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gen_ir.c
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gen_ir.c
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#include "9cc.h"
// 9cc's code generation is two-pass. In the first pass, abstract
// syntax trees are compiled to IR (intermediate representation).
//
// IR resembles the real x86-64 instruction set, but it has infinite
// number of registers. We don't try too hard to reuse registers in
// this pass. Instead, we "kill" registers to mark them as dead when
// we are done with them and use new registers.
//
// Such infinite number of registers are mapped to a finite registers
// in a later pass.
static Function *fn;
static BB *out;
static int nreg = 1;
static BB *new_bb() {
BB *bb = calloc(1, sizeof(BB));
bb->label = nlabel++;
bb->ir = new_vec();
bb->succ = new_vec();
bb->pred = new_vec();
bb->def_regs = new_vec();
bb->in_regs = new_vec();
bb->out_regs = new_vec();
vec_push(fn->bbs, bb);
return bb;
}
static IR *new_ir(int op) {
IR *ir = calloc(1, sizeof(IR));
ir->op = op;
vec_push(out->ir, ir);
return ir;
}
Reg *new_reg() {
Reg *r = calloc(1, sizeof(Reg));
r->vn = nreg++;
r->rn = -1;
return r;
}
static IR *emit(int op, Reg *r0, Reg *r1, Reg *r2) {
IR *ir = new_ir(op);
ir->r0 = r0;
ir->r1 = r1;
ir->r2 = r2;
return ir;
}
static IR *br(Reg *r, BB *then, BB *els) {
IR *ir = new_ir(IR_BR);
ir->r2 = r;
ir->bb1 = then;
ir->bb2 = els;
return ir;
}
static IR *jmp(BB *bb) {
IR *ir = new_ir(IR_JMP);
ir->bb1 = bb;
return ir;
}
static IR *jmp_arg(BB *bb, Reg *r) {
IR *ir = new_ir(IR_JMP);
ir->bb1 = bb;
ir->bbarg = r;
return ir;
}
static Reg *imm(int imm) {
Reg *r = new_reg();
IR *ir = new_ir(IR_IMM);
ir->r0 = r;
ir->imm = imm;
return r;
}
static Reg *gen_expr(Node *node);
static void load(Node *node, Reg *dst, Reg *src) {
IR *ir = emit(IR_LOAD, dst, NULL, src);
ir->size = node->ty->size;
}
// In C, all expressions that can be written on the left-hand side of
// the '=' operator must have an address in memory. In other words, if
// you can apply the '&' operator to take an address of some
// expression E, you can assign E to a new value.
//
// Other expressions, such as `1+2`, cannot be written on the lhs of
// '=', since they are just temporary values that don't have an address.
//
// The stuff that can be written on the lhs of '=' is called lvalue.
// Other values are called rvalue. An lvalue is essentially an address.
//
// When lvalues appear on the rvalue context, they are converted to
// rvalues by loading their values from their addresses. You can think
// '&' as an operator that suppresses such automatic lvalue-to-rvalue
// conversion.
//
// This function evaluates a given node as an lvalue.
static Reg *gen_lval(Node *node) {
if (node->op == ND_DEREF)
return gen_expr(node->expr);
if (node->op == ND_DOT) {
Reg *r1 = new_reg();
Reg *r2 = gen_lval(node->expr);
Reg *r3 = imm(node->ty->offset);
emit(IR_ADD, r1, r2, r3);
return r1;
}
assert(node->op == ND_VARREF);
Var *var = node->var;
IR *ir;
if (var->is_local) {
ir = new_ir(IR_BPREL);
ir->r0 = new_reg();
ir->var = var;
} else {
ir = new_ir(IR_LABEL_ADDR);
ir->r0 = new_reg();
ir->name = var->name;
}
return ir->r0;
}
static Reg *gen_binop(int op, Node *node) {
Reg *r1 = new_reg();
Reg *r2 = gen_expr(node->lhs);
Reg *r3 = gen_expr(node->rhs);
emit(op, r1, r2, r3);
return r1;
}
static void gen_stmt(Node *node);
static Reg *gen_expr(Node *node) {
switch (node->op) {
case ND_NUM:
return imm(node->val);
case ND_EQ:
return gen_binop(IR_EQ, node);
case ND_NE:
return gen_binop(IR_NE, node);
case ND_LOGAND: {
BB *bb = new_bb();
BB *set0 = new_bb();
BB *set1 = new_bb();
BB *last = new_bb();
br(gen_expr(node->lhs), bb, set0);
out = bb;
br(gen_expr(node->rhs), set1, set0);
out = set0;
jmp_arg(last, imm(0));
out = set1;
jmp_arg(last, imm(1));
out = last;
out->param = new_reg();
return out->param;
}
case ND_LOGOR: {
BB *bb = new_bb();
BB *set0 = new_bb();
BB *set1 = new_bb();
BB *last = new_bb();
Reg *r1 = gen_expr(node->lhs);
br(r1, set1, bb);
out = bb;
Reg *r2 = gen_expr(node->rhs);
br(r2, set1, set0);
out = set0;
jmp_arg(last, imm(0));
out = set1;
jmp_arg(last, imm(1));
out = last;
out->param = new_reg();
return out->param;
}
case ND_VARREF:
case ND_DOT: {
Reg *r = new_reg();
load(node, r, gen_lval(node));
return r;
}
case ND_CALL: {
Reg *args[6];
for (int i = 0; i < node->args->len; i++)
args[i] = gen_expr(node->args->data[i]);
IR *ir = new_ir(IR_CALL);
ir->r0 = new_reg();
ir->name = node->name;
ir->nargs = node->args->len;
memcpy(ir->args, args, sizeof(args));
return ir->r0;
}
case ND_ADDR:
return gen_lval(node->expr);
case ND_DEREF: {
Reg *r = new_reg();
load(node, r, gen_expr(node->expr));
return r;
}
case ND_CAST: {
Reg *r1 = gen_expr(node->expr);
if (node->ty->ty != BOOL)
return r1;
Reg *r2 = new_reg();
emit(IR_NE, r2, r1, imm(0));
return r2;
}
case ND_STMT_EXPR:
for (int i = 0; i < node->stmts->len; i++)
gen_stmt(node->stmts->data[i]);
return gen_expr(node->expr);
case '=': {
Reg *r1 = gen_expr(node->rhs);
Reg *r2 = gen_lval(node->lhs);
IR *ir = emit(IR_STORE, NULL, r2, r1);
ir->size = node->ty->size;
return r1;
}
case '+':
return gen_binop(IR_ADD, node);
case '-':
return gen_binop(IR_SUB, node);
case '*':
return gen_binop(IR_MUL, node);
case '/':
return gen_binop(IR_DIV, node);
case '%':
return gen_binop(IR_MOD, node);
case '<':
return gen_binop(IR_LT, node);
case ND_LE:
return gen_binop(IR_LE, node);
case '&':
return gen_binop(IR_AND, node);
case '|':
return gen_binop(IR_OR, node);
case '^':
return gen_binop(IR_XOR, node);
case ND_SHL:
return gen_binop(IR_SHL, node);
case ND_SHR:
return gen_binop(IR_SHR, node);
case '~': {
Reg *r1 = new_reg();
Reg *r2 = gen_expr(node->expr);
emit(IR_XOR, r1, r2, imm(-1));
return r1;
}
case ',':
gen_expr(node->lhs);
return gen_expr(node->rhs);
case '?': {
BB *then = new_bb();
BB *els = new_bb();
BB *last = new_bb();
br(gen_expr(node->cond), then, els);
out = then;
jmp_arg(last, gen_expr(node->then));
out = els;
jmp_arg(last, gen_expr(node->els));
out = last;
out->param = new_reg();
return out->param;
}
case '!': {
Reg *r1 = new_reg();
Reg *r2 = gen_expr(node->expr);
emit(IR_EQ, r1, r2, imm(0));
return r1;
}
default:
assert(0 && "unknown AST type");
}
}
static void gen_stmt(Node *node) {
switch (node->op) {
case ND_NULL:
return;
case ND_IF: {
BB *then = new_bb();
BB *els = new_bb();
BB *last = new_bb();
br(gen_expr(node->cond), then, els);
out = then;
gen_stmt(node->then);
jmp(last);
out = els;
if (node->els)
gen_stmt(node->els);
jmp(last);
out = last;
return;
}
case ND_FOR: {
BB *cond = new_bb();
node->continue_ = new_bb();
BB *body = new_bb();
node->break_ = new_bb();
if (node->init)
gen_stmt(node->init);
jmp(cond);
out = cond;
if (node->cond) {
Reg *r = gen_expr(node->cond);
br(r, body, node->break_);
} else {
jmp(body);
}
out = body;
gen_stmt(node->body);
jmp(node->continue_);
out = node->continue_;
if (node->inc)
gen_expr(node->inc);
jmp(cond);
out = node->break_;
return;
}
case ND_DO_WHILE: {
node->continue_ = new_bb();
BB *body = new_bb();
node->break_ = new_bb();
jmp(body);
out = body;
gen_stmt(node->body);
jmp(node->continue_);
out = node->continue_;
Reg *r = gen_expr(node->cond);
br(r, body, node->break_);
out = node->break_;
return;
}
case ND_SWITCH: {
node->break_ = new_bb();
node->continue_ = new_bb();
Reg *r = gen_expr(node->cond);
for (int i = 0; i < node->cases->len; i++) {
Node *case_ = node->cases->data[i];
case_->bb = new_bb();
BB *next = new_bb();
Reg *r2 = new_reg();
emit(IR_EQ, r2, r, imm(case_->val));
br(r2, case_->bb, next);
out = next;
}
jmp(node->break_);
gen_stmt(node->body);
jmp(node->break_);
out = node->break_;
return;
}
case ND_CASE:
jmp(node->bb);
out = node->bb;
gen_stmt(node->body);
break;
case ND_BREAK:
jmp(node->target->break_);
out = new_bb();
break;
case ND_CONTINUE:
jmp(node->target->continue_);
out = new_bb();
break;
case ND_RETURN: {
Reg *r = gen_expr(node->expr);
IR *ir = new_ir(IR_RETURN);
ir->r2 = r;
out = new_bb();
return;
}
case ND_EXPR_STMT:
gen_expr(node->expr);
return;
case ND_COMP_STMT:
for (int i = 0; i < node->stmts->len; i++)
gen_stmt(node->stmts->data[i]);
return;
default:
error("unknown node: %d", node->op);
}
}
static void gen_param(Var *var, int i) {
IR *ir = new_ir(IR_STORE_ARG);
ir->var = var;
ir->imm = i;
ir->size = var->ty->size;
var->address_taken = true;
}
void gen_ir(Program *prog) {
for (int i = 0; i < prog->funcs->len; i++) {
fn = prog->funcs->data[i];
assert(fn->node->op == ND_FUNC);
// Add an empty entry BB to make later analysis easy.
out = new_bb();
BB *bb = new_bb();
jmp(bb);
out = bb;
// Emit IR.
Vector *params = fn->node->params;
for (int i = 0; i < params->len; i++)
gen_param(params->data[i], i);
gen_stmt(fn->node->body);
// Make it always ends with a return to make later analysis easy.
new_ir(IR_RETURN)->r2 = imm(0);
// Later passes shouldn't need the AST, so make it explicit.
fn->node = NULL;
}
}