more work on local variable support

[cparser] / ast.c

#include <config.h>

#include "ast_t.h"
#include "type_t.h"

#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <ctype.h>

#include "adt/error.h"

struct obstack ast_obstack;

static FILE *out;
static int   indent;

static void print_statement(const statement_t *statement);

void change_indent(int delta)
{
        indent += delta;
        assert(indent >= 0);
}

void print_indent(void)
{
        for(int i = 0; i < indent; ++i)
                fprintf(out, "\t");
}

static void print_const(const const_t *cnst)
{
        if(cnst->expression.datatype == NULL)
                return;

        if(is_type_integer(cnst->expression.datatype)) {
                fprintf(out, "%d", cnst->v.int_value);
        } else if(is_type_floating(cnst->expression.datatype)) {
                fprintf(out, "%Lf", cnst->v.float_value);
        }
}

static void print_string_literal(const string_literal_t *string_literal)
{
        fputc('"', out);
        for(const char *c = string_literal->value; *c != '\0'; ++c) {
                switch(*c) {
                case '\"':  fputs("\\\"", out); break;
                case '\\':  fputs("\\\\", out); break;
                case '\a':  fputs("\\a", out); break;
                case '\b':  fputs("\\b", out); break;
                case '\f':  fputs("\\f", out); break;
                case '\n':  fputs("\\n", out); break;
                case '\r':  fputs("\\r", out); break;
                case '\t':  fputs("\\t", out); break;
                case '\v':  fputs("\\v", out); break;
                case '\?':  fputs("\\?", out); break;
                default:
                        if(!isprint(*c)) {
                                fprintf(out, "\\x%x", *c);
                                break;
                        }
                        fputc(*c, out);
                        break;
                }
        }
        fputc('"', out);
}

static void print_call_expression(const call_expression_t *call)
{
        print_expression(call->function);
        fprintf(out, "(");
        call_argument_t *argument = call->arguments;
        int              first    = 1;
        while(argument != NULL) {
                if(!first) {
                        fprintf(out, ", ");
                } else {
                        first = 0;
                }
                print_expression(argument->expression);

                argument = argument->next;
        }
        fprintf(out, ")");
}

static void print_binary_expression(const binary_expression_t *binexpr)
{
        fprintf(out, "(");
        print_expression(binexpr->left);
        fprintf(out, " ");
        switch(binexpr->type) {
        case BINEXPR_INVALID:            fputs("INVOP", out); break;
        case BINEXPR_COMMA:              fputs(",", out);     break;
        case BINEXPR_ASSIGN:             fputs("=", out);     break;
        case BINEXPR_ADD:                fputs("+", out);     break;
        case BINEXPR_SUB:                fputs("-", out);     break;
        case BINEXPR_MUL:                fputs("*", out);     break;
        case BINEXPR_MOD:                fputs("%", out);     break;
        case BINEXPR_DIV:                fputs("/", out);     break;
        case BINEXPR_BITWISE_OR:         fputs("|", out);     break;
        case BINEXPR_BITWISE_AND:        fputs("&", out);     break;
        case BINEXPR_BITWISE_XOR:        fputs("^", out);     break;
        case BINEXPR_LOGICAL_OR:         fputs("||", out);    break;
        case BINEXPR_LOGICAL_AND:        fputs("&&", out);    break;
        case BINEXPR_NOTEQUAL:           fputs("!=", out);    break;
        case BINEXPR_EQUAL:              fputs("==", out);    break;
        case BINEXPR_LESS:               fputs("<", out);     break;
        case BINEXPR_LESSEQUAL:          fputs("<=", out);    break;
        case BINEXPR_GREATER:            fputs(">", out);     break;
        case BINEXPR_GREATEREQUAL:       fputs(">=", out);    break;
        case BINEXPR_SHIFTLEFT:          fputs("<<", out);    break;
        case BINEXPR_SHIFTRIGHT:         fputs(">>", out);    break;

        case BINEXPR_ADD_ASSIGN:         fputs("+=", out);    break;
        case BINEXPR_SUB_ASSIGN:         fputs("-=", out);    break;
        case BINEXPR_MUL_ASSIGN:         fputs("*=", out);    break;
        case BINEXPR_MOD_ASSIGN:         fputs("%=", out);    break;
        case BINEXPR_DIV_ASSIGN:         fputs("/=", out);    break;
        case BINEXPR_BITWISE_OR_ASSIGN:  fputs("|=", out);    break;
        case BINEXPR_BITWISE_AND_ASSIGN: fputs("&=", out);    break;
        case BINEXPR_BITWISE_XOR_ASSIGN: fputs("^=", out);    break;
        case BINEXPR_SHIFTLEFT_ASSIGN:   fputs("<<=", out);   break;
        case BINEXPR_SHIFTRIGHT_ASSIGN:  fputs(">>=", out);   break;
        }
        fprintf(out, " ");
        print_expression(binexpr->right);
        fprintf(out, ")");
}

static void print_unary_expression(const unary_expression_t *unexpr)
{
        switch(unexpr->type) {
        case UNEXPR_NEGATE:           fputs("-", out);  break;
        case UNEXPR_PLUS:             fputs("+", out);  break;
        case UNEXPR_NOT:              fputs("!", out);  break;
        case UNEXPR_BITWISE_NEGATE:   fputs("~", out);  break;
        case UNEXPR_PREFIX_INCREMENT: fputs("++", out); break;
        case UNEXPR_PREFIX_DECREMENT: fputs("--", out); break;
        case UNEXPR_DEREFERENCE:      fputs("*", out);  break;
        case UNEXPR_TAKE_ADDRESS:     fputs("&", out);  break;

        case UNEXPR_POSTFIX_INCREMENT:
                fputs("(", out);
                print_expression(unexpr->value);
                fputs(")", out);
                fputs("++", out);
                return;
        case UNEXPR_POSTFIX_DECREMENT:
                fputs("(", out);
                print_expression(unexpr->value);
                fputs(")", out);
                fputs("--", out);
                return;
        case UNEXPR_CAST:
                fputs("(", out);
                print_type(unexpr->expression.datatype);
                fputs(")", out);
                break;
        case UNEXPR_INVALID:
                fprintf(out, "unop%d", unexpr->type);
                break;
        }
        fputs("(", out);
        print_expression(unexpr->value);
        fputs(")", out);
}

static void print_reference_expression(const reference_expression_t *ref)
{
        fprintf(out, "%s", ref->declaration->symbol->string);
}

static void print_array_expression(const array_access_expression_t *expression)
{
        fputs("(", out);
        print_expression(expression->array_ref);
        fputs(")[", out);
        print_expression(expression->index);
        fputs("]", out);
}

static void print_sizeof_expression(const sizeof_expression_t *expression)
{
        fputs("sizeof", out);
        if(expression->size_expression != NULL) {
                fputc('(', out);
                print_expression(expression->size_expression);
                fputc(')', out);
        } else {
                fputc('(', out);
                print_type(expression->type);
                fputc(')', out);
        }
}

static void print_builtin_symbol(const builtin_symbol_expression_t *expression)
{
        fputs(expression->symbol->string, out);
}

static void print_conditional(const conditional_expression_t *expression)
{
        fputs("(", out);
        print_expression(expression->condition);
        fputs(" ? ", out);
        print_expression(expression->true_expression);
        fputs(" : ", out);
        print_expression(expression->false_expression);
        fputs(")", out);
}

static void print_va_arg(const va_arg_expression_t *expression)
{
        fputs("__builtin_va_arg(", out);
        print_expression(expression->arg);
        fputs(", ", out);
        print_type(expression->expression.datatype);
        fputs(")", out);
}

static void print_select(const select_expression_t *expression)
{
        print_expression(expression->compound);
        if(expression->compound->datatype == NULL ||
                        expression->compound->datatype->type == TYPE_POINTER) {
                fputs("->", out);
        } else {
                fputc('.', out);
        }
        fputs(expression->symbol->string, out);
}

void print_expression(const expression_t *expression)
{
        switch(expression->type) {
        case EXPR_INVALID:
                fprintf(out, "*invalid expression*");
                break;
        case EXPR_CONST:
                print_const((const const_t*) expression);
                break;
        case EXPR_FUNCTION:
        case EXPR_PRETTY_FUNCTION:
        case EXPR_STRING_LITERAL:
                print_string_literal((const string_literal_t*) expression);
                break;
        case EXPR_CALL:
                print_call_expression((const call_expression_t*) expression);
                break;
        case EXPR_BINARY:
                print_binary_expression((const binary_expression_t*) expression);
                break;
        case EXPR_REFERENCE:
                print_reference_expression((const reference_expression_t*) expression);
                break;
        case EXPR_ARRAY_ACCESS:
                print_array_expression((const array_access_expression_t*) expression);
                break;
        case EXPR_UNARY:
                print_unary_expression((const unary_expression_t*) expression);
                break;
        case EXPR_SIZEOF:
                print_sizeof_expression((const sizeof_expression_t*) expression);
                break;
        case EXPR_BUILTIN_SYMBOL:
                print_builtin_symbol((const builtin_symbol_expression_t*) expression);
                break;
        case EXPR_CONDITIONAL:
                print_conditional((const conditional_expression_t*) expression);
                break;
        case EXPR_VA_ARG:
                print_va_arg((const va_arg_expression_t*) expression);
                break;
        case EXPR_SELECT:
                print_select((const select_expression_t*) expression);
                break;

        case EXPR_OFFSETOF:
        case EXPR_STATEMENT:
                /* TODO */
                fprintf(out, "some expression of type %d", expression->type);
                break;
        }
}

static void print_compound_statement(const compound_statement_t *block)
{
        fputs("{\n", out);
        indent++;

        statement_t *statement = block->statements;
        while(statement != NULL) {
                print_indent();
                print_statement(statement);

                statement = statement->next;
        }
        indent--;
        print_indent();
        fputs("}\n", out);
}

static void print_return_statement(const return_statement_t *statement)
{
        fprintf(out, "return ");
        if(statement->return_value != NULL)
                print_expression(statement->return_value);
        fputs(";\n", out);
}

static void print_expression_statement(const expression_statement_t *statement)
{
        print_expression(statement->expression);
        fputs(";\n", out);
}

static void print_goto_statement(const goto_statement_t *statement)
{
        fprintf(out, "goto ");
        if(statement->label != NULL) {
                fprintf(out, "%s", statement->label->symbol->string);
        } else {
                fprintf(out, "?%s", statement->label_symbol->string);
        }
        fputs(";\n", out);
}

static void print_label_statement(const label_statement_t *statement)
{
        fprintf(out, "%s:\n", statement->symbol->string);
}

static void print_if_statement(const if_statement_t *statement)
{
        fputs("if(", out);
        print_expression(statement->condition);
        fputs(") ", out);
        if(statement->true_statement != NULL) {
                print_statement(statement->true_statement);
        }

        if(statement->false_statement != NULL) {
                print_indent();
                fputs("else ", out);
                print_statement(statement->false_statement);
        }
}

static void print_switch_statement(const switch_statement_t *statement)
{
        fputs("switch(", out);
        print_expression(statement->expression);
        fputs(") ", out);
        print_statement(statement->body);
}

static void print_case_label(const case_label_statement_t *statement)
{
        if(statement->expression == NULL) {
                fputs("default:\n", out);
        } else {
                fputs("case ", out);
                print_expression(statement->expression);
                fputs(":\n", out);
        }
}

static void print_declaration_statement(
                const declaration_statement_t *statement)
{
        int first = 1;
        declaration_t *declaration = statement->declarations_begin;
        for( ; declaration != statement->declarations_end->next;
               declaration = declaration->next) {
                if(!first) {
                        print_indent();
                } else {
                        first = 0;
                }
                print_declaration(declaration);
                fputc('\n', out);
        }
}

static void print_while_statement(const while_statement_t *statement)
{
        fputs("while(", out);
        print_expression(statement->condition);
        fputs(") ", out);
        print_statement(statement->body);
}

static void print_do_while_statement(const do_while_statement_t *statement)
{
        fputs("do ", out);
        print_statement(statement->body);
        print_indent();
        fputs("while(", out);
        print_expression(statement->condition);
        fputs(");\n", out);
}

static void print_for_statement(const for_statement_t *statement)
{
        fputs("for(", out);
        if(statement->context.declarations != NULL) {
                assert(statement->initialisation == NULL);
                print_declaration(statement->context.declarations);
                if(statement->context.declarations->next != NULL) {
                        panic("multiple declarations in for statement not supported yet");
                }
        } else if(statement->initialisation) {
                print_expression(statement->initialisation);
        }
        fputs("; ", out);
        if(statement->condition != NULL) {
                print_expression(statement->condition);
        }
        fputs("; ", out);
        if(statement->step != NULL) {
                print_expression(statement->step);
        }
        fputs(")", out);
        print_statement(statement->body);
}

void print_statement(const statement_t *statement)
{
        switch(statement->type) {
        case STATEMENT_COMPOUND:
                print_compound_statement((const compound_statement_t*) statement);
                break;
        case STATEMENT_RETURN:
                print_return_statement((const return_statement_t*) statement);
                break;
        case STATEMENT_EXPRESSION:
                print_expression_statement((const expression_statement_t*) statement);
                break;
        case STATEMENT_LABEL:
                print_label_statement((const label_statement_t*) statement);
                break;
        case STATEMENT_GOTO:
                print_goto_statement((const goto_statement_t*) statement);
                break;
        case STATEMENT_CONTINUE:
                fputs("continue;\n", out);
                break;
        case STATEMENT_BREAK:
                fputs("break;\n", out);
                break;
        case STATEMENT_IF:
                print_if_statement((const if_statement_t*) statement);
                break;
        case STATEMENT_SWITCH:
                print_switch_statement((const switch_statement_t*) statement);
                break;
        case STATEMENT_CASE_LABEL:
                print_case_label((const case_label_statement_t*) statement);
                break;
        case STATEMENT_DECLARATION:
                print_declaration_statement((const declaration_statement_t*) statement);
                break;
        case STATEMENT_WHILE:
                print_while_statement((const while_statement_t*) statement);
                break;
        case STATEMENT_DO_WHILE:
                print_do_while_statement((const do_while_statement_t*) statement);
                break;
        case STATEMENT_FOR:
                print_for_statement((const for_statement_t*) statement);
                break;
        case STATEMENT_INVALID:
                fprintf(out, "*invalid statement*");
                break;
        }
}

static void print_storage_class(storage_class_t storage_class)
{
        switch(storage_class) {
        case STORAGE_CLASS_ENUM_ENTRY:
        case STORAGE_CLASS_NONE:
                break;
        case STORAGE_CLASS_TYPEDEF:  fputs("typedef ", out); break;
        case STORAGE_CLASS_EXTERN:   fputs("extern ", out); break;
        case STORAGE_CLASS_STATIC:   fputs("static ", out); break;
        case STORAGE_CLASS_AUTO:     fputs("auto ", out); break;
        case STORAGE_CLASS_REGISTER: fputs("register ", out); break;
        }
}

void print_initializer(const initializer_t *initializer)
{
        if(initializer->type == INITIALIZER_VALUE) {
                print_expression(initializer->v.value);
                return;
        }

        assert(initializer->type == INITIALIZER_LIST);
        fputs("{ ", out);
        initializer_t *iter = initializer->v.list;
        for( ; iter != NULL; iter = iter->next) {
                print_initializer(iter);
                if(iter->next != NULL) {
                        fputs(", ", out);
                }
        }
        fputs("}", out);
}

static void print_normal_declaration(const declaration_t *declaration)
{
        print_storage_class(declaration->storage_class);
        print_type_ext(declaration->type, declaration->symbol,
                       &declaration->context);
        if(declaration->type->type == TYPE_FUNCTION) {
                if(declaration->init.statement != NULL) {
                        fputs("\n", out);
                        print_statement(declaration->init.statement);
                        return;
                }
        } else if(declaration->init.initializer != NULL) {
                fputs(" = ", out);
                print_initializer(declaration->init.initializer);
        }
        fputc(';', out);
}

void print_declaration(const declaration_t *declaration)
{
        if(declaration->namespace != NAMESPACE_NORMAL &&
                        declaration->symbol == NULL)
                return;

        switch(declaration->namespace) {
        case NAMESPACE_NORMAL:
                print_normal_declaration(declaration);
                break;
        case NAMESPACE_STRUCT:
                fputs("struct ", out);
                fputs(declaration->symbol->string, out);
                fputc(' ', out);
                print_compound_definition(declaration);
                fputc(';', out);
                break;
        case NAMESPACE_UNION:
                fputs("union ", out);
                fputs(declaration->symbol->string, out);
                fputc(' ', out);
                print_compound_definition(declaration);
                fputc(';', out);
                break;
        case NAMESPACE_ENUM:
                fputs("enum ", out);
                fputs(declaration->symbol->string, out);
                fputc(' ', out);
                print_enum_definition(declaration);
                fputc(';', out);
                break;
        }
}

void print_ast(const translation_unit_t *unit)
{
        inc_type_visited();
        set_print_compound_entries(true);

        declaration_t *declaration = unit->context.declarations;
        for( ; declaration != NULL; declaration = declaration->next) {
                if(declaration->storage_class == STORAGE_CLASS_ENUM_ENTRY)
                        continue;
                if(declaration->namespace != NAMESPACE_NORMAL &&
                                declaration->symbol == NULL)
                        continue;

                print_indent();
                print_declaration(declaration);
                fputc('\n', out);
        }
}

void init_ast(void)
{
        obstack_init(&ast_obstack);
}

void exit_ast(void)
{
        obstack_free(&ast_obstack, NULL);
}

void ast_set_output(FILE *stream)
{
        out = stream;
        type_set_output(stream);
}

void* (allocate_ast) (size_t size)
{
        return _allocate_ast(size);
}