next the s vars */
- for (i=0; i<pi->x_dim; ++i)
- if (bitset_is_set(good_row, i)) {
- /* participation in objective */
- fprintf(out, " s%d_%d\tobj\t%d\n", pi->x[i].n, pi->x[i].c, 1);
- /* in Q */
- fprintf(out, " s%d_%d\tcQ%d\t%d\n", pi->x[i].n, pi->x[i].c, i, -1);
- }
+ /* color the removed nodes in right order */
+ for (cs = sr->col_suff; cs; cs = cs->next) {
+ int free_col;
+ ir_node *other, *irn;
- /* next the y vars */
- for (i=0; i<pi->x_dim; ++i)
- if (bitset_is_set(good_row, i)) {
- /* in Q */
- fprintf(out, " y%d_%d\tcQ%d\t%d\n", pi->x[i].n, pi->x[i].c, i, -1);
- /* in y */
- fprintf(out, " y%d_%d\tcy%d\t%d\n", pi->x[i].n, pi->x[i].c, i, 1);
- }
+ /* get free color by inspecting all neighbors */
+ irn = cs->irn;
+ bitset_clear_all(used_cols);
- fprintf(out, "RHS\n");
- for (i=0; i<pi->x_dim; ++i)
- if (bitset_is_set(good_row, i))
- fprintf(out, " rhs\tcQ%d\t%d\n", i, -pi->bigM);
- for (i=0; i<pi->A_dim; ++i)
- fprintf(out, " rhs\tcA%d\t%d\n", i, 1);
- for (i=0; i<pi->B_dim; ++i)
- fprintf(out, " rhs\tcB%d\t%d\n", i, 1);
- for (i=0; i<pi->x_dim; ++i)
- if (bitset_is_set(good_row, i))
- fprintf(out, " rhs\tcy%d\t%d\n", i, 2*pi->bigM);
-
- fprintf(out, "ENDATA\n");
- fclose(out);
-}
-#endif
+ be_ifg_foreach_neighbour(ifg, iter, irn, other) {
+ if (!sr_is_removed(sr, other)) /* only inspect nodes which are in graph right now */
+ bitset_set(used_cols, get_irn_col(sr->co, other));
+ }
-#ifdef DO_SOLVE
-/**
- * Dumps the known solution to a file to make use of it
- * as a starting solution respectively as a bound
- */
-static void pi_dump_start_sol(problem_instance_t *pi) {
- int i;
- FILE *out = ffopen(pi->co->name, "mst", "wt");
- fprintf(out, "NAME\n");
- for (i=0; i<pi->x_dim; ++i) {
- int val, n, c;
- n = pi->x[i].n;
- c = pi->x[i].c;
- if (get_irn_color(get_irn_for_graph_nr(pi->co->irg, n)) == c)
- val = 1;
- else
- val = 0;
- fprintf(out, " x%d_%d\t%d\n", n, c, val);
+ /* now all bits not set are possible colors */
+ free_col = bitset_next_clear(used_cols, 0);
+ assert(free_col != -1 && "No free color found. This can not be.");
+ set_irn_col(sr->co, irn, free_col);
+ pset_remove_ptr(sr->all_removed, irn); /* irn is back in graph again */
}
- fprintf(out, "ENDATA\n");
- fclose(out);
}
-/**
- * Invoke an external solver
- */
-static void pi_solve_ilp(problem_instance_t *pi) {
- FILE *out, *pwfile;
- char passwd[128];
-
- DBG((dbg, LEVEL_1, "Solving with CPLEX@RZ...\n"));
- /* write command file for CPLEX */
- out = ffopen(pi->co->name, "cmd", "wt");
- fprintf(out, "set logfile %s.sol\n", pi->co->name);
-#ifdef DUMP_MILP
- fprintf(out, "read %s.milp mps\n", pi->co->name);
-#endif
-#ifdef DUMP_MIQP
- fprintf(out, "read %s.miqp mps\n", pi->co->name);
-#endif
- fprintf(out, "read %s.mst\n", pi->co->name);
- fprintf(out, "set mip strategy mipstart 1\n");
- fprintf(out, "set mip emphasis 3\n");
- fprintf(out, "optimize\n");
- fprintf(out, "display solution variables 1-%d\n", pi->x_dim);
- fprintf(out, "set logfile cplex.log\n");
- fprintf(out, "quit\n");
- fclose(out);
-
- /* write expect-file for copying problem to RZ */
- pwfile = fopen(SSH_PASSWD_FILE, "rt");
- fgets(passwd, sizeof(passwd), pwfile);
- fclose(pwfile);
-
- out = ffopen(EXPECT_FILENAME, "exp", "wt");
- fprintf(out, "#! /usr/bin/expect\n");
- fprintf(out, "spawn scp %s.miqp %s.milp %s.mst %s.cmd %s:\n", pi->co->name, pi->co->name, pi->co->name, pi->co->name, SSH_USER_HOST); /* copy problem files */
- fprintf(out, "expect \"word:\"\nsend \"%s\\n\"\ninteract\n", passwd);
-
- fprintf(out, "spawn ssh %s \"./cplex90 < %s.cmd\"\n", SSH_USER_HOST, pi->co->name); /* solve */
- fprintf(out, "expect \"word:\"\nsend \"%s\\n\"\ninteract\n", passwd);
-
- fprintf(out, "spawn scp %s:%s.sol .\n", SSH_USER_HOST, pi->co->name); /*copy back solution */
- fprintf(out, "expect \"word:\"\nsend \"%s\\n\"\ninteract\n", passwd);
-
- fprintf(out, "spawn ssh %s ./dell\n", SSH_USER_HOST); /* clean files on server */
- fprintf(out, "expect \"word:\"\nsend \"%s\\n\"\ninteract\n", passwd);
- fclose(out);
-
- /* call the expect script */
- chmod(EXPECT_FILENAME ".exp", 0700);
- system(EXPECT_FILENAME ".exp");
+void free_size_red(size_red_t *sr) {
+ del_pset(sr->all_removed);
+ obstack_free(&sr->ob, NULL);
+ free(sr);
}
-/**
- * Sets the colors of irns according to the values of variables found in the
- * output file of the solver.
- */
-static void pi_apply_solution(problem_instance_t *pi) {
- FILE *in = ffopen(pi->co->name, "sol", "rt");
-
- if (!in)
- return;
- DBG((dbg, LEVEL_1, "Applying solution...\n"));
- while (!feof(in)) {
- char buf[1024];
- int num = -1, col = -1, val = -1;
-
- fgets(buf, sizeof(buf), in);
- DBG((dbg, LEVEL_3, "Line: %s", buf));
-
- if (strcmp(buf, "No integer feasible solution exists.") == 0)
- assert(0 && "CPLEX says: No integer feasible solution exists!");
-
- if (strcmp(buf, "TODO Out of memory") == 0) {}
-
-#ifdef DO_STAT
- {
- /* solution time */
- float sol_time;
- int iter;
- if (sscanf(buf, "Solution time = %f sec. Iterations = %d", &sol_time, &iter) == 2) {
- DBG((dbg, LEVEL_2, " Time: %f Iter: %d\n", sol_time, iter));
- curr_vals[I_ILP_TIME] += 10 * sol_time;
- curr_vals[I_ILP_ITER] += iter;
- }
- }
-#endif
+/******************************************************************************
+ _____ _ _____ _ _____
+ / ____| (_) |_ _| | | __ \
+ | | __ ___ _ __ ___ _ __ _ ___ | | | | | |__) |
+ | | |_ |/ _ \ '_ \ / _ \ '__| |/ __| | | | | | ___/
+ | |__| | __/ | | | __/ | | | (__ _| |_| |____| |
+ \_____|\___|_| |_|\___|_| |_|\___| |_____|______|_|
- /* variable value */
- if (sscanf(buf, "x%d_%d %d", &num, &col, &val) == 3 && val == 1) {
- DBG((dbg, LEVEL_2, " x%d_%d = %d\n", num, col, val));
- set_irn_color(get_irn_for_graph_nr(pi->co->irg, num), col);
- }
- }
- fclose(in);
-}
-#endif /* DO_SOLVE */
-
-#ifdef DELETE_FILES
-static void pi_delete_files(problem_instance_t *pi) {
- char buf[1024];
- int end = snprintf(buf, sizeof(buf), "%s", pi->co->name);
- DBG((dbg, LEVEL_1, "Deleting files...\n"));
-#ifdef DUMP_MATRICES
- snprintf(buf+end, sizeof(buf)-end, ".matrix");
- remove(buf);
-#endif
-#ifdef DUMP_MILP
- snprintf(buf+end, sizeof(buf)-end, ".mps");
- remove(buf);
- snprintf(buf+end, sizeof(buf)-end, ".mst");
- remove(buf);
- snprintf(buf+end, sizeof(buf)-end, ".cmd");
- remove(buf);
- remove(EXPECT_FILENAME ".exp");
-#endif
-#ifdef DO_SOLVE
- snprintf(buf+end, sizeof(buf)-end, ".sol");
- remove(buf);
-#endif
-}
-#endif
+ *****************************************************************************/
-/**
- * Collects all irns in currently processed register class
- */
-static void pi_collect_x_names(ir_node *block, void *env) {
- problem_instance_t *pi = env;
- struct list_head *head = &get_ra_block_info(block)->border_head;
- border_t *curr;
- bitset_t *pos_regs = bitset_alloca(pi->co->cls->n_regs);
-
- list_for_each_entry_reverse(border_t, curr, head, list)
- if (curr->is_def && curr->is_real) {
- x_name_t xx;
- pi->A_dim++; /* one knapsack constraint for each node */
-
- xx.n = get_irn_graph_nr(curr->irn);
- pi_set_first_pos(pi, xx.n, pi->x_dim);
-
- // iterate over all possible colors in order
- bitset_clear_all(pos_regs);
- pi->co->isa->get_allocatable_regs(curr->irn, pi->co->cls, pos_regs);
- bitset_foreach(pos_regs, xx.c) {
- DBG((dbg, LEVEL_2, "Adding %n %d\n", curr->irn, xx.c));
- obstack_grow(&pi->ob, &xx, sizeof(xx));
- pi->x_dim++; /* one x variable for each node and color */
- }
- }
-}
+ilp_env_t *new_ilp_env(copy_opt_t *co, ilp_callback build, ilp_callback apply, void *env) {
+ ilp_env_t *res = malloc(sizeof(*res));
+ assert(res);
-/**
- * Checks if all nodes in living are live_out in block block.
- */
-static INLINE int all_live_in(ir_node *block, pset *living) {
- ir_node *n;
- for (n = pset_first(living); n; n = pset_next(living))
- if (!is_live_in(block, n)) {
- pset_break(living);
- return 0;
- }
- return 1;
+ res->co = co;
+ res->build = build;
+ res->apply = apply;
+ res->env = env;
+ res->sr = new_size_red(co);
+
+ return res;
}
-/**
- * Finds cliques in the interference graph, considering only nodes
- * for which the color pi->curr_color is possible. Finds only 'maximal-cliques',
- * viz cliques which are not conatained in another one.
- * This is used for the matrix B.
- */
-static void pi_clique_finder(ir_node *block, void *env) {
- problem_instance_t *pi = env;
- enum phase_t {growing, shrinking} phase = growing;
- struct list_head *head = &get_ra_block_info(block)->border_head;
- border_t *b;
- pset *living = pset_new_ptr(SLOTS_LIVING);
-
- list_for_each_entry_reverse(border_t, b, head, list) {
- const ir_node *irn = b->irn;
-
- if (b->is_def) {
- DBG((dbg, LEVEL_2, "Def %n\n", irn));
- pset_insert_ptr(living, irn);
- phase = growing;
- } else { /* is_use */
- DBG((dbg, LEVEL_2, "Use %n\n", irn));
-
- /* before shrinking the set, store the current 'maximum' clique;
- * do NOT if clique is a single node
- * do NOT if all values are live_in (in this case they were contained in a live-out clique elsewhere) */
- if (phase == growing && pset_count(living) >= 2 && !all_live_in(block, living)) {
- ir_node *n;
- for (n = pset_first(living); n; n = pset_next(living)) {
- int pos = pi_get_pos(pi, get_irn_graph_nr(n), pi->curr_color);
- matrix_set(pi->B, pi->curr_row, pos, 1);
- DBG((dbg, LEVEL_2, "B[%d, %d] := %d\n", pi->curr_row, pos, 1));
- }
- pi->curr_row++;
- }
- pset_remove_ptr(living, irn);
- phase = shrinking;
- }
- }
+lpp_sol_state_t ilp_go(ilp_env_t *ienv) {
+ sr_remove(ienv->sr);
- del_pset(living);
-}
+ ienv->build(ienv);
-/**
- * Generate the initial problem matrices and vectors.
- */
-static problem_instance_t *new_pi(const copy_opt_t *co) {
- DBG((dbg, LEVEL_1, "Generating new instance...\n"));
- problem_instance_t *pi = calloc(1, sizeof(*pi));
- pi->co = co;
- pi->num2pos = new_set(set_cmp_num2pos, SLOTS_NUM2POS);
- pi->bigM = 1;
-
- /* Vector x
- * one entry per node and possible color */
- obstack_init(&pi->ob);
- dom_tree_walk_irg(co->irg, pi_collect_x_names, NULL, pi);
- pi->x = obstack_finish(&pi->ob);
-
- /* Matrix Q
- * weights for the 'same-color-optimization' target */
- {
- unit_t *curr;
- pi->Q = new_matrix(pi->x_dim, pi->x_dim);
-
- list_for_each_entry(unit_t, curr, &co->units, units) {
- const ir_node *root, *arg;
- int rootnr, argnr;
- unsigned rootpos, argpos;
- int i;
-
- root = curr->nodes[0];
- rootnr = get_irn_graph_nr(root);
- rootpos = pi_get_first_pos(pi, rootnr);
- for (i = 1; i < curr->node_count; ++i) {
- int weight = -get_weight(root, arg);
- arg = curr->nodes[i];
- argnr = get_irn_graph_nr(arg);
- argpos = pi_get_first_pos(pi, argnr);
-
- DBG((dbg, LEVEL_2, "Q[%n, %n] := %d\n", root, arg, weight));
- /* for all colors root and arg have in common, set the weight for
- * this pair in the objective function matrix Q */
- while (rootpos < pi->x_dim && argpos < pi->x_dim &&
- pi->x[rootpos].n == rootnr && pi->x[argpos].n == argnr) {
- if (pi->x[rootpos].c < pi->x[argpos].c)
- ++rootpos;
- else if (pi->x[rootpos].c > pi->x[argpos].c)
- ++argpos;
- else {
- matrix_set(pi->Q, rootpos++, argpos++, weight);
-
- if (weight < pi->minQij) {
- DBG((dbg, LEVEL_2, "minQij = %d\n", weight));
- pi->minQij = weight;
- }
- if (weight > pi->maxQij) {
- DBG((dbg, LEVEL_2, "maxQij = %d\n", weight));
- pi->maxQij = weight;
- }
- }
- }
- }
- }
- }
+#ifdef LPP_SOLVE_NET
+ lpp_solve_net(ienv->lp, LPP_HOST, LPP_SOLVER);
+#else
+ lpp_solve_cplex(ienv->lp);
+#endif
- /* Matrix A
- * knapsack constraint for each node */
- {
- int row = 0, col = 0;
- pi->A = new_matrix(pi->A_dim, pi->x_dim);
- while (col < pi->x_dim) {
- int curr_n = pi->x[col].n;
- while (col < pi->x_dim && pi->x[col].n == curr_n) {
- DBG((dbg, LEVEL_2, "A[%d, %d] := %d\n", row, col, 1));
- matrix_set(pi->A, row, col++, 1);
- }
- ++row;
- }
- assert(row == pi->A_dim);
- }
+ ienv->apply(ienv);
- /* Matrix B
- * interference constraints using exactly those cliques not contained in others. */
- {
- int color, expected_clipques = pi->A_dim/4 * pi->co->cls->n_regs;
- pi->B = new_matrix(expected_clipques, pi->x_dim);
- for (color = 0; color < pi->co->cls->n_regs; ++color) {
- pi->curr_color = color;
- dom_tree_walk_irg(pi->co->irg, pi_clique_finder, NULL, pi);
- }
- pi->B_dim = matrix_get_rowcount(pi->B);
- }
+ sr_reinsert(ienv->sr);
- return pi;
+ return lpp_get_sol_state(ienv->lp);
}
-/**
- * clean the problem instance
- */
-static void free_pi(problem_instance_t *pi) {
- DBG((dbg, LEVEL_1, "Generating new instance...\n"));
- del_matrix(pi->Q);
- del_matrix(pi->A);
- del_matrix(pi->B);
- del_set(pi->num2pos);
- obstack_free(&pi->ob, NULL);
- free(pi);
+void free_ilp_env(ilp_env_t *ienv) {
+ free_size_red(ienv->sr);
+ free_lpp(ienv->lp);
+ free(ienv);
}
-void co_ilp_opt(copy_opt_t *co) {
- dbg = firm_dbg_register("ir.be.copyoptilp");
- firm_dbg_set_mask(dbg, DEBUG_LVL);
- if (!strcmp(co->name, DEBUG_IRG))
- firm_dbg_set_mask(dbg, -1);
-
- problem_instance_t *pi = new_pi(co);
- DBG((dbg, 0, "\t\t\t %5d %5d %5d\n", pi->x_dim, pi->A_dim, pi->B_dim));
-
- if (pi->x_dim > 0) {
-#ifdef DUMP_MATRICES
- pi_dump_matrices(pi);
-#endif
-
-#ifdef DUMP_MILP
- pi_dump_milp(pi);
-#endif
+#else /* WITH_ILP */
-#ifdef DO_SOLVE
- pi_dump_start_sol(pi);
- pi_solve_ilp(pi);
- pi_apply_solution(pi);
-#endif
-
-#ifdef DELETE_FILES
- pi_delete_files(pi);
-#endif
- }
- free_pi(pi);
+static void only_that_you_can_compile_without_WITH_ILP_defined(void) {
}
+
+#endif /* WITH_ILP */