chibicc/preprocess.c

1209 lines
32 KiB
C

// This file implements the C preprocessor.
//
// The preprocessor takes a list of tokens as an input and returns a
// new list of tokens as an output.
//
// The preprocessing language is designed in such a way that that's
// guaranteed to stop even if there is a recursive macro.
// Informally speaking, a macro is applied only once for each token.
// That is, if a macro token T appears in a result of direct or
// indirect macro expansion of T, T won't be expanded any further.
// For example, if T is defined as U, and U is defined as T, then
// token T is expanded to U and then to T and the macro expansion
// stops at that point.
//
// To achieve the above behavior, we attach for each token a set of
// macro names from which the token is expanded. The set is called
// "hideset". Hideset is initially empty, and every time we expand a
// macro, the macro name is added to the resulting tokens' hidesets.
//
// The above macro expansion algorithm is explained in this document
// written by Dave Prossor, which is used as a basis for the
// standard's wording:
// https://github.com/rui314/chibicc/wiki/cpp.algo.pdf
#include "chibicc.h"
typedef struct MacroParam MacroParam;
struct MacroParam {
MacroParam *next;
char *name;
};
typedef struct MacroArg MacroArg;
struct MacroArg {
MacroArg *next;
char *name;
bool is_va_args;
Token *tok;
};
typedef Token *macro_handler_fn(Token *);
typedef struct Macro Macro;
struct Macro {
char *name;
bool is_objlike; // Object-like or function-like
MacroParam *params;
char *va_args_name;
Token *body;
macro_handler_fn *handler;
};
// `#if` can be nested, so we use a stack to manage nested `#if`s.
typedef struct CondIncl CondIncl;
struct CondIncl {
CondIncl *next;
enum { IN_THEN, IN_ELIF, IN_ELSE } ctx;
Token *tok;
bool included;
};
typedef struct Hideset Hideset;
struct Hideset {
Hideset *next;
char *name;
};
static HashMap macros;
static CondIncl *cond_incl;
static HashMap pragma_once;
static int include_next_idx;
static Token *preprocess2(Token *tok);
static Macro *find_macro(Token *tok);
static bool is_hash(Token *tok) {
return tok->at_bol && equal(tok, "#");
}
// Some preprocessor directives such as #include allow extraneous
// tokens before newline. This function skips such tokens.
static Token *skip_line(Token *tok) {
if (tok->at_bol)
return tok;
warn_tok(tok, "extra token");
while (tok->at_bol)
tok = tok->next;
return tok;
}
static Token *copy_token(Token *tok) {
Token *t = calloc(1, sizeof(Token));
*t = *tok;
t->next = NULL;
return t;
}
static Token *new_eof(Token *tok) {
Token *t = copy_token(tok);
t->kind = TK_EOF;
t->len = 0;
return t;
}
static Hideset *new_hideset(char *name) {
Hideset *hs = calloc(1, sizeof(Hideset));
hs->name = name;
return hs;
}
static Hideset *hideset_union(Hideset *hs1, Hideset *hs2) {
Hideset head = {};
Hideset *cur = &head;
for (; hs1; hs1 = hs1->next)
cur = cur->next = new_hideset(hs1->name);
cur->next = hs2;
return head.next;
}
static bool hideset_contains(Hideset *hs, char *s, int len) {
for (; hs; hs = hs->next)
if (strlen(hs->name) == len && !strncmp(hs->name, s, len))
return true;
return false;
}
static Hideset *hideset_intersection(Hideset *hs1, Hideset *hs2) {
Hideset head = {};
Hideset *cur = &head;
for (; hs1; hs1 = hs1->next)
if (hideset_contains(hs2, hs1->name, strlen(hs1->name)))
cur = cur->next = new_hideset(hs1->name);
return head.next;
}
static Token *add_hideset(Token *tok, Hideset *hs) {
Token head = {};
Token *cur = &head;
for (; tok; tok = tok->next) {
Token *t = copy_token(tok);
t->hideset = hideset_union(t->hideset, hs);
cur = cur->next = t;
}
return head.next;
}
// Append tok2 to the end of tok1.
static Token *append(Token *tok1, Token *tok2) {
if (tok1->kind == TK_EOF)
return tok2;
Token head = {};
Token *cur = &head;
for (; tok1->kind != TK_EOF; tok1 = tok1->next)
cur = cur->next = copy_token(tok1);
cur->next = tok2;
return head.next;
}
static Token *skip_cond_incl2(Token *tok) {
while (tok->kind != TK_EOF) {
if (is_hash(tok) &&
(equal(tok->next, "if") || equal(tok->next, "ifdef") ||
equal(tok->next, "ifndef"))) {
tok = skip_cond_incl2(tok->next->next);
continue;
}
if (is_hash(tok) && equal(tok->next, "endif"))
return tok->next->next;
tok = tok->next;
}
return tok;
}
// Skip until next `#else`, `#elif` or `#endif`.
// Nested `#if` and `#endif` are skipped.
static Token *skip_cond_incl(Token *tok) {
while (tok->kind != TK_EOF) {
if (is_hash(tok) &&
(equal(tok->next, "if") || equal(tok->next, "ifdef") ||
equal(tok->next, "ifndef"))) {
tok = skip_cond_incl2(tok->next->next);
continue;
}
if (is_hash(tok) &&
(equal(tok->next, "elif") || equal(tok->next, "else") ||
equal(tok->next, "endif")))
break;
tok = tok->next;
}
return tok;
}
// Double-quote a given string and returns it.
static char *quote_string(char *str) {
int bufsize = 3;
for (int i = 0; str[i]; i++) {
if (str[i] == '\\' || str[i] == '"')
bufsize++;
bufsize++;
}
char *buf = calloc(1, bufsize);
char *p = buf;
*p++ = '"';
for (int i = 0; str[i]; i++) {
if (str[i] == '\\' || str[i] == '"')
*p++ = '\\';
*p++ = str[i];
}
*p++ = '"';
*p++ = '\0';
return buf;
}
static Token *new_str_token(char *str, Token *tmpl) {
char *buf = quote_string(str);
return tokenize(new_file(tmpl->file->name, tmpl->file->file_no, buf));
}
// Copy all tokens until the next newline, terminate them with
// an EOF token and then returns them. This function is used to
// create a new list of tokens for `#if` arguments.
static Token *copy_line(Token **rest, Token *tok) {
Token head = {};
Token *cur = &head;
for (; !tok->at_bol; tok = tok->next)
cur = cur->next = copy_token(tok);
cur->next = new_eof(tok);
*rest = tok;
return head.next;
}
static Token *new_num_token(int val, Token *tmpl) {
char *buf = format("%d\n", val);
return tokenize(new_file(tmpl->file->name, tmpl->file->file_no, buf));
}
static Token *read_const_expr(Token **rest, Token *tok) {
tok = copy_line(rest, tok);
Token head = {};
Token *cur = &head;
while (tok->kind != TK_EOF) {
// "defined(foo)" or "defined foo" becomes "1" if macro "foo"
// is defined. Otherwise "0".
if (equal(tok, "defined")) {
Token *start = tok;
bool has_paren = consume(&tok, tok->next, "(");
if (tok->kind != TK_IDENT)
error_tok(start, "macro name must be an identifier");
Macro *m = find_macro(tok);
tok = tok->next;
if (has_paren)
tok = skip(tok, ")");
cur = cur->next = new_num_token(m ? 1 : 0, start);
continue;
}
cur = cur->next = tok;
tok = tok->next;
}
cur->next = tok;
return head.next;
}
// Read and evaluate a constant expression.
static long eval_const_expr(Token **rest, Token *tok) {
Token *start = tok;
Token *expr = read_const_expr(rest, tok->next);
expr = preprocess2(expr);
if (expr->kind == TK_EOF)
error_tok(start, "no expression");
// [https://www.sigbus.info/n1570#6.10.1p4] The standard requires
// we replace remaining non-macro identifiers with "0" before
// evaluating a constant expression. For example, `#if foo` is
// equivalent to `#if 0` if foo is not defined.
for (Token *t = expr; t->kind != TK_EOF; t = t->next) {
if (t->kind == TK_IDENT) {
Token *next = t->next;
*t = *new_num_token(0, t);
t->next = next;
}
}
// Convert pp-numbers to regular numbers
convert_pp_tokens(expr);
Token *rest2;
long val = const_expr(&rest2, expr);
if (rest2->kind != TK_EOF)
error_tok(rest2, "extra token");
return val;
}
static CondIncl *push_cond_incl(Token *tok, bool included) {
CondIncl *ci = calloc(1, sizeof(CondIncl));
ci->next = cond_incl;
ci->ctx = IN_THEN;
ci->tok = tok;
ci->included = included;
cond_incl = ci;
return ci;
}
static Macro *find_macro(Token *tok) {
if (tok->kind != TK_IDENT)
return NULL;
return hashmap_get2(&macros, tok->loc, tok->len);
}
static Macro *add_macro(char *name, bool is_objlike, Token *body) {
Macro *m = calloc(1, sizeof(Macro));
m->name = name;
m->is_objlike = is_objlike;
m->body = body;
hashmap_put(&macros, name, m);
return m;
}
static MacroParam *read_macro_params(Token **rest, Token *tok, char **va_args_name) {
MacroParam head = {};
MacroParam *cur = &head;
while (!equal(tok, ")")) {
if (cur != &head)
tok = skip(tok, ",");
if (equal(tok, "...")) {
*va_args_name = "__VA_ARGS__";
*rest = skip(tok->next, ")");
return head.next;
}
if (tok->kind != TK_IDENT)
error_tok(tok, "expected an identifier");
if (equal(tok->next, "...")) {
*va_args_name = strndup(tok->loc, tok->len);
*rest = skip(tok->next->next, ")");
return head.next;
}
MacroParam *m = calloc(1, sizeof(MacroParam));
m->name = strndup(tok->loc, tok->len);
cur = cur->next = m;
tok = tok->next;
}
*rest = tok->next;
return head.next;
}
static void read_macro_definition(Token **rest, Token *tok) {
if (tok->kind != TK_IDENT)
error_tok(tok, "macro name must be an identifier");
char *name = strndup(tok->loc, tok->len);
tok = tok->next;
if (!tok->has_space && equal(tok, "(")) {
// Function-like macro
char *va_args_name = NULL;
MacroParam *params = read_macro_params(&tok, tok->next, &va_args_name);
Macro *m = add_macro(name, false, copy_line(rest, tok));
m->params = params;
m->va_args_name = va_args_name;
} else {
// Object-like macro
add_macro(name, true, copy_line(rest, tok));
}
}
static MacroArg *read_macro_arg_one(Token **rest, Token *tok, bool read_rest) {
Token head = {};
Token *cur = &head;
int level = 0;
for (;;) {
if (level == 0 && equal(tok, ")"))
break;
if (level == 0 && !read_rest && equal(tok, ","))
break;
if (tok->kind == TK_EOF)
error_tok(tok, "premature end of input");
if (equal(tok, "("))
level++;
else if (equal(tok, ")"))
level--;
cur = cur->next = copy_token(tok);
tok = tok->next;
}
cur->next = new_eof(tok);
MacroArg *arg = calloc(1, sizeof(MacroArg));
arg->tok = head.next;
*rest = tok;
return arg;
}
static MacroArg *
read_macro_args(Token **rest, Token *tok, MacroParam *params, char *va_args_name) {
Token *start = tok;
tok = tok->next->next;
MacroArg head = {};
MacroArg *cur = &head;
MacroParam *pp = params;
for (; pp; pp = pp->next) {
if (cur != &head)
tok = skip(tok, ",");
cur = cur->next = read_macro_arg_one(&tok, tok, false);
cur->name = pp->name;
}
if (va_args_name) {
MacroArg *arg;
if (equal(tok, ")")) {
arg = calloc(1, sizeof(MacroArg));
arg->tok = new_eof(tok);
} else {
if (pp != params)
tok = skip(tok, ",");
arg = read_macro_arg_one(&tok, tok, true);
}
arg->name = va_args_name;;
arg->is_va_args = true;
cur = cur->next = arg;
} else if (pp) {
error_tok(start, "too many arguments");
}
skip(tok, ")");
*rest = tok;
return head.next;
}
static MacroArg *find_arg(MacroArg *args, Token *tok) {
for (MacroArg *ap = args; ap; ap = ap->next)
if (tok->len == strlen(ap->name) && !strncmp(tok->loc, ap->name, tok->len))
return ap;
return NULL;
}
// Concatenates all tokens in `tok` and returns a new string.
static char *join_tokens(Token *tok, Token *end) {
// Compute the length of the resulting token.
int len = 1;
for (Token *t = tok; t != end && t->kind != TK_EOF; t = t->next) {
if (t != tok && t->has_space)
len++;
len += t->len;
}
char *buf = calloc(1, len);
// Copy token texts.
int pos = 0;
for (Token *t = tok; t != end && t->kind != TK_EOF; t = t->next) {
if (t != tok && t->has_space)
buf[pos++] = ' ';
strncpy(buf + pos, t->loc, t->len);
pos += t->len;
}
buf[pos] = '\0';
return buf;
}
// Concatenates all tokens in `arg` and returns a new string token.
// This function is used for the stringizing operator (#).
static Token *stringize(Token *hash, Token *arg) {
// Create a new string token. We need to set some value to its
// source location for error reporting function, so we use a macro
// name token as a template.
char *s = join_tokens(arg, NULL);
return new_str_token(s, hash);
}
// Concatenate two tokens to create a new token.
static Token *paste(Token *lhs, Token *rhs) {
// Paste the two tokens.
char *buf = format("%.*s%.*s", lhs->len, lhs->loc, rhs->len, rhs->loc);
// Tokenize the resulting string.
Token *tok = tokenize(new_file(lhs->file->name, lhs->file->file_no, buf));
if (tok->next->kind != TK_EOF)
error_tok(lhs, "pasting forms '%s', an invalid token", buf);
return tok;
}
static bool has_varargs(MacroArg *args) {
for (MacroArg *ap = args; ap; ap = ap->next)
if (!strcmp(ap->name, "__VA_ARGS__"))
return ap->tok->kind != TK_EOF;
return false;
}
// Replace func-like macro parameters with given arguments.
static Token *subst(Token *tok, MacroArg *args) {
Token head = {};
Token *cur = &head;
while (tok->kind != TK_EOF) {
// "#" followed by a parameter is replaced with stringized actuals.
if (equal(tok, "#")) {
MacroArg *arg = find_arg(args, tok->next);
if (!arg)
error_tok(tok->next, "'#' is not followed by a macro parameter");
cur = cur->next = stringize(tok, arg->tok);
tok = tok->next->next;
continue;
}
// [GNU] If __VA_ARG__ is empty, `,##__VA_ARGS__` is expanded
// to the empty token list. Otherwise, its expaned to `,` and
// __VA_ARGS__.
if (equal(tok, ",") && equal(tok->next, "##")) {
MacroArg *arg = find_arg(args, tok->next->next);
if (arg && arg->is_va_args) {
if (arg->tok->kind == TK_EOF) {
tok = tok->next->next->next;
} else {
cur = cur->next = copy_token(tok);
tok = tok->next->next;
}
continue;
}
}
if (equal(tok, "##")) {
if (cur == &head)
error_tok(tok, "'##' cannot appear at start of macro expansion");
if (tok->next->kind == TK_EOF)
error_tok(tok, "'##' cannot appear at end of macro expansion");
MacroArg *arg = find_arg(args, tok->next);
if (arg) {
if (arg->tok->kind != TK_EOF) {
*cur = *paste(cur, arg->tok);
for (Token *t = arg->tok->next; t->kind != TK_EOF; t = t->next)
cur = cur->next = copy_token(t);
}
tok = tok->next->next;
continue;
}
*cur = *paste(cur, tok->next);
tok = tok->next->next;
continue;
}
MacroArg *arg = find_arg(args, tok);
if (arg && equal(tok->next, "##")) {
Token *rhs = tok->next->next;
if (arg->tok->kind == TK_EOF) {
MacroArg *arg2 = find_arg(args, rhs);
if (arg2) {
for (Token *t = arg2->tok; t->kind != TK_EOF; t = t->next)
cur = cur->next = copy_token(t);
} else {
cur = cur->next = copy_token(rhs);
}
tok = rhs->next;
continue;
}
for (Token *t = arg->tok; t->kind != TK_EOF; t = t->next)
cur = cur->next = copy_token(t);
tok = tok->next;
continue;
}
// If __VA_ARG__ is empty, __VA_OPT__(x) is expanded to the
// empty token list. Otherwise, __VA_OPT__(x) is expanded to x.
if (equal(tok, "__VA_OPT__") && equal(tok->next, "(")) {
MacroArg *arg = read_macro_arg_one(&tok, tok->next->next, true);
if (has_varargs(args))
for (Token *t = arg->tok; t->kind != TK_EOF; t = t->next)
cur = cur->next = t;
tok = skip(tok, ")");
continue;
}
// Handle a macro token. Macro arguments are completely macro-expanded
// before they are substituted into a macro body.
if (arg) {
Token *t = preprocess2(arg->tok);
t->at_bol = tok->at_bol;
t->has_space = tok->has_space;
for (; t->kind != TK_EOF; t = t->next)
cur = cur->next = copy_token(t);
tok = tok->next;
continue;
}
// Handle a non-macro token.
cur = cur->next = copy_token(tok);
tok = tok->next;
continue;
}
cur->next = tok;
return head.next;
}
// If tok is a macro, expand it and return true.
// Otherwise, do nothing and return false.
static bool expand_macro(Token **rest, Token *tok) {
if (hideset_contains(tok->hideset, tok->loc, tok->len))
return false;
Macro *m = find_macro(tok);
if (!m)
return false;
// Built-in dynamic macro application such as __LINE__
if (m->handler) {
*rest = m->handler(tok);
(*rest)->next = tok->next;
return true;
}
// Object-like macro application
if (m->is_objlike) {
Hideset *hs = hideset_union(tok->hideset, new_hideset(m->name));
Token *body = add_hideset(m->body, hs);
for (Token *t = body; t->kind != TK_EOF; t = t->next)
t->origin = tok;
*rest = append(body, tok->next);
(*rest)->at_bol = tok->at_bol;
(*rest)->has_space = tok->has_space;
return true;
}
// If a funclike macro token is not followed by an argument list,
// treat it as a normal identifier.
if (!equal(tok->next, "("))
return false;
// Function-like macro application
Token *macro_token = tok;
MacroArg *args = read_macro_args(&tok, tok, m->params, m->va_args_name);
Token *rparen = tok;
// Tokens that consist a func-like macro invocation may have different
// hidesets, and if that's the case, it's not clear what the hideset
// for the new tokens should be. We take the interesection of the
// macro token and the closing parenthesis and use it as a new hideset
// as explained in the Dave Prossor's algorithm.
Hideset *hs = hideset_intersection(macro_token->hideset, rparen->hideset);
hs = hideset_union(hs, new_hideset(m->name));
Token *body = subst(m->body, args);
body = add_hideset(body, hs);
for (Token *t = body; t->kind != TK_EOF; t = t->next)
t->origin = macro_token;
*rest = append(body, tok->next);
(*rest)->at_bol = macro_token->at_bol;
(*rest)->has_space = macro_token->has_space;
return true;
}
char *search_include_paths(char *filename) {
if (filename[0] == '/')
return filename;
static HashMap cache;
char *cached = hashmap_get(&cache, filename);
if (cached)
return cached;
// Search a file from the include paths.
for (int i = 0; i < include_paths.len; i++) {
char *path = format("%s/%s", include_paths.data[i], filename);
if (!file_exists(path))
continue;
hashmap_put(&cache, filename, path);
include_next_idx = i + 1;
return path;
}
return NULL;
}
static char *search_include_next(char *filename) {
for (; include_next_idx < include_paths.len; include_next_idx++) {
char *path = format("%s/%s", include_paths.data[include_next_idx], filename);
if (file_exists(path))
return path;
}
return NULL;
}
// Read an #include argument.
static char *read_include_filename(Token **rest, Token *tok, bool *is_dquote) {
// Pattern 1: #include "foo.h"
if (tok->kind == TK_STR) {
// A double-quoted filename for #include is a special kind of
// token, and we don't want to interpret any escape sequences in it.
// For example, "\f" in "C:\foo" is not a formfeed character but
// just two non-control characters, backslash and f.
// So we don't want to use token->str.
*is_dquote = true;
*rest = skip_line(tok->next);
return strndup(tok->loc + 1, tok->len - 2);
}
// Pattern 2: #include <foo.h>
if (equal(tok, "<")) {
// Reconstruct a filename from a sequence of tokens between
// "<" and ">".
Token *start = tok;
// Find closing ">".
for (; !equal(tok, ">"); tok = tok->next)
if (tok->at_bol || tok->kind == TK_EOF)
error_tok(tok, "expected '>'");
*is_dquote = false;
*rest = skip_line(tok->next);
return join_tokens(start->next, tok);
}
// Pattern 3: #include FOO
// In this case FOO must be macro-expanded to either
// a single string token or a sequence of "<" ... ">".
if (tok->kind == TK_IDENT) {
Token *tok2 = preprocess2(copy_line(rest, tok));
return read_include_filename(&tok2, tok2, is_dquote);
}
error_tok(tok, "expected a filename");
}
// Detect the following "include guard" pattern.
//
// #ifndef FOO_H
// #define FOO_H
// ...
// #endif
static char *detect_include_guard(Token *tok) {
// Detect the first two lines.
if (!is_hash(tok) || !equal(tok->next, "ifndef"))
return NULL;
tok = tok->next->next;
if (tok->kind != TK_IDENT)
return NULL;
char *macro = strndup(tok->loc, tok->len);
tok = tok->next;
if (!is_hash(tok) || !equal(tok->next, "define") || !equal(tok->next->next, macro))
return NULL;
// Read until the end of the file.
while (tok->kind != TK_EOF) {
if (!is_hash(tok)) {
tok = tok->next;
continue;
}
if (equal(tok->next, "endif") && tok->next->next->kind == TK_EOF)
return macro;
if (equal(tok, "if") || equal(tok, "ifdef") || equal(tok, "ifndef"))
tok = skip_cond_incl(tok->next);
else
tok = tok->next;
}
return NULL;
}
static Token *include_file(Token *tok, char *path, Token *filename_tok) {
// Check for "#pragma once"
if (hashmap_get(&pragma_once, path))
return tok;
// If we read the same file before, and if the file was guarded
// by the usual #ifndef ... #endif pattern, we may be able to
// skip the file without opening it.
static HashMap include_guards;
char *guard_name = hashmap_get(&include_guards, path);
if (guard_name && hashmap_get(&macros, guard_name))
return tok;
Token *tok2 = tokenize_file(path);
if (!tok2)
error_tok(filename_tok, "%s: cannot open file: %s", path, strerror(errno));
guard_name = detect_include_guard(tok2);
if (guard_name)
hashmap_put(&include_guards, path, guard_name);
return append(tok2, tok);
}
// Read #line arguments
static void read_line_marker(Token **rest, Token *tok) {
Token *start = tok;
tok = preprocess(copy_line(rest, tok));
if (tok->kind != TK_NUM || tok->ty->kind != TY_INT)
error_tok(tok, "invalid line marker");
start->file->line_delta = tok->val - start->line_no;
tok = tok->next;
if (tok->kind == TK_EOF)
return;
if (tok->kind != TK_STR)
error_tok(tok, "filename expected");
start->file->display_name = tok->str;
}
// Visit all tokens in `tok` while evaluating preprocessing
// macros and directives.
static Token *preprocess2(Token *tok) {
Token head = {};
Token *cur = &head;
while (tok->kind != TK_EOF) {
// If it is a macro, expand it.
if (expand_macro(&tok, tok))
continue;
// Pass through if it is not a "#".
if (!is_hash(tok)) {
tok->line_delta = tok->file->line_delta;
tok->filename = tok->file->display_name;
cur = cur->next = tok;
tok = tok->next;
continue;
}
Token *start = tok;
tok = tok->next;
if (equal(tok, "include")) {
bool is_dquote;
char *filename = read_include_filename(&tok, tok->next, &is_dquote);
if (filename[0] != '/' && is_dquote) {
char *path = format("%s/%s", dirname(strdup(start->file->name)), filename);
if (file_exists(path)) {
tok = include_file(tok, path, start->next->next);
continue;
}
}
char *path = search_include_paths(filename);
tok = include_file(tok, path ? path : filename, start->next->next);
continue;
}
if (equal(tok, "include_next")) {
bool ignore;
char *filename = read_include_filename(&tok, tok->next, &ignore);
char *path = search_include_next(filename);
tok = include_file(tok, path ? path : filename, start->next->next);
continue;
}
if (equal(tok, "define")) {
read_macro_definition(&tok, tok->next);
continue;
}
if (equal(tok, "undef")) {
tok = tok->next;
if (tok->kind != TK_IDENT)
error_tok(tok, "macro name must be an identifier");
undef_macro(strndup(tok->loc, tok->len));
tok = skip_line(tok->next);
continue;
}
if (equal(tok, "if")) {
long val = eval_const_expr(&tok, tok);
push_cond_incl(start, val);
if (!val)
tok = skip_cond_incl(tok);
continue;
}
if (equal(tok, "ifdef")) {
bool defined = find_macro(tok->next);
push_cond_incl(tok, defined);
tok = skip_line(tok->next->next);
if (!defined)
tok = skip_cond_incl(tok);
continue;
}
if (equal(tok, "ifndef")) {
bool defined = find_macro(tok->next);
push_cond_incl(tok, !defined);
tok = skip_line(tok->next->next);
if (defined)
tok = skip_cond_incl(tok);
continue;
}
if (equal(tok, "elif")) {
if (!cond_incl || cond_incl->ctx == IN_ELSE)
error_tok(start, "stray #elif");
cond_incl->ctx = IN_ELIF;
if (!cond_incl->included && eval_const_expr(&tok, tok))
cond_incl->included = true;
else
tok = skip_cond_incl(tok);
continue;
}
if (equal(tok, "else")) {
if (!cond_incl || cond_incl->ctx == IN_ELSE)
error_tok(start, "stray #else");
cond_incl->ctx = IN_ELSE;
tok = skip_line(tok->next);
if (cond_incl->included)
tok = skip_cond_incl(tok);
continue;
}
if (equal(tok, "endif")) {
if (!cond_incl)
error_tok(start, "stray #endif");
cond_incl = cond_incl->next;
tok = skip_line(tok->next);
continue;
}
if (equal(tok, "line")) {
read_line_marker(&tok, tok->next);
continue;
}
if (tok->kind == TK_PP_NUM) {
read_line_marker(&tok, tok);
continue;
}
if (equal(tok, "pragma") && equal(tok->next, "once")) {
hashmap_put(&pragma_once, tok->file->name, (void *)1);
tok = skip_line(tok->next->next);
continue;
}
if (equal(tok, "pragma")) {
do {
tok = tok->next;
} while (!tok->at_bol);
continue;
}
if (equal(tok, "error"))
error_tok(tok, "error");
// `#`-only line is legal. It's called a null directive.
if (tok->at_bol)
continue;
error_tok(tok, "invalid preprocessor directive");
}
cur->next = tok;
return head.next;
}
void define_macro(char *name, char *buf) {
Token *tok = tokenize(new_file("<built-in>", 1, buf));
add_macro(name, true, tok);
}
void undef_macro(char *name) {
hashmap_delete(&macros, name);
}
static Macro *add_builtin(char *name, macro_handler_fn *fn) {
Macro *m = add_macro(name, true, NULL);
m->handler = fn;
return m;
}
static Token *file_macro(Token *tmpl) {
while (tmpl->origin)
tmpl = tmpl->origin;
return new_str_token(tmpl->file->display_name, tmpl);
}
static Token *line_macro(Token *tmpl) {
while (tmpl->origin)
tmpl = tmpl->origin;
int i = tmpl->line_no + tmpl->file->line_delta;
return new_num_token(i, tmpl);
}
// __COUNTER__ is expanded to serial values starting from 0.
static Token *counter_macro(Token *tmpl) {
static int i = 0;
return new_num_token(i++, tmpl);
}
// __TIMESTAMP__ is expanded to a string describing the last
// modification time of the current file. E.g.
// "Fri Jul 24 01:32:50 2020"
static Token *timestamp_macro(Token *tmpl) {
struct stat st;
if (stat(tmpl->file->name, &st) != 0)
return new_str_token("??? ??? ?? ??:??:?? ????", tmpl);
char buf[30];
ctime_r(&st.st_mtime, buf);
buf[24] = '\0';
return new_str_token(buf, tmpl);
}
static Token *base_file_macro(Token *tmpl) {
return new_str_token(base_file, tmpl);
}
// __DATE__ is expanded to the current date, e.g. "May 17 2020".
static char *format_date(struct tm *tm) {
static char mon[][4] = {
"Jan", "Feb", "Mar", "Apr", "May", "Jun",
"Jul", "Aug", "Sep", "Oct", "Nov", "Dec",
};
return format("\"%s %2d %d\"", mon[tm->tm_mon], tm->tm_mday, tm->tm_year + 1900);
}
// __TIME__ is expanded to the current time, e.g. "13:34:03".
static char *format_time(struct tm *tm) {
return format("\"%02d:%02d:%02d\"", tm->tm_hour, tm->tm_min, tm->tm_sec);
}
void init_macros(void) {
// Define predefined macros
define_macro("_LP64", "1");
define_macro("__C99_MACRO_WITH_VA_ARGS", "1");
define_macro("__ELF__", "1");
define_macro("__LP64__", "1");
define_macro("__SIZEOF_DOUBLE__", "8");
define_macro("__SIZEOF_FLOAT__", "4");
define_macro("__SIZEOF_INT__", "4");
define_macro("__SIZEOF_LONG_DOUBLE__", "8");
define_macro("__SIZEOF_LONG_LONG__", "8");
define_macro("__SIZEOF_LONG__", "8");
define_macro("__SIZEOF_POINTER__", "8");
define_macro("__SIZEOF_PTRDIFF_T__", "8");
define_macro("__SIZEOF_SHORT__", "2");
define_macro("__SIZEOF_SIZE_T__", "8");
define_macro("__SIZE_TYPE__", "unsigned long");
define_macro("__STDC_HOSTED__", "1");
define_macro("__STDC_NO_COMPLEX__", "1");
define_macro("__STDC_UTF_16__", "1");
define_macro("__STDC_UTF_32__", "1");
define_macro("__STDC_VERSION__", "201112L");
define_macro("__STDC__", "1");
define_macro("__USER_LABEL_PREFIX__", "");
define_macro("__alignof__", "_Alignof");
define_macro("__amd64", "1");
define_macro("__amd64__", "1");
define_macro("__chibicc__", "1");
define_macro("__const__", "const");
define_macro("__gnu_linux__", "1");
define_macro("__inline__", "inline");
define_macro("__linux", "1");
define_macro("__linux__", "1");
define_macro("__signed__", "signed");
define_macro("__typeof__", "typeof");
define_macro("__unix", "1");
define_macro("__unix__", "1");
define_macro("__volatile__", "volatile");
define_macro("__x86_64", "1");
define_macro("__x86_64__", "1");
define_macro("linux", "1");
define_macro("unix", "1");
add_builtin("__FILE__", file_macro);
add_builtin("__LINE__", line_macro);
add_builtin("__COUNTER__", counter_macro);
add_builtin("__TIMESTAMP__", timestamp_macro);
add_builtin("__BASE_FILE__", base_file_macro);
time_t now = time(NULL);
struct tm *tm = localtime(&now);
define_macro("__DATE__", format_date(tm));
define_macro("__TIME__", format_time(tm));
}
typedef enum {
STR_NONE, STR_UTF8, STR_UTF16, STR_UTF32, STR_WIDE,
} StringKind;
static StringKind getStringKind(Token *tok) {
if (!strcmp(tok->loc, "u8"))
return STR_UTF8;
switch (tok->loc[0]) {
case '"': return STR_NONE;
case 'u': return STR_UTF16;
case 'U': return STR_UTF32;
case 'L': return STR_WIDE;
}
unreachable();
}
// Concatenate adjacent string literals into a single string literal
// as per the C spec.
static void join_adjacent_string_literals(Token *tok) {
// First pass: If regular string literals are adjacent to wide
// string literals, regular string literals are converted to a wide
// type before concatenation. In this pass, we do the conversion.
for (Token *tok1 = tok; tok1->kind != TK_EOF;) {
if (tok1->kind != TK_STR || tok1->next->kind != TK_STR) {
tok1 = tok1->next;
continue;
}
StringKind kind = getStringKind(tok1);
Type *basety = tok1->ty->base;
for (Token *t = tok1->next; t->kind == TK_STR; t = t->next) {
StringKind k = getStringKind(t);
if (kind == STR_NONE) {
kind = k;
basety = t->ty->base;
} else if (k != STR_NONE && kind != k) {
error_tok(t, "unsupported non-standard concatenation of string literals");
}
}
if (basety->size > 1)
for (Token *t = tok1; t->kind == TK_STR; t = t->next)
if (t->ty->base->size == 1)
*t = *tokenize_string_literal(t, basety);
while (tok1->kind == TK_STR)
tok1 = tok1->next;
}
// Second pass: concatenate adjacent string literals.
for (Token *tok1 = tok; tok1->kind != TK_EOF;) {
if (tok1->kind != TK_STR || tok1->next->kind != TK_STR) {
tok1 = tok1->next;
continue;
}
Token *tok2 = tok1->next;
while (tok2->kind == TK_STR)
tok2 = tok2->next;
int len = tok1->ty->array_len;
for (Token *t = tok1->next; t != tok2; t = t->next)
len = len + t->ty->array_len - 1;
char *buf = calloc(tok1->ty->base->size, len);
int i = 0;
for (Token *t = tok1; t != tok2; t = t->next) {
memcpy(buf + i, t->str, t->ty->size);
i = i + t->ty->size - t->ty->base->size;
}
*tok1 = *copy_token(tok1);
tok1->ty = array_of(tok1->ty->base, len);
tok1->str = buf;
tok1->next = tok2;
tok1 = tok2;
}
}
// Entry point function of the preprocessor.
Token *preprocess(Token *tok) {
tok = preprocess2(tok);
if (cond_incl)
error_tok(cond_incl->tok, "unterminated conditional directive");
convert_pp_tokens(tok);
join_adjacent_string_literals(tok);
for (Token *t = tok; t; t = t->next)
t->line_no += t->line_delta;
return tok;
}