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cg.c
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#include "defs.h"
#include "data.h"
#include "decl.h"
// Code generator for x86-64
// Copyright (c) 2019 Warren Toomey, GPL3
// List of available registers and their names
// We need a list of byte registers, too
static int freereg[4];
static char *reglist[4] = { "%r8", "%r9", "%r10", "%r11" };
static char *breglist[4] = { "%r8b", "%r9b", "%r10b", "%r11b" };
// Set all registers as available
void freeall_registers(void) {
freereg[0] = freereg[1] = freereg[2] = freereg[3] = 1;
}
// Allocate a free register. Return the number of
// the register. Die if no available registers.
static int alloc_register(void) {
for (int i = 0; i < 4; i++) {
if (freereg[i]) {
freereg[i] = 0;
return (i);
}
}
fatal("Out of registers");
}
// Return a register to the list of available registers.
// Check to see if it's not already there.
static void free_register(int reg) {
if (freereg[reg] != 0)
fatald("Error trying to free register", reg);
freereg[reg] = 1;
}
// Print out the assembly preamble
void cgpreamble() {
freeall_registers();
fputs("\t.text\n"
".LC0:\n"
"\t.string\t\"%d\\n\"\n"
"printint:\n"
"\tpushq\t%rbp\n"
"\tmovq\t%rsp, %rbp\n"
"\tsubq\t$16, %rsp\n"
"\tmovl\t%edi, -4(%rbp)\n"
"\tmovl\t-4(%rbp), %eax\n"
"\tmovl\t%eax, %esi\n"
"\tleaq .LC0(%rip), %rdi\n"
"\tmovl $0, %eax\n"
"\tcall printf@PLT\n" "\tnop\n" "\tleave\n" "\tret\n" "\n", Outfile);
}
// Print out a function preamble
void cgfuncpreamble(char *name) {
fprintf(Outfile,
"\t.text\n"
"\t.globl\t%s\n"
"\t.type\t%s, @function\n"
"%s:\n" "\tpushq\t%%rbp\n"
"\tmovq\t%%rsp, %%rbp\n", name, name, name);
}
// Print out a function postamble
void cgfuncpostamble() {
fputs("\tmovl $0, %eax\n" "\tpopq %rbp\n" "\tret\n", Outfile);
}
// Load an integer literal value into a register.
// Return the number of the register
int cgloadint(int value) {
// Get a new register
int r = alloc_register();
// Print out the code to initialise it
fprintf(Outfile, "\tmovq\t$%d, %s\n", value, reglist[r]);
return (r);
}
// Load a value from a variable into a register.
// Return the number of the register
int cgloadglob(char *identifier) {
// Get a new register
int r = alloc_register();
// Print out the code to initialise it
fprintf(Outfile, "\tmovq\t%s(\%%rip), %s\n", identifier, reglist[r]);
return (r);
}
// Add two registers together and return
// the number of the register with the result
int cgadd(int r1, int r2) {
fprintf(Outfile, "\taddq\t%s, %s\n", reglist[r1], reglist[r2]);
free_register(r1);
return (r2);
}
// Subtract the second register from the first and
// return the number of the register with the result
int cgsub(int r1, int r2) {
fprintf(Outfile, "\tsubq\t%s, %s\n", reglist[r2], reglist[r1]);
free_register(r2);
return (r1);
}
// Multiply two registers together and return
// the number of the register with the result
int cgmul(int r1, int r2) {
fprintf(Outfile, "\timulq\t%s, %s\n", reglist[r1], reglist[r2]);
free_register(r1);
return (r2);
}
// Divide the first register by the second and
// return the number of the register with the result
int cgdiv(int r1, int r2) {
fprintf(Outfile, "\tmovq\t%s,%%rax\n", reglist[r1]);
fprintf(Outfile, "\tcqo\n");
fprintf(Outfile, "\tidivq\t%s\n", reglist[r2]);
fprintf(Outfile, "\tmovq\t%%rax,%s\n", reglist[r1]);
free_register(r2);
return (r1);
}
// Call printint() with the given register
void cgprintint(int r) {
fprintf(Outfile, "\tmovq\t%s, %%rdi\n", reglist[r]);
fprintf(Outfile, "\tcall\tprintint\n");
free_register(r);
}
// Store a register's value into a variable
int cgstorglob(int r, char *identifier) {
fprintf(Outfile, "\tmovq\t%s, %s(\%%rip)\n", reglist[r], identifier);
return (r);
}
// Generate a global symbol
void cgglobsym(char *sym) {
fprintf(Outfile, "\t.comm\t%s,8,8\n", sym);
}
// List of comparison instructions,
// in AST order: A_EQ, A_NE, A_LT, A_GT, A_LE, A_GE
static char *cmplist[] =
{ "sete", "setne", "setl", "setg", "setle", "setge" };
// Compare two registers and set if true.
int cgcompare_and_set(int ASTop, int r1, int r2) {
// Check the range of the AST operation
if (ASTop < A_EQ || ASTop > A_GE)
fatal("Bad ASTop in cgcompare_and_set()");
fprintf(Outfile, "\tcmpq\t%s, %s\n", reglist[r2], reglist[r1]);
fprintf(Outfile, "\t%s\t%s\n", cmplist[ASTop - A_EQ], breglist[r2]);
fprintf(Outfile, "\tmovzbq\t%s, %s\n", breglist[r2], reglist[r2]);
free_register(r1);
return (r2);
}
// Generate a label
void cglabel(int l) {
fprintf(Outfile, "L%d:\n", l);
}
// Generate a jump to a label
void cgjump(int l) {
fprintf(Outfile, "\tjmp\tL%d\n", l);
}
// List of inverted jump instructions,
// in AST order: A_EQ, A_NE, A_LT, A_GT, A_LE, A_GE
static char *invcmplist[] = { "jne", "je", "jge", "jle", "jg", "jl" };
// Compare two registers and jump if false.
int cgcompare_and_jump(int ASTop, int r1, int r2, int label) {
// Check the range of the AST operation
if (ASTop < A_EQ || ASTop > A_GE)
fatal("Bad ASTop in cgcompare_and_set()");
fprintf(Outfile, "\tcmpq\t%s, %s\n", reglist[r2], reglist[r1]);
fprintf(Outfile, "\t%s\tL%d\n", invcmplist[ASTop - A_EQ], label);
freeall_registers();
return (NOREG);
}