projects/07/src/codewriter.h
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#ifndef _CODEWRITER_H #define _CODEWRITER_H // 'codewriter.h' roughly corresponds to the 'CodeWriter' module specified in // nand2tetris, with a few liberties taken. #include <stdbool.h> #include <stdint.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include "parser.h" #include "util.h" #define _DEBUG // memory mapping: // 0-15 virtual registers R0-R15 // 16-255 static variables // 256-2047 stack #define SP (0) // points to word ahead of top of stack #define LCL (1) // points to local segment #define ARG (2) // points to argument segment #define POINTER (3) #define THIS (3) #define THAT (4) #define TEMP (5) #define R13 (13) // R13-R15 are scratch space that #define R14 (14) // VM-generated assembly can use #define R15 (15) // for whatever. #define STATIC (16) // start of static variables segment (240 words, 16-255) char *static_sym_name; // static segment index indexes into map, retrieves hack assembly symbol offset #define MAX_STATIC_SYMBOLS (240) // for whatever. uint16_t static_symbol_map[MAX_STATIC_SYMBOLS]; uint8_t g_symbol_offset_bump = 0; // holds current largest symbol offset, bumps char comp_vm_funcs[] = "@__comp_funcs_end\n" "0;JMP\n" "\n" "(__test_eq)\n" "@SP\n" "AM=M-1\n" // RAM[SP]--, A = RAM[SP] "D=M\n" // D = RAM[SP] (top stack val) "A=A-1\n" // --A (--> bottom stack val) "D=M-D\n" // if D == 0, equal "M=0\n" // prematurely push false "@__test_eq_neq\n" // if D == 0, equal "D;JNE\n" // if D != 0, not equal, jump "@SP\n" // get SP "A=M-1\n" // get bottom stack val address "M=-1\n" // push 0xffff (true) "(__test_eq_neq)\n" "@R13\n" // return address in RAM[R13] "A=M\n" // A = return address "0;JMP\n" // return "\n" "(__test_gt)\n" "@SP\n" "AM=M-1\n" // RAM[SP]--, A = RAM[SP] "D=M\n" // D = RAM[SP] (top stack val) "A=A-1\n" // --A (--> bottom stack val) "D=M-D\n" // if (D - M) > 0; push true "M=0\n" // prematurely push false "@__test_gt_neq\n" // if D == 0, equal "D;JLE\n" // if D != 0, not equal, jump "@SP\n" // get SP "A=M-1\n" // get bottom stack val address "M=-1\n" // push 0xffff (true) "(__test_gt_neq)\n" "@R13\n" // return address in RAM[R13] "A=M\n" // A = return address "0;JMP\n" // return "\n" "(__test_lt)\n" "@SP\n" "AM=M-1\n" // RAM[SP]--, A = RAM[SP] "D=M\n" // D = RAM[SP] (top stack val) "A=A-1\n" // --A (--> bottom stack val) "D=M-D\n" // if (D - M) < 0; push true "M=0\n" // prematurely push false "@__test_lt_neq\n" // if D == 0, equal "D;JGE\n" // if D != 0, not equal, jump "@SP\n" // get SP "A=M-1\n" // get bottom stack val address "M=-1\n" // push 0xffff (true) "(__test_lt_neq)\n" "@R13\n" // return address in RAM[R13] "A=M\n" // A = return address "0;JMP\n" // return "\n" "(__comp_funcs_end)\n"; char vm_init[] = "//@256\n" // starting address of stack (nothing pushed yet) "//D=A\n" // D = 256 "//@SP\n" // A = <constant representing address of SP> "//M=D\n" // <memory pointed to by SP> = 256 "\n%s\n"; // <- comp_vm_funcs // TODO: add initializers for argument, local, static, constant, this, that char vm_stop[] = "(END)\n" // starting address of stack (nothing pushed yet) "@END\n" // D = 256 "0;JMP\n"; // A = <constant representing address of SP> void write_vm_init(FILE *fp) { fprintf(fp, vm_init, comp_vm_funcs); } void write_vm_stop(FILE *fp) { fprintf(fp, "\n%s", vm_stop); } static bool write_arithmetic(struct vm_instruction_t *vm_instr, FILE *fp) { char binary_op_template[] = "@SP\n" "AM=M-1\n" // RAM[SP]--, A = RAM[SP] "D=M\n" // D = RAM[SP] (top stack val) "A=A-1\n" // --A (--> bottom stack val) "%s"; // arithmetic op goes here char unary_op_template[] = "@SP\n" "A=M-1\n" // A = SP - 1 "%s"; // arithmetic op goes here char op_add[] = "M=D+M\n"; char op_sub[] = "M=M-D\n"; char op_eq[] = "@%s_%lu_eq\n" // <- static_sym_name, file_line_number "D=A\n" "@R13\n" "M=D\n" "@__test_eq\n" "0;JMP\n" "(%s_%lu_eq)\n" // return here "\n"; char op_gt[] = "@%s_%lu_gt\n" // <- static_sym_name, file_line_number "D=A\n" "@R13\n" "M=D\n" "@__test_gt\n" "0;JMP\n" "(%s_%lu_gt)\n" // return here "\n"; char op_lt[] = "@%s_%lu_lt\n" // <- static_sym_name, file_line_number "D=A\n" "@R13\n" "M=D\n" "@__test_lt\n" "0;JMP\n" "(%s_%lu_lt)\n" // return here "\n"; char op_and[] = "M=D&M\n"; char op_or[] = "M=D|M\n"; char op_neg[] = "M=-M\n"; char op_not[] = "M=!M\n"; // binary operations if (!strncmp(vm_instr->arg1, "add", CMD_STR_MAX_LEN)) { fprintf(fp, binary_op_template, op_add); } else if (!strncmp(vm_instr->arg1, "sub", CMD_STR_MAX_LEN)) { fprintf(fp, binary_op_template, op_sub); } else if (!strncmp(vm_instr->arg1, "eq", CMD_STR_MAX_LEN)) { fprintf(fp, op_eq, static_sym_name, file_line_no, static_sym_name, file_line_no); } else if (!strncmp(vm_instr->arg1, "gt", CMD_STR_MAX_LEN)) { fprintf(fp, op_gt, static_sym_name, file_line_no, static_sym_name, file_line_no); } else if (!strncmp(vm_instr->arg1, "lt", CMD_STR_MAX_LEN)) { fprintf(fp, op_lt, static_sym_name, file_line_no, static_sym_name, file_line_no); } else if (!strncmp(vm_instr->arg1, "and", CMD_STR_MAX_LEN)) { fprintf(fp, binary_op_template, op_and); } else if (!strncmp(vm_instr->arg1, "or", CMD_STR_MAX_LEN)) { fprintf(fp, binary_op_template, op_or); // unary operations } else if (!strncmp(vm_instr->arg1, "neg", CMD_STR_MAX_LEN)) { fprintf(fp, unary_op_template, op_neg); } else if (!strncmp(vm_instr->arg1, "not", CMD_STR_MAX_LEN)) { fprintf(fp, unary_op_template, op_not); } else { err("error: invalid arithmetic op \"%s\"\n", vm_instr->arg1); return false; } return true; } static bool resolve_static_address(struct vm_instruction_t *vm_instr, uint16_t *addr) { uint16_t symbol_offset; if (vm_instr->arg2 >= MAX_STATIC_SYMBOLS) { err("error: arg2 too large, >= %u\n", MAX_STATIC_SYMBOLS); return false; } symbol_offset = static_symbol_map[vm_instr->arg2]; if (symbol_offset == 0xffff) { // new offset not in map (-1 special) if (g_symbol_offset_bump >= MAX_STATIC_SYMBOLS) { err("error: symbol offset grew too large (>= %u), " "too many static variables\n", MAX_STATIC_SYMBOLS); return false; } static_symbol_map[vm_instr->arg2] = g_symbol_offset_bump; *addr = g_symbol_offset_bump; ++g_symbol_offset_bump; // bump global symbol offset } else { // offset found in map, return symbol value/index *addr = symbol_offset; } return true; } // push 16-bit value from segment offset onto top of stack static bool write_push(struct vm_instruction_t *vm_instr, FILE *fp) { uint16_t addr, arg2 = vm_instr->arg2; // TODO: could add SP counter/check to catch overflows char const_template[] = "@%hu\n" // A = constant "D=A\n%s"; // D = constant char addr_template[] = "@%hu\n" // A = segment + index "D=M\n%s"; // D = RAM[segment + index] char static_template[] = "@%s.%hu\n" // A = segment + index "D=M\n%s"; // D = RAM[segment + index] char indirect_template[] = "@%hu\n" // A = segment "D=M\n" // D = RAM[segment] "@%hu\n" // A = index "A=A+D\n" // A = segment + index "D=M\n%s"; // D = RAM[segment + index] char push_boilerplate[] = "@SP\n" "M=M+1\n" // RAM[SP]++ // inc SP "A=M-1\n" // A = RAM[SP] - 1 // prev top "M=D\n"; // RAM[SP] = constant if (!strcmp(vm_instr->arg1, "constant")) { // TODO: check size of constant (allowed to be > 32,767?) // TODO: look in nand2tetris forums in case issue already noted fprintf(fp, const_template, arg2, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "argument")) { fprintf(fp, indirect_template, ARG, arg2, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "local")) { fprintf(fp, indirect_template, LCL, arg2, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "static")) { if (!resolve_static_address(vm_instr, &addr)) { return false; } fprintf(fp, static_template, static_sym_name, addr, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "this")) { fprintf(fp, indirect_template, THIS, arg2, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "that")) { fprintf(fp, indirect_template, THAT, arg2, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "pointer")) { addr = POINTER + vm_instr->arg2; fprintf(fp, addr_template, addr, push_boilerplate); } else if (!strcmp(vm_instr->arg1, "temp")) { addr = TEMP + vm_instr->arg2; fprintf(fp, addr_template, addr, push_boilerplate); } else { err("error: invalid segment name \"%s\"\n", vm_instr->arg1); return false; } return true; } // pop 16-bit value from top of stack into segment offset static bool write_pop(struct vm_instruction_t *vm_instr, FILE *fp) { // TODO: could add SP counter/check to catch overflows uint16_t addr, arg2 = vm_instr->arg2; char pop_indirect_template[] = "@%hu\n" // @segment "D=M\n" // D = segment "@%hu\n" // @index "D=A+D\n" // A = segment + index "@R13\n" "M=D\n" // RAM[13] = segment + index "@SP\n" // "AM=M-1\n" // "D=M\n" // "@R13\n" // "A=M\n" // "M=D\n"; // char pop_addr_template[] = "@SP\n" "AM=M-1\n" // decrement SP "D=M\n" // "pop" (read) value into D "@%hu\n" // load address "M=D\n"; // "pop" (write) value to RAM char pop_static_template[] = "@SP\n" "AM=M-1\n" // decrement SP "D=M\n" // "pop" (read) value into D "@%s.%hu\n" // A = segment + index "M=D\n"; // RAM[segment + index] = D if (!strcmp(vm_instr->arg1, "argument")) { fprintf(fp, pop_indirect_template, ARG, arg2); } else if (!strcmp(vm_instr->arg1, "local")) { fprintf(fp, pop_indirect_template, LCL, arg2); } else if (!strcmp(vm_instr->arg1, "static")) { if (!resolve_static_address(vm_instr, &addr)) { return false; } fprintf(fp, pop_static_template, static_sym_name, addr); } else if (!strcmp(vm_instr->arg1, "this")) { fprintf(fp, pop_indirect_template, THIS, arg2); } else if (!strcmp(vm_instr->arg1, "that")) { fprintf(fp, pop_indirect_template, THAT, arg2); } else if (!strcmp(vm_instr->arg1, "pointer")) { addr = POINTER + vm_instr->arg2; fprintf(fp, pop_addr_template, addr); } else if (!strcmp(vm_instr->arg1, "temp")) { addr = TEMP + vm_instr->arg2; fprintf(fp, pop_addr_template, addr); } else { err("error: invalid segment name \"%s\"\n", vm_instr->arg1); return false; } return true; } bool write_instruction(struct vm_instruction_t *vm_instr, FILE *fp) { fprintf(fp, "\n// %lu: %s\n", file_line_no, vm_instr->line); if (vm_instr->cmd == C_ARITHMETIC) { write_arithmetic(vm_instr, fp); } else if (vm_instr->cmd == C_PUSH) { write_push(vm_instr, fp); } else if (vm_instr->cmd == C_POP) { write_pop(vm_instr, fp); } else { err("error: unrecognized instruction (%u)\n", vm_instr->cmd); return false; } return true; } #endif // _CODEWRITER_H |