#include "mcg.h" #define MAX_CHILDREN 10 struct insn { struct ir* ir; struct hop* hop; const struct burm_instruction_data* insndata; int num_children; struct insn* children[MAX_CHILDREN]; }; static struct basicblock* current_bb; static struct hop* current_hop; static struct ir* current_ir; static struct insn* current_insn; static void emit(struct insn* insn); void burm_trace(struct burm_node* p, int ruleno, int cost, int bestcost) { const struct burm_instruction_data* insndata = &burm_instruction_data[ruleno]; //tracef('I', "I: 0x%p matched %s with cost %d vs. %d\n", p, // insndata->name, cost, bestcost); } void burm_panic_cannot_match(struct burm_node* node) { fprintf(stderr, "could not find any patterns to match:\n"); ir_print('!', node->ir); fprintf(stderr, "aborting!\n"); exit(1); } static void emit_return_reg(int index) { hop_add_vreg_insel(current_hop, current_hop->output, index); } static struct vreg* find_vreg_of_child(int child) { struct insn* insn = current_insn->children[child]; if (insn->hop) return insn->hop->output; else return insn->ir->result; } static void emit_reg(int child, int index) { struct vreg* vreg = find_vreg_of_child(child); if (vreg) { hop_add_vreg_insel(current_hop, vreg, index); array_appendu(&vreg->used, current_hop); } } static void emit_string(const char* data) { hop_add_string_insel(current_hop, data); } static void emit_fragment(int child) { emit(current_insn->children[child]); } static void emit_value(int child) { hop_add_value_insel(current_hop, current_insn->children[child]->ir); } static void emit_eoi(void) { hop_add_eoi_insel(current_hop); } static struct constraint* get_constraint(struct vreg* vreg) { struct constraint* c = pmap_findleft(¤t_hop->constraints, vreg); if (!c) { c = calloc(1, sizeof(*c)); pmap_put(¤t_hop->constraints, vreg, c); } return c; } static void constrain_input_reg(int child, uint32_t attr) { struct vreg* vreg = find_vreg_of_child(child); struct constraint* c; assert(vreg); array_appendu(¤t_hop->ins, vreg); get_constraint(vreg)->attrs = attr; } static void constrain_input_reg_preserved(int child) { struct vreg* vreg = find_vreg_of_child(child); struct constraint* c; assert(vreg); array_appendu(¤t_hop->throughs, vreg); get_constraint(vreg)->preserved = true; } static uint32_t find_type_from_constraint(uint32_t attr) { /* Looks through the registers and finds a concrete register implementing * that attribute, and returns the type. We assume that all registers * implementing an attribute (which anyone is going to ask for, 'volatile' * doesn't count) will have the same type. TODO: mcgg should check for * this. */ const struct burm_register_data* brd = burm_register_data; while (brd->id) { if (brd->attrs & attr) { const uint32_t type_attrs = (burm_int_ATTR | burm_float_ATTR | burm_long_ATTR | burm_double_ATTR); if (brd->attrs & type_attrs) return brd->attrs & type_attrs; return attr; } brd++; } fatal("unable to find a register matching attribute 0x%x", attr); return 0; } static void constrain_output_reg(uint32_t attr) { struct vreg* vreg = current_hop->output; if (!vreg) current_hop->output = vreg = new_vreg(); array_appendu(¤t_hop->outs, vreg); vreg->defined = current_hop; vreg->type = find_type_from_constraint(attr); get_constraint(vreg)->attrs = attr; } static void constrain_output_reg_equal_to(int child) { struct vreg* vreg = find_vreg_of_child(child); get_constraint(current_hop->output)->equals_to = vreg; } static const struct burm_emitter_data emitter_data = { &emit_string, &emit_fragment, &emit_return_reg, &emit_reg, &emit_value, &emit_eoi, &constrain_input_reg, &constrain_input_reg_preserved, &constrain_output_reg, &constrain_output_reg_equal_to, }; static void emit(struct insn* insn) { struct insn* old = current_insn; current_insn = insn; insn->insndata->emitter(&emitter_data); current_insn = old; } static struct insn* walk_instructions(struct burm_node* node, int goal) { struct insn* insn = calloc(1, sizeof(*insn)); int i; insn->ir = node->ir; insn->num_children = 0; if (goal) { int insn_no = burm_rule(node->state_label, goal); const short* nts = burm_nts[insn_no]; struct burm_node* children[MAX_CHILDREN] = {0}; insn->insndata = &burm_instruction_data[insn_no]; burm_kids(node, insn_no, children); i = 0; for (;;) { if (!children[i]) break; insn->children[i] = walk_instructions(children[i], nts[i]); insn->num_children++; i++; } tracef('I', "I: $%d goal %d %s selected %d: %s\n", node->ir->id, goal, insn->insndata->is_fragment ? "fragment" : "instruction", insn_no, insn->insndata->name); if (!insn->insndata->is_fragment) { insn->hop = current_hop = new_hop(current_bb, insn->ir); current_hop->insndata = insn->insndata; emit(insn); if (!current_hop->output) { switch (node->label) { case ir_to_esn(IR_REG, 0): current_hop->output = node->ir->result; assert(current_hop->output != NULL); break; case ir_to_esn(IR_NOP, 'I'): case ir_to_esn(IR_NOP, 'F'): case ir_to_esn(IR_NOP, 'L'): case ir_to_esn(IR_NOP, 'D'): current_hop->output = node->left->ir->result; assert(current_hop->output != NULL); break; } } hop_print('I', current_hop); array_append(¤t_bb->hops, current_hop); if ((goal != burm_stmt_NT) && !insn->ir->result) insn->ir->result = insn->hop->output; } } return insn; } static struct burm_node* build_shadow_tree(struct ir* root, struct ir* ir) { struct burm_node* node = calloc(1, sizeof(*node)); node->ir = ir; if (ir->root == root) { node->label = ir_to_esn(ir->opcode, ir->type); if (ir->left) node->left = build_shadow_tree(root, ir->left); if (ir->right) node->right = build_shadow_tree(root, ir->right); } else node->label = ir_to_esn(IR_REG, 0); return node; } static void select_instructions(void) { int i; tracef('I', "I: BLOCK: %s\n", current_bb->name); for (i=0; iirs.count; i++) { struct burm_node* shadow; int insnno; current_ir = current_bb->irs.item[i]; if (current_ir->opcode == IR_PHI) { int j; current_ir->result = new_vreg(); tracef('I', "I: $%d is phi:", current_ir->result->id); for (j=0; ju.phivalue.count; j++) { struct basicblock* parentbb = current_ir->u.phivalue.item[j].left; struct ir* parentir = current_ir->u.phivalue.item[j].right; struct phi* phi = calloc(1, sizeof(*phi)); tracef('I', " %s=>$%d", parentbb->name, parentir->id); phi->prev = parentbb; phi->ir = parentir; pmap_add(¤t_bb->phis, current_ir->result, phi); } tracef('I', "\n"); } else { ir_print('I', current_ir); shadow = build_shadow_tree(current_ir, current_ir); burm_label(shadow); insnno = burm_rule(shadow->state_label, 1); if (!insnno) burm_panic_cannot_match(shadow); walk_instructions(shadow, burm_stmt_NT); } } } void pass_instruction_selector(void) { int i; for (i=0; i