#include "list.h"
#include "bitset.h"
#include "iterator.h"
+#include "bipartite.h"
#include "irmode_t.h"
#include "irgraph_t.h"
#include "belive_t.h"
#include "benode_t.h"
#include "bearch.h"
+#include "beirgmod.h"
#include "beifg.h"
+#include "beinsn_t.h"
#include "bechordal_t.h"
#include "bechordal_draw.h"
#define NO_COLOR (-1)
-#undef DUMP_INTERVALS
+#define MAX(x, y) ((x) > (y) ? (x) : (y))
+#define MIN(x, y) ((x) < (y) ? (x) : (y))
+
+#define DUMP_INTERVALS
typedef struct _be_chordal_alloc_env_t {
be_chordal_env_t *chordal_env;
- pset *pre_colored; /**< Set of precolored nodes. */
- bitset_t *live; /**< A liveness bitset. */
- bitset_t *colors; /**< The color mask. */
- bitset_t *in_colors; /**< Colors used by live in values. */
- int colors_n; /**< The number of colors. */
+ pset *pre_colored; /**< Set of precolored nodes. */
+ bitset_t *live; /**< A liveness bitset. */
+ bitset_t *tmp_colors; /**< An auxiliary bitset which is as long as the number of colors in the class. */
+ bitset_t *colors; /**< The color mask. */
+ bitset_t *in_colors; /**< Colors used by live in values. */
+ int colors_n; /**< The number of colors. */
+ DEBUG_ONLY(firm_dbg_module_t *constr_dbg;) /**< Debug output for the constraint handler. */
} be_chordal_alloc_env_t;
#include "fourcc.h"
*/
static INLINE int has_reg_class(const be_chordal_env_t *env, const ir_node *irn)
{
- return arch_irn_has_reg_class(env->main_env->arch_env, irn, -1, env->cls);
+ // return arch_irn_has_reg_class(env->main_env->arch_env, irn, -1, env->cls);
+ return arch_irn_consider_in_reg_alloc(env->birg->main_env->arch_env, env->cls, irn);
}
#define has_limited_constr(req, irn) \
(arch_get_register_req(arch_env, (req), irn, -1) && (req)->type == arch_register_req_type_limited)
-static int try_pre_color(be_chordal_env_t *env, ir_node *irn,
- pset *pre_colored, bitset_t *colors_used)
+static int get_next_free_reg(const be_chordal_alloc_env_t *alloc_env, bitset_t *colors)
{
- arch_register_req_t req;
+ bitset_t *tmp = alloc_env->tmp_colors;
+ bitset_copy(tmp, colors);
+ bitset_or(tmp, alloc_env->chordal_env->ignore_colors);
+ return bitset_next_clear(tmp, 0);
+}
- if(arch_get_register_req(env->main_env->arch_env, &req, irn, -1) && arch_register_req_is(&req, limited)) {
+static bitset_t *get_decisive_partner_regs(bitset_t *bs, const be_operand_t *o1, const be_operand_t *o2)
+{
+ bitset_t *res = bs;
- bitset_t *bs = bitset_alloca(env->cls->n_regs);
- const arch_register_t *reg;
- int col;
+ if(!o1) {
+ bitset_copy(bs, o2->regs);
+ return bs;
+ }
- req.limited(irn, -1, bs);
- col = bitset_next_set(bs, 0);
- reg = arch_register_for_index(env->cls, col);
+ if(!o2) {
+ bitset_copy(bs, o1->regs);
+ return bs;
+ }
- pset_insert_ptr(pre_colored, irn);
- arch_set_irn_register(env->main_env->arch_env, irn, reg);
+ assert(o1->req.cls == o2->req.cls);
- bitset_set(colors_used, col);
+ if(bitset_contains(o1->regs, o2->regs))
+ bitset_copy(bs, o1->regs);
+ else if(bitset_contains(o2->regs, o1->regs))
+ bitset_copy(bs, o2->regs);
+ else
+ res = NULL;
- DBG((env->dbg, LEVEL_2, "pre coloring %+F with %s\n", irn, reg->name));
+ return res;
+}
+
+static be_insn_t *chordal_scan_insn(be_chordal_alloc_env_t *env, ir_node *irn)
+{
+ be_insn_env_t ie;
+
+ ie.ignore_colors = env->chordal_env->ignore_colors;
+ ie.aenv = env->chordal_env->birg->main_env->arch_env;
+ ie.obst = &env->chordal_env->obst;
+ ie.cls = env->chordal_env->cls;
+ return be_scan_insn(&ie, irn);
+}
+
+static void pair_up_operands(const be_chordal_alloc_env_t *alloc_env, be_insn_t *insn)
+{
+ const be_chordal_env_t *env = alloc_env->chordal_env;
- return 1;
+ int n_uses = be_insn_n_uses(insn);
+ int n_defs = be_insn_n_defs(insn);
+ bitset_t *bs = bitset_alloca(env->cls->n_regs);
+ bipartite_t *bp = bipartite_new(n_defs, n_uses);
+ int *pairing = alloca(MAX(n_defs, n_uses) * sizeof(pairing[0]));
+
+ int i, j;
+
+ /*
+ For each out operand, try to find an in operand which can be assigned the
+ same register as the out operand.
+ */
+ for(j = 0; j < insn->use_start; ++j) {
+ be_operand_t *out_op = &insn->ops[j];
+
+ /* Try to find an in operand which has ... */
+ for(i = insn->use_start; i < insn->n_ops; ++i) {
+ const be_operand_t *op = &insn->ops[i];
+
+ /*
+ The in operand can only be paired with a def, if the node defining the
+ operand's value does not interfere with the instruction itself. That
+ would mean, that it is live at the instruction, so no result of the instruction
+ can have the same register as the operand.
+
+ Furthermore, tow operands can be paired, if the admissible registers
+ of one are a subset of the other's. We record the operand whose constraints
+ count in the decisive array.
+ */
+ if(!values_interfere(op->irn, op->carrier)) {
+ if(get_decisive_partner_regs(bs, out_op, op))
+ bipartite_add(bp, j, i - insn->use_start);
+ }
+ }
+ }
+
+ /* Compute the pairing. */
+ bipartite_matching(bp, pairing);
+ for(i = 0; i < insn->use_start; ++i) {
+ int p = pairing[i] + insn->use_start;
+
+ if(p >= insn->use_start) {
+ insn->ops[i].partner = &insn->ops[p];
+ insn->ops[p].partner = &insn->ops[i];
+ }
}
- return 0;
+ bipartite_free(bp);
}
-/**
- * Handle register targeting constraints signaled by a Perm.
- * @param alloc_env Private data for the allocation phase.
- * @param perm The Perm node guarding the constrained node.
- * @return The constrained node.
-
- Pro-coloring works as follows:
-
- +-----------------------------------+
- | Perm |
- +---.-------.--------.---------.----+
- | | | |
- +---+--+ | | |
- | Proj | | | |
- +------+ | | |
- | | |
- +--+---+ | |
- | Proj | | |
- +--.---+ | |
- | | |
- | +--+---+ |
- | | Proj | |
- | +------+ |
- | |
- | +---+--+
- `-. | Proj | Result:
- `._ +---.--+ R1
- `. |
- `-. |
- `._ |
- +`.-+--+
- |Constr| Result:
- +------+ R2
-
- 1) Look at all Projs of the Perm if they have output constraints.
- If one has an output constraint, pre-color it, else record it
- in the set leftover. Its color has to be chosen after all
- constrained nodes are colored. Furthermore record all colors
- used in the pre-coloring in the set colors_used.
-
- 2) Look whether the first node not a Proj (this is the constrained
- node due to which the Perm has been inserted) has an output
- constraint. If yes, pre-color the node accordingly else do nothing
- since the node's input constraints are modelled by the Proj's
- output constraint.
-
- There's one subtle point here: If thenode has an output constraint
- and the live range of some Proj ends at that node, we must give
- that Proj the color of the constrained node. Otherwise the
- available colors may not suffice for the rest of the projs.
-
- 3) At last, color the Projs which have not been colored yet with the
- left over colors.
-
- So afterwards, everything including the constrained node will
- be colored and the assign() phase can complete this coloring.
- Note that therefore, we put the pre-colored nodes in a set
- called pre_colored().
- */
-static ir_node *handle_constraints_at_perm(be_chordal_alloc_env_t *alloc_env, ir_node *perm)
+static ir_node *pre_process_constraints(be_chordal_alloc_env_t *alloc_env, be_insn_t **the_insn)
{
- be_chordal_env_t *env = alloc_env->chordal_env;
- firm_dbg_module_t *dbg = env->dbg;
- const arch_env_t *arch_env = env->main_env->arch_env;
+ be_chordal_env_t *env = alloc_env->chordal_env;
+ const arch_env_t *aenv = env->birg->main_env->arch_env;
+ be_insn_t *insn = *the_insn;
+ ir_node *bl = get_nodes_block(insn->irn);
+ ir_node *copy = NULL;
+ ir_node *perm = NULL;
+ bitset_t *out_constr = bitset_alloca(env->cls->n_regs);
+ bitset_t *bs = bitset_alloca(env->cls->n_regs);
+ DEBUG_ONLY(firm_dbg_module_t *dbg = alloc_env->constr_dbg;)
- pset *leftover = pset_new_ptr(8);
- pset *pre_colored = pset_new_ptr(8);
- bitset_t *colors_used = bitset_alloca(env->cls->n_regs);
- ir_node *irn, *cnstr, *last;
- int has_cnstr = 0;
+ int i;
- assert(be_is_Perm(perm));
+ assert(insn->has_constraints && "only do this for constrained nodes");
- DBG((dbg, LEVEL_2, "Constraints on %+F\n", perm));
+ /*
+ Collect all registers that occur in output constraints.
+ This is necessary, since if the insn has one of these as an input constraint
+ and the corresponding operand interferes with the insn, the operand must
+ be copied.
+ */
+ for(i = 0; i < insn->use_start; ++i) {
+ be_operand_t *op = &insn->ops[i];
+ if(op->has_constraints)
+ bitset_or(out_constr, op->regs);
+ }
/*
- * Color constrained Projs first.
- */
- for(irn = sched_next(perm); is_Proj(irn); irn = sched_next(irn))
- if(!try_pre_color(env, irn, pre_colored, colors_used))
- pset_insert_ptr(leftover, irn);
+ Now, figure out which input operand must be copied since it has input
+ constraints which are also output constraints.
+ */
+ for(i = insn->use_start; i < insn->n_ops; ++i) {
+ be_operand_t *op = &insn->ops[i];
+ if(op->has_constraints && (values_interfere(op->carrier, insn->irn) || arch_irn_is(aenv, op->carrier, ignore))) {
+ bitset_copy(bs, op->regs);
+ bitset_and(bs, out_constr);
+
+ /*
+ The operand (interfering with the node) has input constraints
+ which also occur as output constraints, so insert a copy.
+ */
+ if(bitset_popcnt(bs) > 0) {
+ copy = be_new_Copy(op->req.cls, env->irg, bl, op->carrier);
+ op->carrier = copy;
+ sched_add_before(insn->irn, copy);
+ set_irn_n(insn->irn, op->pos, op->carrier);
+
+ DBG((dbg, LEVEL_2, "adding copy for interfering and constrained op %+F\n", op->carrier));
+ }
+ }
+ }
- cnstr = irn;
- last = irn;
+ /*
+ Make the Perm, recompute liveness and re-scan the insn since the
+ in operands are now the Projs of the Perm.
+ */
+ perm = insert_Perm_after(aenv, env->cls, env->dom_front, sched_prev(insn->irn));
+
+ /* Registers are propagated by insert_Perm_after(). Clean them here! */
+ if(perm) {
+ const ir_edge_t *edge;
+
+ foreach_out_edge(perm, edge) {
+ ir_node *proj = get_edge_src_irn(edge);
+ arch_set_irn_register(aenv, proj, NULL);
+ }
- if(get_irn_mode(cnstr) == mode_T) {
- for(irn = sched_next(cnstr); is_Proj(irn); irn = sched_next(irn))
- if(!try_pre_color(env, irn, pre_colored, colors_used))
- pset_insert_ptr(leftover, irn);
+ /*
+ We also have to re-build the insn since the input operands are now the Projs of
+ the Perm. Recomputing liveness is also a good idea if a Perm is inserted, since
+ the live sets may change.
+ */
+ be_liveness(env->irg);
+ obstack_free(&env->obst, insn);
+ *the_insn = insn = chordal_scan_insn(alloc_env, insn->irn);
- last = sched_prev(irn);
+ /*
+ Copy the input constraints of the insn to the Perm as output
+ constraints. Succeeding phases (coalescing will need that).
+ */
+ for(i = insn->use_start; i < insn->n_ops; ++i) {
+ be_operand_t *op = &insn->ops[i];
+ ir_node *proj = op->carrier;
+ /*
+ Note that the predecessor must not be a Proj of the Perm,
+ since ignore-nodes are not Perm'ed.
+ */
+ if(op->has_constraints && is_Proj(proj) && get_Proj_pred(proj) == perm) {
+ be_set_constr_limited(perm, BE_OUT_POS(get_Proj_proj(proj)), &op->req);
+ }
+ }
}
- else
- try_pre_color(env, cnstr, pre_colored, colors_used);
+ return perm;
+}
+
+static ir_node *handle_constraints(be_chordal_alloc_env_t *alloc_env, ir_node *irn, int *silent)
+{
+ be_chordal_env_t *env = alloc_env->chordal_env;
+ void *base = obstack_base(&env->obst);
+ be_insn_t *insn = chordal_scan_insn(alloc_env, irn);
+ ir_node *res = insn->next_insn;
+ int be_silent = *silent;
+
+ if(insn->pre_colored) {
+ int i;
+ for(i = 0; i < insn->use_start; ++i)
+ pset_insert_ptr(alloc_env->pre_colored, insn->ops[i].carrier);
+ }
- for(irn = pset_first(leftover); irn; irn = pset_next(leftover)) {
- const arch_register_t *reg;
- ir_node *precol;
- int colored = 0;
+ /*
+ If the current node is a barrier toggle the silent flag.
+ If we are in the start block, we are ought to be silent at the beginning,
+ so the toggling activates the constraint handling but skips the barrier.
+ If we are in the end block we handle the in requirements of the barrier
+ and set the rest to silent.
+ */
+ if(be_is_Barrier(irn))
+ *silent = !*silent;
+
+ if(be_silent)
+ goto end;
- for(precol = pset_first(pre_colored); precol; precol = pset_next(pre_colored)) {
- if(!values_interfere(irn, precol)) {
- reg = arch_get_irn_register(arch_env, irn);
- arch_set_irn_register(arch_env, irn, reg);
- pset_break(pre_colored);
- colored = 1;
- break;
+ /*
+ Perms inserted before the constraint handling phase are considered to be
+ correctly precolored. These Perms arise during the ABI handling phase.
+ */
+ if(insn->has_constraints) {
+ const arch_env_t *aenv = env->birg->main_env->arch_env;
+ int n_regs = env->cls->n_regs;
+ bitset_t *bs = bitset_alloca(n_regs);
+ ir_node **alloc_nodes = alloca(n_regs * sizeof(alloc_nodes[0]));
+ bipartite_t *bp = bipartite_new(n_regs, n_regs);
+ int *assignment = alloca(n_regs * sizeof(assignment[0]));
+ pmap *partners = pmap_create();
+ DEBUG_ONLY(firm_dbg_module_t *dbg = alloc_env->constr_dbg;)
+
+ int i, n_alloc;
+ long col;
+ const ir_edge_t *edge;
+ ir_node *perm = NULL;
+
+ /*
+ prepare the constraint handling of this node.
+ Perms are constructed and Copies are created for constrained values
+ interfering with the instruction.
+ */
+ perm = pre_process_constraints(alloc_env, &insn);
+
+ /* find suitable in operands to the out operands of the node. */
+ pair_up_operands(alloc_env, insn);
+
+ /*
+ look at the in/out operands and add each operand (and its possible partner)
+ to a bipartite graph (left: nodes with partners, right: admissible colors).
+ */
+ for(i = 0, n_alloc = 0; i < insn->n_ops; ++i) {
+ be_operand_t *op = &insn->ops[i];
+
+ /*
+ If the operand has no partner or the partner has not been marked
+ for allocation, determine the admissible registers and mark it
+ for allocation by associating the node and its partner with the
+ set of admissible registers via a bipartite graph.
+ */
+ if(!op->partner || !pmap_contains(partners, op->partner->carrier)) {
+
+ pmap_insert(partners, op->carrier, op->partner ? op->partner->carrier : NULL);
+ alloc_nodes[n_alloc] = op->carrier;
+
+ DBG((dbg, LEVEL_2, "\tassociating %+F and %+F\n", op->carrier, op->partner ? op->partner->carrier : NULL));
+
+ bitset_clear_all(bs);
+ get_decisive_partner_regs(bs, op, op->partner);
+
+ DBG((dbg, LEVEL_2, "\tallowed registers for %+F: %B\n", op->carrier, bs));
+
+ bitset_foreach(bs, col)
+ bipartite_add(bp, n_alloc, col);
+
+ n_alloc++;
}
}
- if(!colored) {
- int col = bitset_next_clear(colors_used, 0);
+ /*
+ Put all nodes which live by the constrained instruction also to the
+ allocation bipartite graph. They are considered unconstrained.
+ */
+ if(perm) {
+ foreach_out_edge(perm, edge) {
+ ir_node *proj = get_edge_src_irn(edge);
+
+ assert(is_Proj(proj));
+
+ if(values_interfere(proj, irn) && !pmap_contains(partners, proj)) {
+ assert(n_alloc < n_regs);
+ alloc_nodes[n_alloc] = proj;
+ pmap_insert(partners, proj, NULL);
+
+ bitset_clear_all(bs);
+ arch_put_non_ignore_regs(aenv, env->cls, bs);
+ bitset_foreach(bs, col)
+ bipartite_add(bp, n_alloc, col);
+
+ n_alloc++;
+ }
+ }
+ }
- assert(col >=0 && "There must be a register left");
- reg = arch_register_for_index(env->cls, col);
- arch_set_irn_register(arch_env, irn, reg);
- bitset_set(colors_used, reg->index);
- pset_insert_ptr(alloc_env->pre_colored, irn);
+ /* Compute a valid register allocation. */
+ bipartite_matching(bp, assignment);
- DBG((dbg, LEVEL_2, "coloring leftover %+F with %s\n", irn, reg->name));
+ /* Assign colors obtained from the matching. */
+ for(i = 0; i < n_alloc; ++i) {
+ const arch_register_t *reg;
+ ir_node *nodes[2];
+ int j;
+
+ assert(assignment[i] >= 0 && "there must have been a register assigned");
+ reg = arch_register_for_index(env->cls, assignment[i]);
+
+ nodes[0] = alloc_nodes[i];
+ nodes[1] = pmap_get(partners, alloc_nodes[i]);
+
+ for(j = 0; j < 2; ++j) {
+ if(!nodes[j])
+ continue;
+
+ arch_set_irn_register(aenv, nodes[j], reg);
+ pset_hinsert_ptr(alloc_env->pre_colored, nodes[j]);
+ DBG((dbg, LEVEL_2, "\tsetting %+F to register %s\n", nodes[j], reg->name));
+ }
}
- }
- pset_insert_pset_ptr(alloc_env->pre_colored, pre_colored);
- del_pset(leftover);
- del_pset(pre_colored);
+ /* Allocate the non-constrained Projs of the Perm. */
+ if(perm) {
+
+ bitset_clear_all(bs);
+
+ /* Put the colors of all Projs in a bitset. */
+ foreach_out_edge(perm, edge) {
+ ir_node *proj = get_edge_src_irn(edge);
+ const arch_register_t *reg = arch_get_irn_register(aenv, proj);
+
+ if(reg != NULL)
+ bitset_set(bs, reg->index);
+ }
+
+ /* Assign the not yet assigned Projs of the Perm a suitable color. */
+ foreach_out_edge(perm, edge) {
+ ir_node *proj = get_edge_src_irn(edge);
+ const arch_register_t *reg = arch_get_irn_register(aenv, proj);
+
+ DBG((dbg, LEVEL_2, "\tchecking reg of %+F: %s\n", proj, reg ? reg->name : "<none>"));
- return last;
+ if(reg == NULL) {
+ col = get_next_free_reg(alloc_env, bs);
+ reg = arch_register_for_index(env->cls, col);
+ bitset_set(bs, reg->index);
+ arch_set_irn_register(aenv, proj, reg);
+ pset_insert_ptr(alloc_env->pre_colored, proj);
+ DBG((dbg, LEVEL_2, "\tsetting %+F to register %s\n", proj, reg->name));
+ }
+ }
+ }
+
+ pmap_destroy(partners);
+ }
+
+end:
+ obstack_free(&env->obst, base);
+ return res;
}
/**
* Handle constraint nodes in each basic block.
- * be_insert_constr_perms() inserts Perm nodes which perm
+ * handle_constraints() inserts Perm nodes which perm
* over all values live at the constrained node right in front
* of the constrained node. These Perms signal a constrained node.
- * For further comments, refer to handle_constraints_at_perm().
+ * For further comments, refer to handle_constraints().
*/
static void constraints(ir_node *bl, void *data)
{
be_chordal_alloc_env_t *env = data;
- arch_env_t *arch_env = env->chordal_env->main_env->arch_env;
+
+ /*
+ Start silent in the start block.
+ The silence remains until the first barrier is seen.
+ Each other block is begun loud.
+ */
+ int silent = bl == get_irg_start_block(get_irn_irg(bl));
ir_node *irn;
- for(irn = sched_first(bl); !sched_is_end(irn); irn = sched_next(irn)) {
- if(be_is_Perm(irn) && arch_irn_has_reg_class(arch_env, irn, 0, env->chordal_env->cls))
- irn = handle_constraints_at_perm(env, irn);
+ /*
+ If the block is the start block search the barrier and
+ start handling constraints from there.
+ */
+
+ for(irn = sched_first(bl); !sched_is_end(irn);) {
+ irn = handle_constraints(env, irn, &silent);
}
}
be_chordal_alloc_env_t *alloc_env = env_ptr;
be_chordal_env_t *env = alloc_env->chordal_env;
bitset_t *live = alloc_env->live;
- firm_dbg_module_t *dbg = env->dbg;
ir_node *irn;
+ DEBUG_ONLY(firm_dbg_module_t *dbg = env->dbg;)
int i, n;
unsigned step = 0;
* Make final uses of all values live out of the block.
* They are necessary to build up real intervals.
*/
- for(irn = pset_first(live_end); irn; irn = pset_next(live_end)) {
+ foreach_pset(live_end, irn) {
if(has_reg_class(env, irn)) {
DBG((dbg, LEVEL_3, "\tMaking live: %+F/%d\n", irn, get_irn_graph_nr(irn)));
bitset_set(live, get_irn_graph_nr(irn));
/*
* Add initial defs for all values live in.
*/
- for(irn = pset_first(live_in); irn; irn = pset_next(live_in)) {
+ foreach_pset(live_in, irn) {
if(has_reg_class(env, irn)) {
/* Mark the value live in. */
}
}
-
- del_pset(live_in);
- del_pset(live_end);
+ del_pset(live_in);
+ del_pset(live_end);
}
static void assign(ir_node *block, void *env_ptr)
{
be_chordal_alloc_env_t *alloc_env = env_ptr;
be_chordal_env_t *env = alloc_env->chordal_env;
- firm_dbg_module_t *dbg = env->dbg;
bitset_t *live = alloc_env->live;
bitset_t *colors = alloc_env->colors;
bitset_t *in_colors = alloc_env->in_colors;
- const arch_env_t *arch_env = env->main_env->arch_env;
+ const arch_env_t *arch_env = env->birg->main_env->arch_env;
+ DEBUG_ONLY(firm_dbg_module_t *dbg = env->dbg;)
const ir_node *irn;
border_t *b;
struct list_head *head = get_block_border_head(env, block);
pset *live_in = put_live_in(block, pset_new_ptr_default());
- bitset_clear_all(live);
bitset_clear_all(colors);
+ bitset_clear_all(live);
bitset_clear_all(in_colors);
DBG((dbg, LEVEL_4, "Assigning colors for block %+F\n", block));
* Since their colors have already been assigned (The dominators were
* allocated before), we have to mark their colors as used also.
*/
- for(irn = pset_first(live_in); irn; irn = pset_next(live_in)) {
+ foreach_pset(live_in, irn) {
if(has_reg_class(env, irn)) {
const arch_register_t *reg = arch_get_irn_register(arch_env, irn);
int col;
}
/*
- * Mind that the sequence of defs from back to front defines a perfect
+ * Mind that the sequence
+ * of defs from back to front defines a perfect
* elimination order. So, coloring the definitions from first to last
* will work.
*/
const arch_register_t *reg;
int col = NO_COLOR;
- DBG((dbg, LEVEL_4, "\tcolors in use: %b\n", colors));
-
if(pset_find_ptr(alloc_env->pre_colored, irn)) {
reg = arch_get_irn_register(arch_env, irn);
col = reg->index;
}
else {
- col = bitset_next_clear(colors, 0);
+ col = get_next_free_reg(alloc_env, colors);
reg = arch_register_for_index(env->cls, col);
assert(arch_get_irn_register(arch_env, irn) == NULL && "This node must not have been assigned a register yet");
+ assert(!arch_register_type_is(reg, ignore) && "Must not assign ignore register");
}
bitset_set(colors, col);
arch_set_irn_register(arch_env, irn, reg);
DBG((dbg, LEVEL_1, "\tassigning register %s(%d) to %+F\n",
- arch_register_get_name(reg), col, irn));
+ arch_register_get_name(reg), col, irn));
assert(!bitset_is_set(live, nr) && "Value's definition must not have been encountered");
bitset_set(live, nr);
void be_ra_chordal_color(be_chordal_env_t *chordal_env)
{
- int node_count = get_graph_node_count(chordal_env->irg);
+ be_chordal_alloc_env_t env;
+ char buf[256];
+
int colors_n = arch_register_class_n_regs(chordal_env->cls);
ir_graph *irg = chordal_env->irg;
- be_chordal_alloc_env_t env;
if(get_irg_dom_state(irg) != dom_consistent)
compute_doms(irg);
- env.chordal_env = chordal_env;
- env.live = bitset_malloc(node_count);
- env.colors = bitset_malloc(colors_n);
- env.in_colors = bitset_malloc(colors_n);
- env.colors_n = colors_n;
- env.pre_colored = pset_new_ptr_default();
+ env.chordal_env = chordal_env;
+ env.colors_n = colors_n;
+ env.colors = bitset_alloca(colors_n);
+ env.tmp_colors = bitset_alloca(colors_n);
+ env.in_colors = bitset_alloca(colors_n);
+ env.pre_colored = pset_new_ptr_default();
+ FIRM_DBG_REGISTER(env.constr_dbg, "firm.be.chordal.constr");
+
/* Handle register targeting constraints */
dom_tree_walk_irg(irg, constraints, NULL, &env);
+ if(chordal_env->opts->dump_flags & BE_CH_DUMP_CONSTR) {
+ snprintf(buf, sizeof(buf), "-%s-constr", chordal_env->cls->name);
+ be_dump(chordal_env->irg, buf, dump_ir_block_graph_sched);
+ }
+
+ be_numbering(irg);
+ env.live = bitset_malloc(get_graph_node_count(chordal_env->irg));
+
/* First, determine the pressure */
dom_tree_walk_irg(irg, pressure, NULL, &env);
/* Assign the colors */
dom_tree_walk_irg(irg, assign, NULL, &env);
-#ifdef DUMP_INTERVALS
- {
- char buf[128];
- plotter_t *plotter;
+ be_numbering_done(irg);
- ir_snprintf(buf, sizeof(buf), "ifg_%s_%F.eps", cls->name, irg);
- plotter = new_plotter_ps(buf);
-
- draw_interval_tree(&draw_chordal_def_opts, chordal_env, plotter, env->arch_env, cls);
- plotter_free(plotter);
+ if(chordal_env->opts->dump_flags & BE_CH_DUMP_TREE_INTV) {
+ plotter_t *plotter;
+ ir_snprintf(buf, sizeof(buf), "ifg_%s_%F.eps", chordal_env->cls->name, irg);
+ plotter = new_plotter_ps(buf);
+ draw_interval_tree(&draw_chordal_def_opts, chordal_env, plotter);
+ plotter_free(plotter);
}
-#endif
-
- free(env.live);
- free(env.colors);
- free(env.in_colors);
del_pset(env.pre_colored);
}