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|
/*
Copyright (C) 2019, 2020 Leo Tenenbaum.
This file is part of toc. toc is distributed under version 3 of the GNU General Public License, without any warranty whatsoever.
You should have received a copy of the GNU General Public License along with toc. If not, see <https://www.gnu.org/licenses/>.
*/
static Status types_stmt(Typer *tr, Statement *s);
static Status type_resolve(Typer *tr, Type *t, Location where);
static inline void *typer_malloc(Typer *tr, size_t bytes) {
return allocr_malloc(tr->allocr, bytes);
}
static inline void *typer_calloc(Typer *tr, size_t n, size_t sz) {
return allocr_calloc(tr->allocr, n, sz);
}
static inline void *typer_arr_add_(Typer *tr, void **arr, size_t sz) {
return arr_adda_(arr, sz, tr->allocr);
}
static inline void typer_block_enter(Typer *tr, Block *b) {
*(Block **)arr_adda(&tr->blocks, tr->allocr) = b;
tr->block = b;
}
static inline void typer_block_exit(Typer *tr) {
arr_remove_lasta(&tr->blocks, tr->allocr);
tr->block = *(Block **)arr_last(tr->blocks);
}
static size_t compiler_sizeof_builtin(BuiltinType b) {
switch (b) {
case BUILTIN_I8: return sizeof(I8);
case BUILTIN_U8: return sizeof(U8);
case BUILTIN_I16: return sizeof(I16);
case BUILTIN_U16: return sizeof(U16);
case BUILTIN_I32: return sizeof(I32);
case BUILTIN_U32: return sizeof(U32);
case BUILTIN_I64: return sizeof(I64);
case BUILTIN_U64: return sizeof(U64);
case BUILTIN_F32: return sizeof(F32);
case BUILTIN_F64: return sizeof(F64);
case BUILTIN_CHAR: return sizeof(char); /* = 1 */
case BUILTIN_BOOL: return sizeof(bool);
case BUILTIN_TYPE: return sizeof(Type *);
case BUILTIN_NMS: return sizeof(Namespace *);
case BUILTIN_VARARGS: return sizeof(VarArg *);
}
assert(0);
return 0;
}
static size_t compiler_alignof_builtin(BuiltinType b) {
switch (b) {
case BUILTIN_I8: return toc_alignof(I8);
case BUILTIN_U8: return toc_alignof(U8);
case BUILTIN_I16: return toc_alignof(I16);
case BUILTIN_U16: return toc_alignof(U16);
case BUILTIN_I32: return toc_alignof(I32);
case BUILTIN_U32: return toc_alignof(U32);
case BUILTIN_I64: return toc_alignof(I64);
case BUILTIN_U64: return toc_alignof(U64);
case BUILTIN_F32: return toc_alignof(F32);
case BUILTIN_F64: return toc_alignof(F64);
case BUILTIN_CHAR: return toc_alignof(char);
case BUILTIN_BOOL: return toc_alignof(bool);
case BUILTIN_TYPE: return toc_alignof(Type *);
case BUILTIN_NMS: return toc_alignof(Namespace *);
case BUILTIN_VARARGS: return toc_alignof(VarArg *);
}
assert(0);
return 0;
}
/* finds offsets and size */
static Status struct_find_offsets(StructDef *s) {
/* assume the align of a struct is the greatest align out of its children's */
if (!(s->flags & STRUCT_DEF_FOUND_OFFSETS)) {
if (s->flags & STRUCT_DEF_FINDING_OFFSETS) {
err_print(s->where, "Circular dependency in struct!");
return false;
}
s->flags |= STRUCT_DEF_FINDING_OFFSETS;
size_t bytes = 0;
size_t total_align = 1;
arr_foreach(s->fields, Field, f) {
size_t size = compiler_sizeof(f->type);
if (size == SIZE_MAX) {
info_print(f->where, "... while descending into this field of a struct.");
return false;
}
size_t falign = compiler_alignof(f->type);
if (falign > total_align)
total_align = falign;
/* align */
bytes += ((falign - bytes) % falign + falign) % falign; /* = -bytes mod falign */
assert(bytes % falign == 0);
f->offset = bytes;
/* add size */
bytes += size;
}
bytes += ((total_align - bytes) % total_align + total_align) % total_align; /* = -bytes mod align */
s->size = bytes;
s->align = total_align;
s->flags |= STRUCT_DEF_FOUND_OFFSETS;
}
return true;
}
static size_t compiler_alignof(Type *t) {
assert(t->flags & TYPE_IS_RESOLVED);
switch (t->kind) {
case TYPE_BUILTIN:
return compiler_alignof_builtin(t->builtin);
case TYPE_VOID:
return 1;
case TYPE_FN:
return toc_alignof(FnExpr *);
case TYPE_PTR:
return toc_alignof(void *);
case TYPE_TUPLE:
return toc_alignof(Value *);
case TYPE_ARR:
return compiler_alignof(t->arr.of);
case TYPE_SLICE:
if (sizeof(void *) > sizeof(size_t))
return toc_alignof(void *);
else
return toc_alignof(size_t);
case TYPE_STRUCT:
if (!struct_find_offsets(t->struc))
return SIZE_MAX;
return t->struc->align;
case TYPE_UNKNOWN:
case TYPE_EXPR:
break;
}
assert(0);
return 0;
}
/* size of a type at compile time */
static size_t compiler_sizeof(Type *t) {
Value v;
assert(t->flags & TYPE_IS_RESOLVED);
switch (t->kind) {
case TYPE_BUILTIN:
return compiler_sizeof_builtin(t->builtin);
case TYPE_FN:
return sizeof v.fn;
case TYPE_PTR:
return sizeof v.ptr;
case TYPE_ARR:
return t->arr.n * compiler_sizeof(t->arr.of);
case TYPE_TUPLE:
return sizeof v.tuple;
case TYPE_SLICE:
return sizeof v.slice;
case TYPE_STRUCT: {
if (!struct_find_offsets(t->struc))
return SIZE_MAX;
return t->struc->size;
} break;
case TYPE_VOID:
case TYPE_UNKNOWN:
return 0;
case TYPE_EXPR:
break;
}
assert(0);
return 0;
}
#define typer_arr_add(tr, a) typer_arr_add_(tr, (void **)(a), sizeof **(a))
static bool type_eq(Type *a, Type *b) {
if (a->kind == TYPE_UNKNOWN || b->kind == TYPE_UNKNOWN)
return true; /* allow things such as 3 + #C("5") */
assert(a->flags & TYPE_IS_RESOLVED);
assert(b->flags & TYPE_IS_RESOLVED);
if (a->kind != b->kind) return false;
if (b->flags & TYPE_IS_FLEXIBLE) {
Type *tmp = a;
a = b;
b = tmp;
}
if (a->flags & TYPE_IS_FLEXIBLE) {
if (b->flags & TYPE_IS_FLEXIBLE) return true;
assert(a->kind == TYPE_BUILTIN);
if (type_builtin_is_float(a->builtin)) {
return type_builtin_is_float(b->builtin);
}
assert(a->builtin == BUILTIN_I64);
return type_builtin_is_numerical(b->builtin);
}
switch (a->kind) {
case TYPE_VOID: return true;
case TYPE_UNKNOWN: assert(0); return false;
case TYPE_BUILTIN:
return a->builtin == b->builtin;
case TYPE_STRUCT:
return a->struc == b->struc;
case TYPE_FN: {
if (arr_len(a->fn.types) != arr_len(b->fn.types)) return false;
Type *a_types = a->fn.types, *b_types = b->fn.types;
Constness *a_constness = a->fn.constness, *b_constness = b->fn.constness;
for (size_t i = 0; i < arr_len(a->fn.types); ++i) {
Constness const_a = CONSTNESS_NO, const_b = CONSTNESS_NO;
if (a_constness)
const_a = a_constness[i];
if (b_constness)
const_b = b_constness[i];
if ((const_a == CONSTNESS_NO && const_b == CONSTNESS_YES)
|| (const_a == CONSTNESS_YES && const_b == CONSTNESS_NO))
return false;
if (!type_eq(&a_types[i], &b_types[i]))
return false;
}
return true;
}
case TYPE_TUPLE: {
if (arr_len(a->tuple) != arr_len(b->tuple)) return false;
Type *a_types = a->tuple, *b_types = b->tuple;
for (size_t i = 0; i < arr_len(a->tuple); ++i) {
if (!type_eq(&a_types[i], &b_types[i]))
return false;
}
return true;
}
case TYPE_ARR:
if (a->arr.n != b->arr.n) return false;
return type_eq(a->arr.of, b->arr.of);
case TYPE_SLICE:
return type_eq(a->slice, b->slice);
case TYPE_PTR:
return type_eq(a->ptr, b->ptr);
case TYPE_EXPR:
break;
}
assert(0);
return false;
}
/* expected must equal got, or an error will be produced */
static Status type_must_eq(Location where, Type *expected, Type *got) {
if (!type_eq(expected, got)) {
char *str_ex = type_to_str(expected);
char *str_got = type_to_str(got);
err_print(where, "Type mismatch: expected %s, but got %s.", str_ex, str_got);
return false;
}
return true;
}
/* prints an error and returns false if the given expression is not an l-value */
static Status expr_must_lval(Expression *e) {
/* NOTE: make sure you update eval when you change this */
switch (e->kind) {
case EXPR_IDENT: {
Identifier i = e->ident;
if (i->decl_kind == IDECL_DECL) {
Declaration *d = i->decl;
if (d->flags & DECL_IS_CONST) {
char *istr = ident_to_str(i);
err_print(e->where, "Use of constant %s as a non-constant expression.", istr);
info_print(d->where, "%s was declared here.", istr);
free(istr);
return false;
}
if (type_is_builtin(&d->type, BUILTIN_VARARGS)) {
char *istr = ident_to_str(i);
err_print(e->where, "varargs cannot be set or pointed to.");
info_print(d->where, "%s was declared here.", istr);
free(istr);
return false;
}
}
return true;
}
case EXPR_UNARY_OP:
if (e->unary.op == UNARY_DEREF) return true;
if (e->unary.op == UNARY_LEN) {
Type *of_type = &e->unary.of->type;
if (of_type->kind != TYPE_PTR && !expr_must_lval(e->unary.of)) { /* can't set length of a non-lvalue slice */
return false;
}
return of_type->kind == TYPE_SLICE
|| (of_type->kind == TYPE_PTR
&& of_type->kind == TYPE_SLICE);
}
err_print(e->where, "Cannot use operator %s as l-value.", unary_op_to_str(e->unary.op));
return false;
case EXPR_BINARY_OP:
switch (e->binary.op) {
case BINARY_AT_INDEX:
if (!expr_must_lval(e->binary.lhs))
return false;
if (type_is_builtin(&e->binary.lhs->type, BUILTIN_VARARGS)) {
err_print(e->where, "Cannot set or take address of vararg.");
return false;
}
return true;
case BINARY_DOT: return true;
default: break;
}
err_print(e->where, "Cannot use operator %s as l-value.", binary_op_to_str(e->binary.op));
return false;
case EXPR_TUPLE:
/* x, y is an lval, but 3, "hello" is not. */
arr_foreach(e->tuple, Expression, x) {
if (!expr_must_lval(x))
return false;
}
return true;
default: {
err_print(e->where, "Cannot use %s as l-value.", expr_kind_to_str(e->kind));
return false;
}
}
assert(0);
return false;
}
/* does this type have a Type or a Namespace in it? (e.g. [5]Type, &&Namespace) */
static bool type_is_compileonly(Type *t) {
assert(t->flags & TYPE_IS_RESOLVED);
switch (t->kind) {
case TYPE_VOID:
case TYPE_UNKNOWN:
return false;
case TYPE_BUILTIN:
return t->builtin == BUILTIN_TYPE || t->builtin == BUILTIN_NMS;
case TYPE_PTR:
return type_is_compileonly(t->ptr);
case TYPE_SLICE:
return type_is_compileonly(t->slice);
case TYPE_ARR:
return type_is_compileonly(t->arr.of);
case TYPE_FN:
arr_foreach(t->fn.types, Type, sub) {
if (sub->flags & TYPE_IS_RESOLVED) /* for templates */ {
if (type_is_compileonly(sub))
return true;
} else {
return true;
}
}
return false;
case TYPE_TUPLE:
arr_foreach(t->tuple, Type, sub)
if (type_is_compileonly(sub))
return true;
return false;
case TYPE_STRUCT:
return false; /* structs can only have non-compileonly members */
case TYPE_EXPR: break;
}
assert(0);
return false;
}
/* returns NULL if an error occured */
static char *eval_expr_as_cstr(Typer *tr, Expression *e, const char *what_is_this) {
Value e_val;
if (!types_expr(tr, e))
return NULL;
if (!type_is_slicechar(&e->type)) {
char *got = type_to_str(&e->type);
err_print(e->where, "Expected []char for %s, but got %s.", what_is_this, got);
free(got);
return NULL;
}
if (!eval_expr(tr->evalr, e, &e_val))
return NULL;
Slice e_slice = e_val.slice;
char *str = typer_malloc(tr, (size_t)e_slice.n + 1);
str[e_slice.n] = 0;
memcpy(str, e_slice.data, (size_t)e_slice.n);
return str;
}
enum {
/* is f an instance? (changes behaviour a bit) */
TYPE_OF_FN_IS_INSTANCE = 0x01
};
static Status type_of_fn(Typer *tr, FnExpr *f, Type *t, U16 flags) {
if (f->flags & FN_EXPR_FOREIGN) {
/* we've already mostly determined the type in parse_expr */
if (!type_resolve(tr, &f->foreign.type, f->where))
return false;
*t = f->foreign.type;
char *name_cstr = eval_expr_as_cstr(tr, f->foreign.name_expr, "foreign name");
if (!name_cstr)
return false;
f->foreign.name = name_cstr;
if (f->foreign.lib_expr) {
char *lib_cstr = eval_expr_as_cstr(tr, f->foreign.lib_expr, "foreign library name");
if (!lib_cstr)
return false;
f->foreign.lib = lib_cstr;
} else {
f->foreign.lib = NULL;
}
return true;
}
t->kind = TYPE_FN;
t->fn.types = NULL;
t->fn.constness = NULL; /* OPTIM: constness doesn't need to be a dynamic array */
t->flags = 0;
bool success = true;
bool entered_fn = false;
size_t param_idx;
FnExpr *prev_fn = tr->fn;
FnExpr fn_copy = {0};
Declaration *last_param = arr_last(f->params);
bool has_varargs = last_param && (last_param->flags & DECL_ANNOTATES_TYPE) && type_is_builtin(&last_param->type, BUILTIN_VARARGS);
if (has_varargs)
f->flags |= FN_EXPR_HAS_VARARGS;
/* f has compile time params/varargs, but it's not an instance! */
bool generic = !(flags & TYPE_OF_FN_IS_INSTANCE) && (fn_has_any_const_params(f) || has_varargs);
if (generic) {
Copier cop = copier_create(tr->allocr, &f->body);
copy_fn_expr(&cop, &fn_copy, f, COPY_FN_EXPR_DONT_COPY_BODY);
f = &fn_copy;
}
size_t idx = 0;
bool has_constant_params = false;
Type *ret_type = typer_arr_add(tr, &t->fn.types);
tr->fn = f;
typer_block_enter(tr, &f->body);
size_t nparams = arr_len(f->params);
entered_fn = true;
for (param_idx = 0; param_idx < nparams; ++param_idx) {
Declaration *param = &f->params[param_idx];
if (!generic) {
if (!types_decl(tr, param)) {
success = false;
goto ret;
}
if (type_is_builtin(¶m->type, BUILTIN_VARARGS)) {
if (param_idx != nparams-1 || arr_len(param->idents) > 1) {
err_print(param->where, "varargs must be the last parameter to a function.");
success = false;
goto ret;
}
}
if (param->flags & DECL_HAS_EXPR) {
if (param->expr.kind != EXPR_VAL) {
Value val;
if (!eval_expr(tr->evalr, ¶m->expr, &val)) {
info_print(param->where, "Was trying to evaluate default arguments (which must be constants!)");
success = false;
goto ret;
}
param->expr.kind = EXPR_VAL;
param->expr.val = val;
if (param->expr.type.flags & TYPE_IS_FLEXIBLE) {
/* cast to the annotated type, if one exists */
if (param->flags & DECL_ANNOTATES_TYPE) {
val_cast(¶m->expr.val, ¶m->expr.type, ¶m->expr.val, ¶m->type);
param->expr.type = param->type;
}
}
}
}
}
U32 is_at_all_const = param->flags & (DECL_IS_CONST | DECL_SEMI_CONST);
if (is_at_all_const) {
if (!t->fn.constness) {
has_constant_params = true;
for (size_t i = 0; i < idx; ++i) {
*(Constness *)typer_arr_add(tr, &t->fn.constness) = CONSTNESS_NO;
}
}
}
for (size_t i = 0; i < arr_len(param->idents); ++i) {
Type *param_type = typer_arr_add(tr, &t->fn.types);
if (param->flags & (DECL_ANNOTATES_TYPE|DECL_FOUND_TYPE))
*param_type = param->type;
else
param_type->kind = TYPE_UNKNOWN;
if (has_constant_params) {
Constness constn;
if (param->flags & DECL_IS_CONST) {
constn = CONSTNESS_YES;
} else if (param->flags & DECL_SEMI_CONST) {
constn = CONSTNESS_SEMI;
} else {
constn = CONSTNESS_NO;
}
*(Constness *)typer_arr_add(tr, &t->fn.constness) = constn;
}
++idx;
}
}
if (f->ret_decls && !generic && f->ret_type.kind == TYPE_VOID /* haven't found return type yet */) {
/* find return type */
arr_foreach(f->ret_decls, Declaration, d) {
if (!types_decl(tr, d)) {
success = false;
goto ret;
}
}
if (arr_len(f->ret_decls) == 1 && arr_len(f->ret_decls[0].idents) == 1) {
f->ret_type = f->ret_decls[0].type;
} else {
f->ret_type.kind = TYPE_TUPLE;
f->ret_type.flags = TYPE_IS_RESOLVED;
f->ret_type.was_expr = NULL;
f->ret_type.tuple = NULL;
arr_foreach(f->ret_decls, Declaration, d) {
arr_foreach(d->idents, Identifier, i) {
*(Type *)arr_add(&f->ret_type.tuple) = d->type;
}
}
}
}
if (!generic) {
if (!type_resolve(tr, &f->ret_type, f->where)) {
success = false;
goto ret;
}
if (type_is_builtin(&f->ret_type, BUILTIN_VARARGS)) {
err_print(f->where, "Functions cannot return varargs.");
success = false;
goto ret;
}
if (type_is_compileonly(&f->ret_type)) {
if (type_is_builtin(&f->ret_type, BUILTIN_NMS)) {
err_print(f->where, "Functions cannot return namespaces.");
success = false;
goto ret;
}
/*
a function which returns a compile-only type but has non-constant parameters is weird...
but might be useful, so let's warn
*/
arr_foreach(f->params, Declaration, param) {
if (!(param->flags & DECL_IS_CONST)) {
char *s = type_to_str(&f->ret_type);
warn_print(param->where, "Non-constant parameter in function which returns %s (which is a type which can only be used at run time).", s);
free(s);
break;
}
}
}
t->flags |= TYPE_IS_RESOLVED;
}
*ret_type = f->ret_type;
ret:
/* cleanup */
typer_block_exit(tr);
if (entered_fn) {
tr->fn = prev_fn;
}
return success;
}
/* may modify ident */
static Status type_of_ident(Typer *tr, Location where, Identifier *ident, Type *t) {
t->flags = 0;
Identifier i = *ident;
Block *b = tr->block;
bool undeclared = false;
UsedExpr *used = arr_last(tr->used);
while (1) { /* for each block we are inside... */
/* OPTIM: only hash once */
Identifier translated = ident_translate(i, b ? &b->idents : tr->globals);
if (translated && translated->decl_kind == IDECL_NONE)
translated = NULL;
Statement *translated_is_from_use_stmt = NULL;
while (used && used->scope == b) {
/* look up identifier in this used thing. */
Statement *stmt = used->stmt;
Expression *expr = &stmt->use;
Type *type = &expr->type;
if (type->kind == TYPE_STRUCT) {
/* TODO */
} else {
assert(type_is_builtin(type, BUILTIN_NMS));
assert(expr->kind == EXPR_VAL);
Identifier nms_ident = ident_translate(i, &expr->val.nms->body.idents);
if (nms_ident && nms_ident->decl_kind != IDECL_NONE) {
if (translated) {
/* ambiguous ident reference */
char *s = ident_to_str(nms_ident);
err_print(where, "Ambiguous reference to identifier %s.", s);
info_print(stmt->where, "%s was imported from this use statement.", s);
info_print(ident_decl_location(tr->file, nms_ident), "Specifically, it was declared here.");
/*
we should have given an error about the use statement if it conflicted with a non-used ident,
so translated must be from another use stmt.
*/
assert(translated_is_from_use_stmt);
info_print(translated_is_from_use_stmt->where, "...and also imported from *this* use statement.");
info_print(ident_decl_location(tr->file, translated), "Specifically, it was also declared here.");
}
translated = nms_ident;
translated_is_from_use_stmt = stmt;
}
}
if (used > tr->used)
--used;
else
used = NULL;
}
if (translated) {
#if 0
printf("translated %s from\n", ident_to_str(i));
print_block_location(i->idents->scope);
printf(" to \n");
print_block_location(translated->idents->scope);
#endif
i = *ident = translated;
break;
}
if (b) {
b = b->parent;
} else {
undeclared = true;
break;
}
}
if (undeclared) {
char *s = ident_to_str(i);
err_print(where, "Undeclared identifier: %s", s);
free(s);
return false;
}
switch (i->decl_kind) {
case IDECL_DECL: {
Declaration *d = i->decl;
bool captured = false;
if (ident_scope(i) != NULL && !(ident_scope(i)->flags & BLOCK_IS_NMS)) {
Block *decl_scope = ident_scope(i);
if (!(decl_scope->flags & BLOCK_IS_NMS)) {
/* go back through scopes */
for (Block **block = arr_last(tr->blocks); *block && *block != decl_scope; --block) {
if ((*block)->flags & BLOCK_IS_FN) {
captured = true;
break;
}
}
}
}
if (captured && !(d->flags & DECL_IS_CONST)) {
err_print(where, "Variables cannot be captured into inner functions (but constants can).");
return false;
}
if ((d->flags & DECL_HAS_EXPR) && (d->expr.kind == EXPR_TYPE)) {
/* allow using a type before declaring it */
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_TYPE;
t->flags = TYPE_IS_RESOLVED;
return true;
}
/* are we inside this declaration? */
arr_foreach(tr->in_decls, DeclarationPtr, in_decl) {
if (d == *in_decl) {
/* d needn't have an expression, because it could be its type that refers to itself */
if ((d->flags & DECL_HAS_EXPR) && d->expr.kind == EXPR_FN) {
/* it's okay if a function references itself */
} else {
/* if we've complained about it before when we were figuring out the type, don't complain again */
if (!(d->flags & DECL_ERRORED_ABOUT_SELF_REFERENCE)) {
char *s = ident_to_str(i);
err_print(where, "Use of identifier %s in its own declaration.", s);
free(s);
info_print(d->where, "Declaration was here.");
d->flags |= DECL_ERRORED_ABOUT_SELF_REFERENCE;
}
return false;
}
}
}
if (d->flags & DECL_FOUND_TYPE) {
*t = *decl_type_at_index(d, decl_ident_index(d, i));
assert(t->flags & TYPE_IS_RESOLVED);
return true;
} else {
if ((d->flags & DECL_HAS_EXPR) && (d->expr.kind == EXPR_FN)) {
/* allow using a function before declaring it */
if (!type_of_fn(tr, d->expr.fn, &d->expr.type, 0)) return false;
*t = d->expr.type;
t->flags |= TYPE_IS_RESOLVED; /* for function templates */
return true;
} else {
if (where.start <= d->where.end) {
char *s = ident_to_str(i);
err_print(where, "Use of identifier %s before its declaration.", s);
info_print(d->where, "%s will be declared here.", s);
free(s);
return false;
} else {
if (d->flags & DECL_INFER) {
err_print(where, "Use of identifier before it has been inferred. You are trying to do stuff with inference which toc doesn't support.");
return false;
}
/* let's type the declaration, and redo this (for evaling future functions) */
if (!types_decl(tr, d)) return false;
return type_of_ident(tr, where, ident, t);
}
}
}
} break;
case IDECL_FOR: {
ForExpr *fo = i->decl_for;
/* are we inside this for loop? */
typedef ForExpr *ForExprPtr;
arr_foreach(tr->in_fors, ForExprPtr, in_f) {
if (*in_f == fo) {
char *s = ident_to_str(i);
err_print(where, "Use of identifier %s in its own declaration.", s);
free(s);
return false;
}
}
if (i == fo->index) {
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_I64;
t->flags = TYPE_IS_RESOLVED;
} else {
assert(i == fo->value);
*t = fo->type;
}
} break;
case IDECL_NONE: {
char *s = ident_to_str(i);
err_print(where, "Undeclared identifier: %s", s);
free(s);
return false;
}
}
return true;
}
static Status add_block_to_struct(Typer *tr, Block *b, StructDef *s) {
arr_foreach(b->stmts, Statement, stmt) {
if (stmt->kind == STMT_EXPR) {
if (stmt->expr.kind == EXPR_BLOCK) {
if (!add_block_to_struct(tr, stmt->expr.block, s))
return false;
continue;
}
}
if (stmt->kind != STMT_DECL) {
err_print(stmt->where, "structs can only contain declarations.");
return false;
}
Declaration *d = stmt->decl;
DeclFlags flags = d->flags;
if (flags & DECL_EXPORT) {
err_print(d->where, "struct members can't be exported.");
return false;
}
if (flags & DECL_IS_CONST) {
if (flags & DECL_INFER) {
err_print(d->where, "struct members can't be inferred.");
return false;
}
*(Declaration **)typer_arr_add(tr, &s->constants) = d;
} else {
if (flags & DECL_SEMI_CONST) {
err_print(d->where, "struct members can't be semi-constant.");
return false;
}
if (flags & DECL_HAS_EXPR) {
err_print(d->where, "Non-constant struct members can't have initializers.");
return false;
}
int i = 0;
arr_foreach(d->idents, Identifier, ident) {
Field *field = typer_arr_add(tr, &s->fields);
field->where = d->where;
field->name = *ident;
field->type = decl_type_at_index(d, i);
++i;
}
}
if (b != &s->scope) {
/* we need to translate d's identifiers to s's scope */
arr_foreach(d->idents, Identifier, ip) {
Identifier redeclared = ident_get(&s->scope.idents, (*ip)->str);
if (redeclared && redeclared->decl_kind != IDECL_NONE) {
char *str = ident_to_str(*ip);
err_print(d->where, "Redeclaration of struct member %s", str);
info_print(ident_decl_location(d->where.file, redeclared), "Previous declaration was here.");
free(str);
return false;
}
*ip = ident_translate_forced(*ip, &s->scope.idents);
(*ip)->decl_kind = IDECL_DECL;
(*ip)->decl = d;
}
}
}
return true;
}
/* fixes the type (replaces [5+3]int with [8]int, etc.) */
static Status type_resolve(Typer *tr, Type *t, Location where) {
Evaluator *ev = tr->evalr;
if (t->flags & TYPE_IS_RESOLVED) return true;
t->was_expr = NULL;
switch (t->kind) {
case TYPE_ARR: {
/* it's an array */
Value val;
Expression *n_expr = t->arr.n_expr;
if (!types_expr(tr, n_expr)) return false;
if (n_expr->type.kind == TYPE_UNKNOWN) {
err_print(n_expr->where, "Cannot determine type of array size at compile time.");
return false;
}
if (n_expr->type.kind != TYPE_BUILTIN || !type_builtin_is_int(n_expr->type.builtin)) {
char *s = type_to_str(&n_expr->type);
err_print(n_expr->where, "Cannot use type %s as the size of an array (it's not an integer type).", s);
free(s);
return false;
}
if (!eval_expr(ev, n_expr, &val))
return false;
U64 size;
if (type_builtin_is_signed(n_expr->type.builtin)) {
I64 ssize = val_to_i64(val, n_expr->type.builtin);
if (ssize < 0) {
err_print(t->arr.n_expr->where, "Negative array length (" I64_FMT ")", ssize);
return false;
}
size = (U64)ssize;
} else {
size = val_to_u64(val, n_expr->type.builtin);
}
t->arr.n = (U64)size;
if (!type_resolve(tr, t->arr.of, where))
return false;
} break;
case TYPE_FN:
arr_foreach(t->fn.types, Type, child_type) {
if (!type_resolve(tr, child_type, where))
return false;
}
break;
case TYPE_TUPLE:
arr_foreach(t->tuple, Type, child_type) {
if (!type_resolve(tr, child_type, where))
return false;
}
break;
case TYPE_PTR:
if (!type_resolve(tr, t->ptr, where))
return false;
break;
case TYPE_SLICE:
if (!type_resolve(tr, t->slice, where))
return false;
break;
case TYPE_STRUCT: {
StructDef *s = t->struc;
if (!(s->flags & STRUCT_DEF_RESOLVED)) {
if (!types_block(tr, &s->scope))
return false;
s->fields = NULL;
s->constants = NULL;
if (!add_block_to_struct(tr, &s->scope, s))
return false;
s->instance_id = 0;
s->flags |= STRUCT_DEF_RESOLVED;
}
} break;
case TYPE_EXPR: {
Value typeval;
if (!types_expr(tr, t->expr))
return false;
if (t->expr->type.kind == TYPE_UNKNOWN && tr->err_ctx->have_errored)
return false; /* silently fail (e.g. if a function couldn't be typed) */
if (!type_is_builtin(&t->expr->type, BUILTIN_TYPE)) {
err_print(t->expr->where, "This expression is not a type, but it's being used as one.");
return false;
}
Expression *expr = t->expr;
if (!eval_expr(tr->evalr, t->expr, &typeval))
return false;
*t = *typeval.type;
if (t->kind == TYPE_STRUCT) {
Declaration *params = t->struc->params;
if (params && !(params[0].flags & DECL_FOUND_VAL)) {
err_print(where, "Expected arguments to structure, but you didn't provide any.");
info_print(t->struc->where, "Structure was declared here.");
return false;
}
}
if (!(t->flags & TYPE_IS_RESOLVED)) {
/* this can happen with functions returning parameterized structs */
if (!type_resolve(tr, t, where))
return false;
}
t->was_expr = expr;
} break;
case TYPE_UNKNOWN:
case TYPE_VOID:
case TYPE_BUILTIN:
break;
}
if (t->kind == TYPE_STRUCT && !!(t->struc->params) == !!(t->struc->instance_id)) { /* don't want it to try to deal with templates */
if (!struct_find_offsets(t->struc))
return false;
}
assert(t->kind != TYPE_EXPR);
t->flags |= TYPE_IS_RESOLVED;
return true;
}
static bool type_can_be_truthy(Type *t) {
assert(t->flags & TYPE_IS_RESOLVED);
switch (t->kind) {
case TYPE_VOID:
case TYPE_TUPLE:
case TYPE_ARR:
case TYPE_STRUCT:
return false;
case TYPE_FN:
case TYPE_UNKNOWN:
case TYPE_PTR:
case TYPE_SLICE:
return true;
case TYPE_BUILTIN:
switch (t->builtin) {
case BUILTIN_TYPE:
case BUILTIN_NMS:
return false;
case BUILTIN_I8:
case BUILTIN_U8:
case BUILTIN_I16:
case BUILTIN_U16:
case BUILTIN_I32:
case BUILTIN_U32:
case BUILTIN_I64:
case BUILTIN_U64:
case BUILTIN_F32:
case BUILTIN_F64:
case BUILTIN_CHAR:
case BUILTIN_BOOL:
case BUILTIN_VARARGS:
return true;
}
case TYPE_EXPR:
break;
}
assert(0);
return false;
}
typedef enum {
CAST_STATUS_NONE,
CAST_STATUS_WARN,
CAST_STATUS_ERR
} CastStatus;
static CastStatus type_cast_status(Type *from, Type *to) {
assert(from->flags & TYPE_IS_RESOLVED);
assert(to->flags & TYPE_IS_RESOLVED);
if (to->kind == TYPE_UNKNOWN)
return CAST_STATUS_NONE;
switch (from->kind) {
case TYPE_UNKNOWN: return CAST_STATUS_NONE;
case TYPE_STRUCT:
case TYPE_VOID:
return CAST_STATUS_ERR;
case TYPE_BUILTIN:
switch (from->builtin) {
case BUILTIN_I8:
case BUILTIN_U8:
case BUILTIN_I16:
case BUILTIN_U16:
case BUILTIN_I32:
case BUILTIN_U32:
case BUILTIN_I64:
case BUILTIN_U64:
switch (to->kind) {
case TYPE_BUILTIN:
switch (to->builtin) {
case BUILTIN_I8:
case BUILTIN_U8:
case BUILTIN_I16:
case BUILTIN_U16:
case BUILTIN_I32:
case BUILTIN_U32:
case BUILTIN_I64:
case BUILTIN_U64:
case BUILTIN_F32:
case BUILTIN_F64:
case BUILTIN_BOOL:
case BUILTIN_CHAR:
return CAST_STATUS_NONE;
case BUILTIN_TYPE:
case BUILTIN_NMS:
case BUILTIN_VARARGS:
return CAST_STATUS_ERR;
}
assert(0);
break;
case TYPE_UNKNOWN:
return CAST_STATUS_NONE;
case TYPE_PTR:
return CAST_STATUS_WARN;
default:
return CAST_STATUS_ERR;
}
break;
case BUILTIN_F32:
case BUILTIN_F64:
if (to->kind != TYPE_BUILTIN) return CAST_STATUS_ERR;
switch (to->builtin) {
case BUILTIN_I8:
case BUILTIN_U8:
case BUILTIN_I16:
case BUILTIN_U16:
case BUILTIN_I32:
case BUILTIN_U32:
case BUILTIN_I64:
case BUILTIN_U64:
case BUILTIN_F32:
case BUILTIN_F64:
case BUILTIN_BOOL:
return CAST_STATUS_NONE;
case BUILTIN_CHAR:
case BUILTIN_TYPE:
case BUILTIN_NMS:
case BUILTIN_VARARGS:
return CAST_STATUS_ERR;
}
assert(0);
break;
case BUILTIN_CHAR:
if (to->kind == TYPE_BUILTIN && type_builtin_is_int(to->builtin))
return CAST_STATUS_NONE;
return CAST_STATUS_ERR;
case BUILTIN_BOOL:
return type_can_be_truthy(to) ? CAST_STATUS_NONE : CAST_STATUS_ERR;
case BUILTIN_TYPE:
case BUILTIN_NMS:
case BUILTIN_VARARGS:
return CAST_STATUS_ERR;
}
break;
case TYPE_TUPLE: return CAST_STATUS_ERR;
case TYPE_FN:
if (to->kind == TYPE_PTR || to->kind == TYPE_FN)
return CAST_STATUS_WARN;
return CAST_STATUS_ERR;
case TYPE_PTR:
if (to->kind == TYPE_BUILTIN && type_builtin_is_int(to->builtin))
return CAST_STATUS_WARN;
if (to->kind == TYPE_PTR)
return CAST_STATUS_NONE;
if (to->kind == TYPE_FN)
return CAST_STATUS_WARN;
/* TODO: Cast from ptr to arr */
return CAST_STATUS_ERR;
case TYPE_ARR:
return CAST_STATUS_ERR;
case TYPE_SLICE:
if (to->kind == TYPE_PTR && type_eq(from->slice, to->ptr))
return CAST_STATUS_NONE;
return CAST_STATUS_ERR;
case TYPE_EXPR:
break;
}
assert(0);
return CAST_STATUS_ERR;
}
static bool arg_is_const(Expression *arg, Constness constness) {
switch (constness) {
case CONSTNESS_NO: return false;
case CONSTNESS_SEMI: return expr_is_definitely_const(arg);
case CONSTNESS_YES: return true;
}
assert(0);
return false;
}
/* pass NULL for instance if this isn't an instance */
static Status types_fn(Typer *tr, FnExpr *f, Type *t, Instance *instance) {
if (f->flags & FN_EXPR_FOREIGN) return true;
FnExpr *prev_fn = tr->fn;
bool success = true;
Expression *ret_expr;
Type *ret_type;
bool has_named_ret_vals;
assert(t->kind == TYPE_FN);
if (instance) {
f = instance->fn;
} else {
if (t->fn.constness)
return true; /* don't type function body yet; we need to do that for every instance */
}
tr->fn = f;
if (!types_block(tr, &f->body)) {
success = false;
goto ret;
}
ret_expr = f->body.ret_expr;
ret_type = t->fn.types;
has_named_ret_vals = f->ret_decls != NULL;
if (ret_expr) {
if (!type_eq(ret_type, &ret_expr->type)) {
char *got = type_to_str(&ret_expr->type);
char *expected = type_to_str(ret_type);
err_print(ret_expr->where, "Returning type %s, but function returns type %s.", got, expected);
if (!instance) /* where will only actually be at the function declaration if it isn't
an instance. otherwise, where will be at the calling site, which will already be
printed */
info_print(f->where, "Function declaration is here.");
free(got); free(expected);
success = false;
goto ret;
}
if (ret_expr->type.kind == TYPE_UNKNOWN) {
/* maybe it's just unknown because something messed up (like typing another function),
and ??? is a placeholder */
if (!tr->err_ctx->have_errored) {
err_print(ret_expr->where, "Can't determine type of return value. Try assigning it to a variable before returning it.");
return false;
}
}
} else if (ret_type->kind != TYPE_VOID && !has_named_ret_vals) {
Statement *stmts = f->body.stmts;
if (arr_len(stmts)) {
Statement *last_stmt = (Statement *)stmts + (arr_len(stmts) - 1);
if (last_stmt->kind == STMT_RET) {
/*
last statement is a return, so it doesn't matter that the function has no return value
ideally this would handle if foo { return 5; } else { return 6; }
*/
success = true;
goto ret;
}
}
/* TODO: this should really be at the closing brace, and not the function declaration */
char *expected = type_to_str(ret_type);
err_print(token_location(f->body.where.file, f->body.where.end), "No return value in function which returns %s.", expected);
free(expected);
info_print(f->where, "Function was declared here:");
success = false;
goto ret;
}
ret:
tr->fn = prev_fn;
return success;
}
/* puts a dynamic array of the argument indices of the parameters into order. *order must be freed, even if function fails */
static Status call_arg_param_order(FnExpr *fn, Type *fn_type, Argument *args, Location where, I16 **orderp) {
*orderp = NULL;
assert(fn_type->flags & TYPE_IS_RESOLVED);
size_t nparams = arr_len(fn_type->fn.types)-1;
size_t nargs = arr_len(args);
if (nargs > nparams && !(fn->flags & FN_EXPR_HAS_VARARGS)) {
err_print(where, "Expected at most %lu argument%s to function, but got %lu.",
nparams, plural_suffix(nparams), nargs);
return false;
}
I16 *order = *orderp =
/* thanks, gcc, for making me do this! (getting erroneous -Walloc-size-larger-than) */
#if defined __GNUC__ && !defined __clang__
nparams > PTRDIFF_MAX ? NULL :
#endif
err_malloc(nparams * sizeof *order);
for (size_t i = 0; i < nparams; ++i)
order[i] = -1;
if (fn->flags & FN_EXPR_FOREIGN) {
I16 i = -1;
arr_foreach(args, Argument, arg) {
if (arg->name) {
err_print(arg->where, "Foreign function calls cannot use named arguments.");
return false;
}
*order++ = ++i;
}
return true;
}
int p = 0; /* counter for sequential parameters */
Declaration *param = fn->params;
size_t ident_idx = 0;
I16 arg_idx = -1;
arr_foreach(args, Argument, arg) {
++arg_idx;
bool named = arg->name != NULL;
int param_idx = -1;
Declaration *this_param;
if (named) {
/* named argument */
int index = 0;
bool found = false;
arr_foreach(fn->params, Declaration, pa) {
arr_foreach(pa->idents, Identifier, id) {
if (ident_eq_str(*id, arg->name)) {
if (type_is_builtin(&pa->type, BUILTIN_VARARGS)) {
err_print(arg->where, "varargs arguments cannot be named.");
return false;
}
this_param = pa;
found = true;
break;
}
++index;
}
if (found) break;
}
if (!found) {
char *name_end = arg->name + ident_str_len(arg->name);
/* temporarily null-terminate string to print it out */
char before = *name_end;
*name_end = 0;
err_print(arg->where, "Argument '%s' does not appear in declaration of function.", arg->name);
*name_end = before;
info_print(fn->where, "Declaration is here.");
return false;
}
param_idx = index;
} else {
/* move past inferred parameters because they must be named */
while (param < (Declaration *)arr_end(fn->params) && (param->flags & DECL_INFER)) {
++p;
++ident_idx;
if (ident_idx == arr_len(param->idents)) {
++param;
ident_idx = 0;
}
}
this_param = param;
if (param > (Declaration *)arr_last(fn->params)) {
err_print(arg->where, "Too many arguments to function!");
info_print(fn->where, "Declaration is here.");
return false;
}
param_idx = p;
}
if (type_is_builtin(&this_param->type, BUILTIN_VARARGS)) {
if (param_idx < (int)nparams && order[param_idx] == -1) {
order[param_idx] = arg_idx;
}
} else {
if (param_idx != -1) {
if (order[param_idx] != -1) {
err_print(arg->where, "Parameter #%d set twice.", param_idx+1);
info_print(args[order[param_idx]].where, "Parameter was previously set here.");
}
order[param_idx] = arg_idx;
}
}
if (!named) {
/* sequential order of parameters */
++p;
if (!type_is_builtin(¶m->type, BUILTIN_VARARGS)) {
++ident_idx;
if (ident_idx == arr_len(param->idents)) {
++param;
ident_idx = 0;
}
}
}
}
size_t param_idx = 0;
arr_foreach(fn->params, Declaration, decl) {
arr_foreach(decl->idents, Identifier, ident) {
if (order[param_idx] == -1) {
if ((decl->flags & DECL_ANNOTATES_TYPE) && type_is_builtin(&decl->type, BUILTIN_VARARGS)) {
order[param_idx] = (I16)nargs;
} else if (!(decl->flags & DECL_HAS_EXPR) && !(decl->flags & DECL_INFER)) {
char *s = ident_to_str(*ident);
err_print(where, "Parameter #%lu (%s) was not set in function call.", param_idx+1, s);
free(s);
return false;
}
}
++param_idx;
}
}
return true;
}
/*
*order must be freed, regardless of return value. if (*order)[i] == -1, that parameter was not set.
*/
static Status parameterized_struct_arg_order(StructDef *struc, Argument *args, I16 **order, Location where) {
size_t nargs = arr_len(args);
/*
it would be nice if this code and the code for arguments to normal functions
weren't split into two separate functions.
*/
size_t nparams = 0;
arr_foreach(struc->params, Declaration, param)
nparams += arr_len(param->idents);
*order = err_malloc(nparams * sizeof **order);
if (nargs > nparams) {
err_print(args[nparams].where, "Expected at most %lu argument%s to parameterized type, but got %lu.", nparams, plural_suffix(nparams), nargs);
return false;
}
for (size_t i = 0; i < nparams; ++i)
(*order)[i] = -1;
int p = 0; /* sequential parameter */
I16 argno = 0;
arr_foreach(args, Argument, arg) {
int param_idx;
if (arg->name) {
param_idx = 0;
arr_foreach(struc->params, Declaration, param) {
arr_foreach(param->idents, Identifier, ident) {
if (ident_eq_str(*ident, arg->name))
goto struct_params_done;
++param_idx;
}
}
struct_params_done:;
} else {
param_idx = p;
++p;
}
if ((*order)[param_idx] != -1) {
Identifier param_name = NULL;
int counter = param_idx;
arr_foreach(struc->params, Declaration, param) {
arr_foreach(param->idents, Identifier, ident) {
if (--counter < 0) {
param_name = *ident;
break;
}
}
if (param_name) break;
}
char *s = ident_to_str(param_name);
err_print(arg->where, "Parameter #%d (%s) set twice in parameterized type instantiation.", param_idx+1, s);
free(s);
return false;
}
(*order)[param_idx] = argno;
++argno;
}
p = 0;
arr_foreach(struc->params, Declaration, param) {
arr_foreach(param->idents, Identifier, ident) {
if ((*order)[p] == -1 && !(param->flags & DECL_HAS_EXPR)) {
char *s = ident_to_str(*ident);
err_print(where, "Parameter #%d (%s) not set in parameterized struct instantiation.", p+1, s);
free(s);
return false;
}
++p;
}
}
return true;
}
static Value get_builtin_val(BuiltinVal val) {
Value v;
switch (val) {
case BUILTIN_STDOUT:
v.ptr = stdout;
break;
case BUILTIN_STDERR:
v.ptr = stderr;
break;
case BUILTIN_STDIN:
v.ptr = stdin;
break;
case BUILTIN_COMPILING:
v.boolv = true;
break;
case BUILTIN_SIZEOF_SHORT:
v.i64 = (I64)sizeof(short);
break;
case BUILTIN_SIZEOF_INT:
v.i64 = (I64)sizeof(int);
break;
case BUILTIN_SIZEOF_LONG:
v.i64 = (I64)sizeof(long);
break;
case BUILTIN_SIZEOF_LONG_LONG:
v.i64 = (I64)sizeof(long long);
break;
case BUILTIN_SIZEOF_FLOAT:
v.i64 = (I64)sizeof(float);
break;
case BUILTIN_SIZEOF_DOUBLE:
v.i64 = (I64)sizeof(double);
break;
case BUILTIN_SIZEOF_LONG_DOUBLE:
v.i64 = (I64)sizeof(long double);
break;
case BUILTIN_SIZEOF_SIZE_T:
v.i64 = (I64)sizeof(size_t);
break;
/* TODO(eventually): fix these for cross compilation */
case BUILTIN_TSIZEOF_SHORT:
v.i64 = (I64)sizeof(short);
break;
case BUILTIN_TSIZEOF_INT:
v.i64 = (I64)sizeof(int);
break;
case BUILTIN_TSIZEOF_LONG:
v.i64 = (I64)sizeof(long);
break;
case BUILTIN_TSIZEOF_LONG_LONG:
v.i64 = (I64)sizeof(long long);
break;
case BUILTIN_TSIZEOF_FLOAT:
v.i64 = (I64)sizeof(float);
break;
case BUILTIN_TSIZEOF_DOUBLE:
v.i64 = (I64)sizeof(double);
break;
case BUILTIN_TSIZEOF_LONG_DOUBLE:
v.i64 = (I64)sizeof(long double);
break;
case BUILTIN_TSIZEOF_SIZE_T:
v.i64 =(I64)sizeof(size_t);
break;
}
return v;
}
static void get_builtin_val_type(Allocator *a, BuiltinVal val, Type *t) {
t->flags = TYPE_IS_RESOLVED;
switch (val) {
case BUILTIN_STDOUT:
case BUILTIN_STDERR:
case BUILTIN_STDIN:
/* use &u8 for FILE * */
t->kind = TYPE_PTR;
t->ptr = allocr_calloc(a, 1, sizeof *t->ptr);
t->ptr->flags = TYPE_IS_RESOLVED;
t->ptr->kind = TYPE_BUILTIN;
t->ptr->builtin = BUILTIN_U8;
break;
case BUILTIN_COMPILING:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_BOOL;
break;
case BUILTIN_SIZEOF_SHORT:
case BUILTIN_SIZEOF_INT:
case BUILTIN_SIZEOF_LONG:
case BUILTIN_SIZEOF_LONG_LONG:
case BUILTIN_SIZEOF_FLOAT:
case BUILTIN_SIZEOF_DOUBLE:
case BUILTIN_SIZEOF_LONG_DOUBLE:
case BUILTIN_TSIZEOF_SHORT:
case BUILTIN_TSIZEOF_INT:
case BUILTIN_TSIZEOF_LONG:
case BUILTIN_TSIZEOF_LONG_LONG:
case BUILTIN_TSIZEOF_FLOAT:
case BUILTIN_TSIZEOF_DOUBLE:
case BUILTIN_TSIZEOF_LONG_DOUBLE:
case BUILTIN_SIZEOF_SIZE_T:
case BUILTIN_TSIZEOF_SIZE_T:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_I64;
break;
}
}
/* gets a struct's constant or parameter, and puts it into e->val. */
static Status get_struct_constant(StructDef *struc, Identifier member, Expression *e) {
if (struc->params && !(struc->params[0].flags & DECL_FOUND_VAL)) {
err_print(e->where, "To access constants from a parameterized struct, you must supply its arguments.");
return false;
}
Identifier i = ident_translate(member, &struc->scope.idents);
if (!i || i->decl_kind == IDECL_NONE) {
char *member_s = ident_to_str(member);
char *struc_s = struc->name ? ident_to_str(struc->name) : "anonymous struct";
err_print(e->where, "%s is not a member of structure %s.", member_s, struc_s);
info_print(struc->where, "struct was declared here.");
free(member_s);
if (struc->name) free(struc_s);
return false;
}
assert((i->decl_kind == IDECL_DECL) && (i->decl->flags & DECL_IS_CONST));
if (i->decl->flags & DECL_FOUND_VAL) {
/* replace with decl value */
int ident_idx = decl_ident_index(i->decl, i);
e->kind = EXPR_VAL;
e->flags = EXPR_FOUND_TYPE;
e->val = *decl_val_at_index(i->decl, ident_idx);
e->type = *decl_type_at_index(i->decl, ident_idx);
return true;
} else {
char *member_s = ident_to_str(member);
char *struc_s = struc->name ? ident_to_str(struc->name) : "anonymous struct";
err_print(e->where, "Cannot get value %s from struct %s. Are you missing parameters to this struct?", member_s, struc_s);
return false;
}
}
static bool fn_type_has_varargs(FnType *f) {
return type_is_builtin(arr_last(f->types), BUILTIN_VARARGS);
}
static Status types_expr(Typer *tr, Expression *e) {
if (e->flags & EXPR_FOUND_TYPE) return true;
Type *t = &e->type;
t->flags = TYPE_IS_RESOLVED;
t->was_expr = NULL;
t->kind = TYPE_UNKNOWN; /* default to unknown type (in the case of an error) */
e->flags |= EXPR_FOUND_TYPE; /* even if failed, pretend we found the type */
switch (e->kind) {
case EXPR_FN: {
if (!type_of_fn(tr, e->fn, &e->type, 0)) {
return false;
}
if (fn_has_any_const_params(e->fn) || fn_type_has_varargs(&e->type.fn)) {
e->fn->instances = typer_calloc(tr, 1, sizeof *e->fn->instances);
t->flags |= TYPE_IS_RESOLVED; /* pretend this type is resolved, even though its children aren't to fix some assertions */
} else {
if (!types_fn(tr, e->fn, &e->type, NULL)) {
return false;
}
}
} break;
case EXPR_LITERAL_INT:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_I64;
t->flags |= TYPE_IS_FLEXIBLE;
break;
case EXPR_LITERAL_STR:
t->kind = TYPE_SLICE;
t->slice = typer_malloc(tr, sizeof *t->slice);
t->slice->flags = TYPE_IS_RESOLVED;
t->slice->was_expr = NULL;
t->slice->kind = TYPE_BUILTIN;
t->slice->builtin = BUILTIN_CHAR;
break;
case EXPR_LITERAL_FLOAT:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_F32;
t->flags |= TYPE_IS_FLEXIBLE;
break;
case EXPR_LITERAL_BOOL:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_BOOL;
break;
case EXPR_LITERAL_CHAR:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_CHAR;
break;
case EXPR_FOR: {
ForExpr *fo = e->for_;
bool in_header = true;
*(ForExpr **)typer_arr_add(tr, &tr->in_fors) = fo;
typer_block_enter(tr, &fo->body); /* while this block is being typed, fo->body will be in tr->blocks twice. hopefully that doesn't mess anything up! */
if (fo->flags & FOR_IS_RANGE) {
if (!types_expr(tr, fo->range.from)) goto for_fail;
{
Type *ft = &fo->range.from->type;
if (ft->kind != TYPE_BUILTIN || !type_builtin_is_numerical(ft->builtin)) {
char *s = type_to_str(ft);
err_print(e->where, "from expression of for loop must be a builtin numerical type, not %s", s);
free(s);
goto for_fail;
}
}
if (fo->range.step) {
if (!types_expr(tr, fo->range.step)) goto for_fail;
Type *st = &fo->range.step->type;
if (st->kind != TYPE_BUILTIN || !type_builtin_is_numerical(st->builtin)) {
char *s = type_to_str(st);
err_print(e->where, "step expression of for loop must be a builtin numerical type, not %s", s);
free(s);
goto for_fail;
}
}
if (fo->range.to) {
if (!types_expr(tr, fo->range.to)) goto for_fail;
Type *tt = &fo->range.to->type;
if (tt->kind != TYPE_BUILTIN || !type_builtin_is_numerical(tt->builtin)) {
char *s = type_to_str(tt);
err_print(e->where, "to expression of for loop must be a builtin numerical type, not %s", s);
free(s);
goto for_fail;
}
}
if (!(fo->flags & FOR_ANNOTATED_TYPE)) {
fo->type = fo->range.from->type;
}
if (!type_eq(&fo->type, &fo->range.from->type)) {
char *exp = type_to_str(&fo->type);
char *got = type_to_str(&fo->range.from->type);
err_print(e->where, "Type of for loop does not match the type of the from expression. Expected %s, but got %s.", exp, got);
free(exp); free(got);
goto for_fail;
}
if (fo->range.step && !type_eq(&fo->type, &fo->range.step->type)) {
char *exp = type_to_str(&fo->type);
char *got = type_to_str(&fo->range.step->type);
err_print(e->where, "Type of for loop does not match the type of the step expression. Expected %s, but got %s.", exp, got);
free(exp); free(got);
goto for_fail;
}
if ((fo->type.flags & TYPE_IS_FLEXIBLE) && fo->range.step)
fo->type = fo->range.step->type;
if (fo->range.to && !type_eq(&fo->type, &fo->range.to->type)) {
char *exp = type_to_str(&fo->type);
char *got = type_to_str(&fo->range.to->type);
err_print(e->where, "Type of for loop does not match the type of the to expression. Expected %s, but got %s.", exp, got);
free(exp); free(got);
goto for_fail;
}
if ((fo->type.flags & TYPE_IS_FLEXIBLE) && fo->range.to)
fo->type = fo->range.to->type;
fo->type.flags &= (TypeFlags)~(TypeFlags)TYPE_IS_FLEXIBLE;
} else {
if (!types_expr(tr, fo->of))
goto for_fail;
Type *iter_type = &fo->of->type;
bool uses_ptr = false;
if (iter_type->kind == TYPE_PTR) {
uses_ptr = true;
iter_type = iter_type->ptr;
}
switch (iter_type->kind) {
case TYPE_SLICE:
iter_type = iter_type->slice;
break;
case TYPE_ARR:
iter_type = iter_type->arr.of;
break;
case TYPE_BUILTIN:
switch (iter_type->builtin) {
case BUILTIN_VARARGS: {
/* exit for body */
typer_block_exit(tr);
arr_remove_lasta(&tr->in_fors, tr->allocr);
/* create one block, containing a block for each vararg */
/* e.g. for x := varargs { total += x; } => { { x := varargs[0]; total += x; } { x := varargs[0]; total += x; } } */
assert(fo->of->kind == EXPR_IDENT);
Identifier varargs_ident = fo->of->ident;
assert(varargs_ident->decl_kind == IDECL_DECL);
Declaration *idecl = varargs_ident->decl;
VarArg *varargs = idecl->val.varargs;
size_t nvarargs = arr_len(varargs);
/* create surrounding block */
e->kind = EXPR_BLOCK;
Block *b = e->block = typer_calloc(tr, 1, sizeof *e->block);
idents_create(&b->idents, tr->allocr, b);
b->stmts = NULL;
b->parent = tr->block;
b->where = e->where;
arr_set_lena(&b->stmts, nvarargs, tr->allocr);
Statement *stmt = b->stmts;
size_t nstmts = arr_len(fo->body.stmts);
bool has_val = fo->value != NULL;
bool has_index = fo->index != NULL;
for (size_t i = 0; i < nvarargs; ++i, ++stmt) {
/* create sub-block #i */
memset(stmt, 0, sizeof *stmt);
stmt->kind = STMT_EXPR;
stmt->expr.kind = EXPR_BLOCK;
Block *sub = stmt->expr.block = typer_calloc(tr, 1, sizeof *sub);
sub->parent = b;
idents_create(&sub->idents, tr->allocr, sub);
sub->stmts = NULL;
sub->where = e->where;
size_t total_nstmts = nstmts + has_val + has_index;
arr_set_lena(&sub->stmts, total_nstmts, tr->allocr);
Copier copier = copier_create(tr->allocr, sub);
if (has_val) {
/* TODO(eventually): don't put a decl in each block, just put one at the start */
Statement *s = &sub->stmts[0];
s->flags = 0;
s->kind = STMT_DECL;
s->where = e->where;
/* declare value */
Declaration *decl = s->decl = typer_calloc(tr, 1, sizeof *decl);
decl->where = fo->of->where;
Identifier ident = ident_translate_forced(fo->value, &sub->idents);
*(Identifier *)arr_adda(&decl->idents, tr->allocr) = ident;
ident->decl_kind = IDECL_DECL;
ident->decl = decl;
decl->flags |= DECL_HAS_EXPR;
decl->expr.kind = EXPR_BINARY_OP;
decl->expr.binary.op = BINARY_AT_INDEX;
decl->expr.binary.lhs = fo->of;
decl->expr.where = fo->of->where;
Expression *index = decl->expr.binary.rhs = typer_calloc(tr, 1, sizeof *decl->expr.binary.rhs);
index->kind = EXPR_LITERAL_INT;
index->intl = (U64)i;
index->where = fo->of->where;
}
if (has_index) {
/* TODO(eventually): don't put a decl in each block, just put one at the start */
Statement *s = &sub->stmts[has_val];
s->flags = 0;
s->kind = STMT_DECL;
s->where = e->where;
/* declare value */
Declaration *decl = s->decl = typer_calloc(tr, 1, sizeof *decl);
decl->where = fo->of->where;
Identifier ident = ident_translate_forced(fo->index, &sub->idents);
*(Identifier *)arr_adda(&decl->idents, tr->allocr) = ident;
ident->decl_kind = IDECL_DECL;
ident->decl = decl;
decl->flags |= DECL_HAS_EXPR;
decl->expr.kind = EXPR_LITERAL_INT;
decl->expr.intl = (U64)i;
decl->expr.where = fo->of->where;
}
size_t start = total_nstmts - nstmts;
for (size_t s = start; s < total_nstmts; ++s) {
copy_stmt(&copier, &sub->stmts[s], &fo->body.stmts[s-start]);
}
}
e->flags &= (ExprFlags)~(ExprFlags)EXPR_FOUND_TYPE;
/* type this new big block */
if (!types_expr(tr, e))
return false;
return true;
}
default: break;
}
/* fallthrough */
default: {
if (fo->of->type.kind == TYPE_UNKNOWN && tr->err_ctx->have_errored) {
/* silently fail */
goto for_fail;
}
char *s = type_to_str(&fo->of->type);
err_print(e->where, "Cannot iterate over non-array non-slice type %s.", s);
free(s);
goto for_fail;
}
}
Type ptr_type = {0};
if (uses_ptr) {
ptr_type.flags = TYPE_IS_RESOLVED;
ptr_type.kind = TYPE_PTR;
ptr_type.ptr = iter_type;
iter_type = &ptr_type;
}
if (fo->flags & FOR_ANNOTATED_TYPE) {
if (!type_eq(iter_type, &fo->type)) {
char *exp = type_to_str(iter_type);
char *got = type_to_str(&fo->type);
err_print(e->where, "Expected to iterate over type %s, but it was annotated as iterating over type %s.");
free(exp); free(got);
goto for_fail;
}
} else fo->type = *iter_type;
}
if ((fo->flags & FOR_IS_RANGE) && fo->range.step) {
Value *stepval = typer_malloc(tr, sizeof *fo->range.stepval);
if (!eval_expr(tr->evalr, fo->range.step, stepval)) {
info_print(fo->range.step->where, "Note that the step of a for loop must be a compile-time constant.");
goto for_fail;
}
val_cast(stepval, &fo->range.step->type, stepval, &fo->type);
fo->range.stepval = stepval;
}
arr_remove_lasta(&tr->in_fors, tr->allocr);
in_header = false;
if (!types_block(tr, &fo->body)) goto for_fail;
if (fo->body.ret_expr) {
err_print(fo->body.ret_expr->where, "for loops can't return values -- you're missing a semicolon (;)");
goto for_fail;
}
t->kind = TYPE_VOID;
typer_block_exit(tr);
break;
for_fail:
if (in_header)
arr_remove_lasta(&tr->in_fors, tr->allocr);
typer_block_exit(tr);
return false;
};
case EXPR_IDENT: {
if (!type_of_ident(tr, e->where, &e->ident, t)) return false;
} break;
case EXPR_CAST: {
CastExpr *c = &e->cast;
if (!types_expr(tr, c->expr))
return false;
if (!type_resolve(tr, &c->type, e->where))
return false;
CastStatus status = type_cast_status(&c->expr->type, &c->type);
if (status != CAST_STATUS_NONE) {
char *from = type_to_str(&c->expr->type);
char *to = type_to_str(&c->type);
if (status == CAST_STATUS_ERR)
err_print(e->where, "Cannot cast from type %s to %s.", from, to);
else
warn_print(e->where, "Casting from type %s to %s.", from, to);
free(from);
free(to);
if (status == CAST_STATUS_ERR)
return false;
}
*t = c->type;
} break;
case EXPR_IF: {
IfExpr *i = e->if_;
IfExpr *curr = i;
if (curr->flags & IF_STATIC) {
while (1) {
Expression *cond = curr->cond;
Expression *next = curr->next_elif;
Value v;
if (cond) {
if (!types_expr(tr, cond))
return false;
if (!eval_expr(tr->evalr, cond, &v))
return false;
}
if (!cond || val_truthiness(v, &cond->type)) {
Block *true_block = &curr->body;
e->kind = EXPR_BLOCK;
e->block = true_block;
break;
}
if (!next) break;
curr = next->if_;
}
if (e->kind == EXPR_IF) {
/* all conds were false */
e->kind = EXPR_BLOCK;
e->block = typer_calloc(tr, 1, sizeof *e->block);
e->block->where = e->where;
e->block->parent = tr->block;
idents_create(&e->block->idents, tr->allocr, e->block);
}
goto expr_block;
}
Type *curr_type = t;
bool has_else = false;
if (!types_block(tr, &curr->body))
return false;
if (curr->body.ret_expr) {
*t = curr->body.ret_expr->type;
} else {
t->kind = TYPE_VOID;
t->flags |= TYPE_IS_RESOLVED;
}
while (1) {
if (curr->cond) {
if (!types_expr(tr, curr->cond))
return false;
if (!type_can_be_truthy(&curr->cond->type)) {
char *s = type_to_str(&curr->cond->type);
err_print(curr->cond->where, "Type %s cannot be the condition of an if statement.", s);
free(s);
return false;
}
} else {
has_else = true;
}
if (curr->next_elif) {
IfExpr *nexti = curr->next_elif->if_;
Type *next_type = &curr->next_elif->type;
curr->next_elif->flags |= EXPR_FOUND_TYPE;
if (!types_block(tr, &nexti->body)) {
return false;
}
if (nexti->body.ret_expr) {
*next_type = nexti->body.ret_expr->type;
} else {
next_type->kind = TYPE_VOID;
next_type->flags = TYPE_IS_RESOLVED;
next_type->was_expr = NULL;
}
if (!type_eq(curr_type, next_type)) {
char *currstr = type_to_str(curr_type);
char *nextstr = type_to_str(next_type);
err_print(curr->next_elif->where, "Mismatched types in if/elif/else chain. Previous block was of type %s, but this one is of type %s.", currstr, nextstr);
free(currstr);
free(nextstr);
return false;
}
curr = nexti;
} else {
break;
}
}
if (!has_else && t->kind != TYPE_VOID) {
err_print(e->where, "Non-void if block with no else.");
return false;
}
} break;
case EXPR_WHILE: {
WhileExpr *w = e->while_;
bool ret = true;
if (w->cond && !types_expr(tr, w->cond))
ret = false;
if (!types_block(tr, &w->body))
ret = false;
if (!ret) return false;
if (w->body.ret_expr) {
err_print(w->body.ret_expr->where, "while loops can't return values -- you're missing a semicolon (;)");
return false;
}
t->kind = TYPE_VOID;
} break;
case EXPR_CALL: {
CallExpr *c = &e->call;
c->instance = NULL;
Expression *f = c->fn;
FnExpr *fn_decl = NULL;
if (!types_expr(tr, f)) return false;
arr_foreach(c->args, Argument, arg) {
if (!types_expr(tr, &arg->val))
return false;
}
if (f->type.kind == TYPE_UNKNOWN) {
e->type.kind = TYPE_UNKNOWN;
return true;
}
if (type_is_builtin(&f->type, BUILTIN_TYPE)) {
/* maybe it's a parameterized type */
} else if (f->type.kind != TYPE_FN) {
char *type = type_to_str(&f->type);
err_print(e->where, "Calling non-function (type %s).", type);
return false;
}
bool has_varargs = f->type.kind == TYPE_FN && fn_type_has_varargs(&f->type.fn);
if (expr_is_definitely_const(f) || type_is_builtin(&f->type, BUILTIN_TYPE) || has_varargs) {
Value val;
if (!eval_expr(tr->evalr, f, &val))
return false;
if (type_is_builtin(&f->type, BUILTIN_TYPE)) {
Type *base = val.type;
if (base->kind != TYPE_STRUCT) {
err_print(e->where, "Cannot pass arguments to non-struct type.");
return false;
}
if (!base->struc->params) {
err_print(e->where, "Passing arguments to struct, but it doesn't take any.");
info_print(base->struc->where, "struct was declared here.");
return false;
}
Copier cop = copier_create(tr->allocr, base->struc->scope.parent);
HashTable *table = &base->struc->instances;
StructDef struc;
copy_struct(&cop, &struc, base->struc);
size_t nparams = 0;
arr_foreach(struc.params, Declaration, param)
nparams += arr_len(param->idents);
bool already_exists;
Value args_val = {0};
Type args_type = {0};
I16 *order;
if (!parameterized_struct_arg_order(&struc, c->args, &order, e->where)) {
free(order);
return false;
}
Type *arg_types = NULL;
arr_set_len(&arg_types, nparams);
Value *arg_vals = typer_malloc(tr, nparams * sizeof *arg_vals);
ErrCtx *err_ctx = tr->err_ctx;
size_t p = 0;
arr_foreach(struc.params, Declaration, param) {
Value param_val = {0};
bool is_tuple = arr_len(param->idents) > 1;
int ident_idx = 0;
/* temporarily add this instance to the stack, while we type the decl, in case you, e.g., pass t = float to struct(t::Type, u::t = "hello") */
*(Location *)arr_add(&err_ctx->instance_stack) = e->where;
typer_block_enter(tr, &struc.scope);
bool success = types_decl(tr, param);
arr_remove_last(&err_ctx->instance_stack);
typer_block_exit(tr);
if (!success) return false;
arr_foreach(param->idents, Identifier, ident) {
Type *type = decl_type_at_index(param, ident_idx);
arg_types[p] = *type;
Value ident_val;
if (order[p] == -1) {
ident_val = *decl_val_at_index(param, ident_idx);
} else {
Argument *arg = &c->args[order[p]];
assert(arg->val.type.flags & TYPE_IS_RESOLVED);
assert(type->flags & TYPE_IS_RESOLVED);
if (!type_eq(&arg->val.type, type)) {
char *expected = type_to_str(type),
*got = type_to_str(&arg->val.type);
err_print(arg->where, "Wrong struct parameter type. Expected %s, but got %s.", expected, got);
return false;
}
if (!eval_expr(tr->evalr, &arg->val, &ident_val))
return false;
}
if (is_tuple)
*(Value *)arr_adda(¶m_val.tuple, tr->allocr) = ident_val;
else
param_val = ident_val;
arg_vals[p] = ident_val;
++p;
++ident_idx;
}
param->val = param_val;
param->flags |= DECL_FOUND_VAL;
}
free(order);
args_val.tuple = arg_vals;
args_type.tuple = arg_types;
args_type.kind = TYPE_TUPLE;
args_type.flags = TYPE_IS_RESOLVED;
Instance *inst = instance_table_adda(tr->allocr, table, args_val, &args_type, &already_exists);
if (!already_exists) {
inst->struc = struc;
size_t i = 0;
arr_foreach(inst->struc.params, Declaration, param) {
param->flags |= DECL_FOUND_VAL;
if (arr_len(param->idents) == 1) {
param->val = arg_vals[i];
++i;
} else {
size_t nmembers = arr_len(param->idents);
param->val.tuple = typer_malloc(tr, nmembers * sizeof *param->val.tuple);
for (size_t idx = 0; idx < nmembers; ++idx) {
param->val.tuple[idx] = arg_vals[i];
++i;
}
}
}
assert(i == nparams);
Type struct_t = {0};
struct_t.kind = TYPE_STRUCT;
struct_t.struc = &inst->struc;
*(Location *)arr_add(&err_ctx->instance_stack) = e->where;
Block *prev_block = tr->block;
tr->block = &inst->struc.scope;
bool success = type_resolve(tr, &struct_t, e->where); /* resolve the struct */
tr->block = prev_block;
arr_remove_last(&err_ctx->instance_stack);
if (!success) return false;
inst->struc.instance_id = table->n;
}
/* expression is actually a type */
e->kind = EXPR_TYPE;
e->typeval = typer_calloc(tr, 1, sizeof *e->typeval);
e->typeval->kind = TYPE_STRUCT;
e->typeval->flags = TYPE_IS_RESOLVED;
e->typeval->struc = &inst->struc;
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_TYPE;
arr_clear(&arg_types);
goto ret;
}
fn_decl = val.fn;
}
Type *ret_type = f->type.fn.types;
Type *param_types = ret_type + 1;
Argument *args = c->args;
size_t nparams = arr_len(f->type.fn.types) - 1;
size_t nargs = arr_len(c->args);
Expression *arg_exprs = NULL;
size_t narg_exprs = 0;
bool is_foreign = (fn_decl->flags & FN_EXPR_FOREIGN) != 0;
I16 *order = NULL;
if (fn_decl && !is_foreign) {
if (!call_arg_param_order(fn_decl, &f->type, c->args, e->where, &order)) {
free(order);
return false;
}
}
size_t nvarargs = 0;
if (has_varargs) {
assert(fn_decl);
/* fn_decl could be foreign, so order could be NULL */
nvarargs = nargs - (order ? (size_t)order[nparams-1] : nparams-1);
narg_exprs = nparams-1 + nvarargs;
} else {
narg_exprs = nparams;
}
arg_exprs = NULL;
arr_set_lena(&arg_exprs, narg_exprs, tr->allocr);
if (fn_decl && !is_foreign) {
size_t i = 0;
Declaration *last_param = arr_last(fn_decl->params);
arr_foreach(fn_decl->params, Declaration, param) {
if (has_varargs && param == last_param) continue;
arr_foreach(param->idents, Identifier, ident) {
I16 arg_idx = order[i];
if (arg_idx == -1) {
if (param->flags & DECL_HAS_EXPR) {
arg_exprs[i].kind = EXPR_VAL;
arg_exprs[i].where = param->where;
arg_exprs[i].flags = param->expr.flags;
arg_exprs[i].type = param->type;
if (has_varargs || f->type.fn.constness) {
/* param->expr hasn't been typed or evaluated, because we passed type_of_fn a "generic" function */
/* we actually need to make a copy of this, so that copy_fn_expr still works later */
Expression default_arg;
Copier cop = copier_create(tr->allocr, tr->block);
copy_expr(&cop, &default_arg, ¶m->expr);
if (!types_expr(tr, &default_arg))
return false;
if (!eval_expr(tr->evalr, &default_arg, &arg_exprs[i].val))
return false;
} else {
arg_exprs[i].val = param->expr.val;
}
}
/* else, it's inferred */
} else {
arg_exprs[i] = args[arg_idx].val;
}
++i;
}
}
} else {
if (nargs != nparams) {
if (!has_varargs || nargs < nparams-1) {
err_print(e->where, "Expected %lu arguments to function call, but got %lu.", (unsigned long)nparams, (unsigned long)nargs);
return false;
}
}
for (size_t p = 0; p < nargs; ++p) {
if (args[p].name) {
err_print(args[p].where, "You can only use named arguments if you directly call a function.");
}
arg_exprs[p] = args[p].val;
}
}
if (has_varargs) {
/* deal with varargs (put them at the end of arg_exprs) */
int idx = order ? order[nparams-1] : (I16)nparams-1;
assert(idx >= 0);
Expression *arg_out = &arg_exprs[(int)nparams-1];
for (; idx < (int)nargs; ++idx) {
Expression *arg = &args[idx].val;
if (type_is_builtin(&arg->type, BUILTIN_VARARGS)) {
/* add each vararg separately */
assert(arg->kind == EXPR_IDENT);
Identifier ident = arg->ident;
assert(ident->decl_kind == IDECL_DECL);
Declaration *decl = ident->decl;
VarArg *varargs_here = decl->val.varargs;
size_t nvarargs_here = arr_len(varargs_here);
/* not just += nvarargs-1 to handle nvarargs_here == 0 */
narg_exprs += nvarargs_here;
--narg_exprs;
nvarargs += nvarargs_here;
--nvarargs;
long arg_out_idx = arg_out - arg_exprs; /* save and restore arg_out to prevent realloc from causing problems */
/* add more room (or if nvarargs_here == 0, remove room) for more varargs */
arr_set_lena(&arg_exprs, narg_exprs, tr->allocr);
arg_out = arg_exprs + arg_out_idx;
for (size_t i = 0; i < nvarargs_here; ++i) {
VarArg *vararg = &varargs_here[i];
Expression *out = arg_out++;
/* construct varargs_here[i] */
out->flags = EXPR_FOUND_TYPE;
out->type = *vararg->type;
out->where = arg->where;
out->kind = EXPR_BINARY_OP;
out->binary.op = BINARY_AT_INDEX;
Expression *lhs = out->binary.lhs = typer_malloc(tr, sizeof *out->binary.lhs);
lhs->kind = EXPR_IDENT;
lhs->flags = EXPR_FOUND_TYPE;
lhs->type = decl->type;
lhs->ident = ident;
lhs->where = arg->where;
Expression *rhs = out->binary.rhs = typer_malloc(tr, sizeof *out->binary.lhs);
rhs->kind = EXPR_VAL;
rhs->flags = EXPR_FOUND_TYPE;
rhs->type.kind = TYPE_BUILTIN;
rhs->type.builtin = BUILTIN_I64;
rhs->type.flags = TYPE_IS_RESOLVED;
rhs->val.i64 = (I64)i;
rhs->where = arg->where;
}
} else {
*arg_out++ = *arg;
}
}
}
FnType *fn_type = &f->type.fn;
c->arg_exprs = arg_exprs;
FnExpr *original_fn = NULL;
FnExpr *fn_copy = NULL;
if (fn_type->constness || (has_varargs && !is_foreign)) {
/* eval function, create copy */
/* the function had better be a compile time constant if it has constant params */
Value fn_val = {0};
if (!eval_expr(tr->evalr, f, &fn_val))
return false;
FnExpr *fn = fn_val.fn;
/* fn is the instance, original_fn is not */
original_fn = fn;
fn_copy = typer_malloc(tr, sizeof *fn_copy);
Copier cop = copier_create(tr->allocr, fn->body.parent);
copy_fn_expr(&cop, fn_copy, fn, 0);
if (has_varargs) {
/* set value of varargs param decl */
VarArg *varargs = NULL;
arr_set_lena(&varargs, nvarargs, tr->allocr);
Declaration *varargs_param = arr_last(fn_copy->params);
DeclFlags is_const = varargs_param->flags & DECL_IS_CONST;
varargs_param->val.varargs = varargs;
for (int v = 0; v < (int)nvarargs; ++v) {
Expression *arg = &arg_exprs[v+order[nparams-1]];
VarArg *vararg = &varargs[v];
if (is_const) {
Value val;
if (!eval_expr(tr->evalr, arg, &val))
return false;
arg->kind = EXPR_VAL;
arg->val = val;
copy_val(tr->allocr, &vararg->val, arg->val, &arg->type);
}
vararg->type = &arg->type;
}
if (is_const) {
varargs_param->flags |= DECL_FOUND_VAL;
}
}
}
if (fn_type->constness) {
FnExpr *fn = fn_copy;
/* keep track of the declaration */
Declaration *param_decl = fn->params;
size_t ident_idx = 0;
size_t i = 0;
Type **arg_types = NULL;
Type **decl_types = NULL;
Identifier *inferred_idents = NULL;
Location *arg_wheres = NULL;
arr_foreach(fn->params, Declaration, param) {
arr_foreach(param->idents, Identifier, ident) {
if (param->flags & DECL_INFER) {
*(Identifier *)arr_add(&inferred_idents) = *ident;
} else if ((param->flags & DECL_ANNOTATES_TYPE)
&& !type_is_builtin(¶m->type, BUILTIN_VARARGS)) {
/* add to stuff infer can use */
Type **p = arr_add(&decl_types);
*p = ¶m->type;
Type **q = arr_add(&arg_types);
*q = &arg_exprs[i].type;
Location *l = arr_add(&arg_wheres);
*l = arg_exprs[i].where;
}
++i;
}
}
size_t ninferred_idents = arr_len(inferred_idents);
if (ninferred_idents) {
Value *inferred_vals = err_malloc(ninferred_idents * sizeof *inferred_vals);
Type *inferred_types = err_malloc(ninferred_idents * sizeof *inferred_types);
Block *prev = tr->block;
tr->block = &fn->body;
if (!infer_ident_vals(tr, decl_types, arg_types, inferred_idents, inferred_vals, inferred_types, arg_wheres)) {
tr->block = prev;
return false;
}
tr->block = prev;
arr_clear(&inferred_idents);
arr_clear(&arg_types);
arr_clear(&decl_types);
{
Type *type = inferred_types;
for (i = 0; i < ninferred_idents; ++i) {
if (type->kind == TYPE_UNKNOWN) {
long counter = (long)i;
Declaration *decl = fn->params;
while (1) {
counter -= (long)arr_len(decl->idents);
if (counter < 0) break;
++decl;
}
err_print(decl->where, "Could not infer value of declaration.");
info_print(e->where, "While processing this call");
return false;
}
++type;
}
}
i = 0;
arr_foreach(fn->params, Declaration, param) {
if (param->flags & DECL_INFER) {
Value *val = &inferred_vals[i];
Type *type = &inferred_types[i];
/* if we have an inferred type argument, it shouldn't be flexible */
if (type_is_builtin(type, BUILTIN_TYPE))
val->type->flags &= (TypeFlags)~(TypeFlags)TYPE_IS_FLEXIBLE;
param->val = *val;
param->type = *type;
param->flags |= DECL_FOUND_VAL | DECL_FOUND_TYPE;
++i;
}
}
free(inferred_vals);
free(inferred_types);
}
/* eval compile time arguments */
for (i = 0; i < nparams; ++i) {
bool should_be_evald = arg_is_const(&arg_exprs[i], fn_type->constness[i]);
if (i == nparams-1 && has_varargs) {
/* handled above */
} else if (should_be_evald) {
if (!order || order[i] != -1) {
Expression *expr = &arg_exprs[i];
Value arg_val = {0};
if (!eval_expr(tr->evalr, expr, &arg_val)) {
if (tr->evalr->enabled) {
info_print(arg_exprs[i].where, "(error occured while trying to evaluate compile-time argument, argument #%lu)", 1+(unsigned long)i);
}
return false;
}
Type *type = &expr->type;
arg_exprs[i].kind = EXPR_VAL;
arg_exprs[i].flags = EXPR_FOUND_TYPE;
arg_exprs[i].val = arg_val;
param_decl->flags |= DECL_FOUND_VAL;
copy_val(tr->allocr, ¶m_decl->val, arg_val, type);
if (!(param_decl->flags & DECL_ANNOTATES_TYPE)) {
param_decl->type = *type;
}
}
}
++ident_idx;
if (ident_idx >= arr_len(param_decl->idents)) {
ident_idx = 0;
++param_decl;
}
}
}
if (fn_type->constness || (has_varargs && !is_foreign)) {
/* type params, return declarations, etc */
if (!type_of_fn(tr, fn_copy, &f->type, TYPE_OF_FN_IS_INSTANCE))
return false;
if (fn_type->constness) {
/* deal with default arguments */
size_t i = 0;
arr_foreach(fn_copy->params, Declaration, param) {
arr_foreach(param->idents, Identifier, ident) {
if (order && order[i] == -1) {
if (param->flags & DECL_INFER) {
arg_exprs[i].kind = EXPR_VAL;
arg_exprs[i].flags = EXPR_FOUND_TYPE;
arg_exprs[i].type = param_types[i] = param->type;
arg_exprs[i].val = param->val;
} else {
assert(param->flags & DECL_HAS_EXPR);
assert(param->expr.kind == EXPR_VAL); /* this was done by type_of_fn */
arg_exprs[i] = param->expr;
copy_val(tr->allocr, &arg_exprs[i].val, param->expr.val, ¶m->expr.type);
}
}
++i;
}
}
}
ret_type = f->type.fn.types;
param_types = ret_type + 1;
}
/* check types of arguments */
for (size_t p = 0; p < nparams; ++p) {
if (p != nparams-1 || !has_varargs) {
Expression *arg = &arg_exprs[p];
Type *expected = ¶m_types[p];
Type *got = &arg->type;
if (!type_eq(expected, got)) {
char *estr = type_to_str(expected);
char *gstr = type_to_str(got);
err_print(arg->where, "Expected type %s as argument to function, but got %s.", estr, gstr);
return false;
}
if (got->flags & TYPE_IS_FLEXIBLE) {
/* "cast" */
*got = *expected;
}
}
}
if (fn_type->constness || (has_varargs && !is_foreign)) {
Type table_index_type = {0};
Value table_index = {0};
/* NOTE: we need to keep table_index's memory around because instance_table_add keeps it to compare against. */
table_index_type.flags = TYPE_IS_RESOLVED;
table_index_type.kind = TYPE_TUPLE;
table_index_type.tuple = NULL;
Type *u64t = typer_arr_add(tr, &table_index_type.tuple);
u64t->was_expr = NULL;
u64t->flags = TYPE_IS_RESOLVED;
u64t->kind = TYPE_BUILTIN;
u64t->builtin = BUILTIN_U64;
table_index.tuple = NULL;
Value *which_are_const_val = typer_arr_add(tr, &table_index.tuple);
U64 *which_are_const = &which_are_const_val->u64;
*which_are_const = 0;
int semi_const_index = 0;
for (size_t i = 0; i < nparams; ++i) {
Expression *arg = &arg_exprs[i];
bool is_const = fn_type->constness && arg_is_const(arg, fn_type->constness[i]);
bool is_vararg = has_varargs && i == nparams-1;
Copier cop = copier_create(tr->allocr, tr->block);
if (is_vararg) {
/* create one additional table index member for varargs */
Value *varargs_val = typer_arr_add(tr, &table_index.tuple);
Type *varargs_type = typer_arr_add(tr, &table_index_type.tuple);
memset(varargs_type, 0, sizeof *varargs_type);
varargs_type->flags = TYPE_IS_RESOLVED;
varargs_type->kind = TYPE_BUILTIN;
varargs_type->builtin = BUILTIN_VARARGS;
varargs_val->varargs = NULL;
for (; i < narg_exprs; ++i) {
arg = &arg_exprs[i];
VarArg *varg = typer_arr_add(tr, &varargs_val->varargs);
varg->type = copy_type_(&cop, &arg->type);
if (is_const) {
copy_val(tr->allocr, &varg->val, arg->val, varg->type);
} else {
/* use zero value everywhere */
varg->val = val_zero(varg->type);
}
}
} else if (is_const) {
assert(arg->kind == EXPR_VAL);
if (fn_type->constness[i] == CONSTNESS_SEMI) {
if (semi_const_index >= 64) {
err_print(f->where, "You can't have more than 64 semi-constant arguments to a function at the moment (sorry).");
return false;
}
*which_are_const |= ((U64)1) << semi_const_index;
++semi_const_index;
}
Value *v = typer_arr_add(tr, &table_index.tuple);
Type *type = typer_arr_add(tr, &table_index_type.tuple);
copy_type(&cop, type, &arg->type);
copy_val(tr->allocr, v, arg->val, type);
}
}
bool instance_already_exists;
c->instance = instance_table_adda(tr->allocr, original_fn->instances, table_index, &table_index_type, &instance_already_exists);
if (instance_already_exists) {
arr_cleara(&table_index_type.tuple, tr->allocr);
arr_cleara(&table_index.tuple, tr->allocr);
} else {
c->instance->fn = fn_copy;
/* fix parameter and return types (they were kind of problematic before, because we didn't know about the instance) */
fn_copy->instance_id = 1+original_fn->instances->n; /* let's help cgen out and assign a non-zero ID to this */
/* type this instance */
/* if anything happens, make sure we let the user know that this happened while generating a fn */
ErrCtx *err_ctx = e->where.file->ctx;
*(Location *)typer_arr_add(tr, &err_ctx->instance_stack) = e->where;
Block *prev_block = tr->block;
tr->block = fn_copy->body.parent;
bool success = types_fn(tr, c->instance->fn, &f->type, c->instance);
tr->block = prev_block;
arr_remove_lasta(&err_ctx->instance_stack, tr->allocr);
if (!success) return false;
}
}
free(order);
*t = *ret_type;
} break;
expr_block:
case EXPR_BLOCK: {
Block *b = e->block;
if (!types_block(tr, b))
return false;
if (b->ret_expr) {
*t = b->ret_expr->type;
} else {
t->kind = TYPE_VOID;
}
} break;
case EXPR_C: {
Expression *code = e->c.code;
if (!types_expr(tr, code))
return false;
if (!type_is_slicechar(&code->type)) {
char *s = type_to_str(&code->type);
err_print(e->where, "Argument to #C directive must of type []char, but got type %s.");
free(s);
return false;
}
Value code_val;
if (!eval_expr(tr->evalr, code, &code_val))
return false;
code->val = code_val;
code->kind = EXPR_VAL;
t->kind = TYPE_UNKNOWN;
} break;
case EXPR_BUILTIN: {
char *builtin_name = eval_expr_as_cstr(tr, e->builtin.which.expr, "#builtin value name");
if (!builtin_name) return false;
int which = -1;
for (BuiltinVal b = 0; b < BUILTIN_VAL_COUNT; b = b + 1) {
if (strs_equal(builtin_val_names[b], builtin_name)) {
which = (int)b;
}
}
if (which == -1) {
err_print(e->where, "Unrecognized builtin value: %s.", builtin_name);
return false;
}
e->builtin.which.val = (BuiltinVal)which;
get_builtin_val_type(tr->allocr, e->builtin.which.val, t);
assert(t->flags & TYPE_IS_RESOLVED);
} break;
case EXPR_UNARY_OP: {
Expression *of = e->unary.of;
Type *of_type = &of->type;
if (!types_expr(tr, of)) return false;
if (of_type->kind == TYPE_UNKNOWN) {
return true;
}
switch (e->unary.op) {
case UNARY_MINUS:
if (of_type->kind != TYPE_BUILTIN || !type_builtin_is_numerical(of_type->builtin)) {
char *s = type_to_str(of_type);
err_print(e->where, "Cannot apply unary - to non-numerical type %s.", s);
free(s);
return false;
}
if (!type_builtin_is_signed(of_type->builtin)) {
char *s = type_to_str(of_type);
warn_print(e->where, "Applying unary - to unsigned type %s may cause overflow.", s);
free(s);
}
*t = *of_type;
break;
case UNARY_ADDRESS:
if (type_is_builtin(of_type, BUILTIN_TYPE)) {
/* oh it's a type! */
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_TYPE;
break;
}
if (!expr_must_lval(of)) {
return false;
}
if (of_type->kind == TYPE_TUPLE) {
/* necessary because x, y (where x and y are variables) is an l-value */
err_print(e->where, "Cannot take address of tuple.");
return false;
}
t->kind = TYPE_PTR;
t->ptr = typer_malloc(tr, sizeof *t->ptr);
*t->ptr = *of_type;
break;
case UNARY_DEREF:
if (of_type->kind != TYPE_PTR) {
char *s = type_to_str(of_type);
err_print(e->where, "Cannot dereference non-pointer type %s.", s);
free(s);
return false;
}
*t = *of_type->ptr;
break;
case UNARY_NOT:
if (!type_can_be_truthy(of_type)) {
char *s = type_to_str(of_type);
err_print(e->where, "Type '%s' cannot be truthy, so the not operator cannot be applied to it.", s);
free(s);
return false;
}
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_BOOL;
break;
case UNARY_LEN:
assert(0); /* types_expr is what makes things UNARY_LEN */
break;
case UNARY_TYPEOF: {
if (of->type.kind == TYPE_VOID) {
err_print(of->where, "This has type void, but you're trying to apply typeof to it.");
return false;
}
if (type_is_builtin(&of->type, BUILTIN_VARARGS)) {
err_print(of->where, "You can't apply typeof to varargs.");
return false;
}
if (of->type.kind == TYPE_TUPLE) {
err_print(of->where, "You can't apply typeof to a tuple.");
return false;
}
e->kind = EXPR_TYPE;
e->typeval = &of->type;
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_TYPE;
} break;
case UNARY_DSIZEOF:
case UNARY_DALIGNOF: {
Type *queried_type;
if (!type_is_builtin(&of->type, BUILTIN_TYPE)) {
char *s = e->unary.op == UNARY_DSIZEOF ? "sizeof" : "alignof";
err_print(e->where, "Argument of #%s must be a Type. Did you mean #%s(typeof ...)?", s, s);
return false;
}
Value val;
if (!eval_expr(tr->evalr, of, &val))
return false;
queried_type = val.type;
if (e->unary.op == UNARY_DSIZEOF)
e->val.i64 = (I64)compiler_sizeof(queried_type);
else
e->val.i64 = (I64)compiler_alignof(queried_type);
e->kind = EXPR_VAL;
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_I64;
} break;
case UNARY_SIZEOF:
case UNARY_ALIGNOF: {
/* eval of */
if (!type_is_builtin(&of->type, BUILTIN_TYPE)) {
char *s = e->unary.op == UNARY_SIZEOF ? "sizeof" : "alignof";
err_print(e->where, "Argument of %s must be a Type. Did you mean %s(typeof ...)?", s, s);
return false;
}
Value val;
if (!eval_expr(tr->evalr, of, &val))
return false;
of->kind = EXPR_VAL;
of->val = val;
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_I64;
} break;
}
} break;
case EXPR_BINARY_OP: {
Expression *lhs = e->binary.lhs;
Expression *rhs = e->binary.rhs;
Type *lhs_type = &lhs->type;
Type *rhs_type = &rhs->type;
BinaryOp o = e->binary.op;
if (o != BINARY_DOT) {
if (!types_expr(tr, lhs)
|| !types_expr(tr, rhs))
return false;
if (lhs_type->kind == TYPE_UNKNOWN || rhs_type->kind == TYPE_UNKNOWN) {
return true;
}
}
switch (o) {
case BINARY_SET:
case BINARY_SET_ADD:
case BINARY_SET_SUB:
case BINARY_SET_MUL:
case BINARY_SET_DIV:
case BINARY_SET_MOD:
if (!expr_must_lval(e->binary.lhs)) {
return false;
}
/* fallthrough */
case BINARY_ADD:
case BINARY_SUB:
case BINARY_MUL:
case BINARY_DIV:
case BINARY_MOD:
case BINARY_LT:
case BINARY_GT:
case BINARY_LE:
case BINARY_GE:
case BINARY_EQ:
case BINARY_NE: {
bool valid = false;
assert(lhs_type->flags & TYPE_IS_RESOLVED);
assert(rhs_type->flags & TYPE_IS_RESOLVED);
if (o == BINARY_SET) {
valid = type_eq(lhs_type, rhs_type);
} else {
/* numerical binary ops */
if (lhs_type->kind == TYPE_BUILTIN && type_eq(lhs_type, rhs_type)) {
/* int + int, etc. */
valid = true;
}
if (o == BINARY_ADD || o == BINARY_SUB || o == BINARY_SET_ADD || o == BINARY_SET_SUB) {
if (lhs_type->kind == TYPE_PTR &&
rhs_type->kind == TYPE_BUILTIN &&
type_builtin_is_numerical(rhs_type->builtin)) {
valid = true;
}
}
if (o == BINARY_LT || o == BINARY_GT || o == BINARY_LE || o == BINARY_GE
|| o == BINARY_EQ || o == BINARY_NE) {
/* comparable types */
if (type_eq(lhs_type, rhs_type)) {
switch (lhs_type->kind) {
case TYPE_PTR:
case TYPE_BUILTIN: /* all builtins are comparable */
valid = true;
default:
break;
}
}
}
}
if (valid) {
switch (o) {
case BINARY_SET:
/* type of x = y is always void */
t->kind = TYPE_VOID;
break;
case BINARY_LT:
case BINARY_GT:
case BINARY_LE:
case BINARY_GE:
case BINARY_EQ:
case BINARY_NE:
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_BOOL;
break;
default: {
int lhs_is_flexible = lhs_type->flags & TYPE_IS_FLEXIBLE;
int rhs_is_flexible = rhs_type->flags & TYPE_IS_FLEXIBLE;
if (lhs_is_flexible && rhs_is_flexible) {
/* both flexible */
*t = *lhs_type;
if (rhs_type->builtin == BUILTIN_F32) {
/* promote to float */
t->builtin = BUILTIN_F32;
}
} else if (!lhs_is_flexible) {
/* lhs inflexible, rhs ? */
*t = *lhs_type;
} else {
/* lhs flexible, rhs ? */
*t = *rhs_type;
}
if ((o == BINARY_MOD || o == BINARY_SET_MOD)
&& type_builtin_is_float(t->builtin)) {
err_print(e->where, "Cannot use operator % on floating-point numbers.");
valid = false;
}
} break;
}
}
if (!valid) {
char *s1, *s2;
s1 = type_to_str(lhs_type);
s2 = type_to_str(rhs_type);
const char *op = binary_op_to_str(o);
err_print(e->where, "Invalid types to operator %s: %s and %s", op, s1, s2);
return false;
}
if (o == BINARY_SET_ADD ||
o == BINARY_SET_SUB ||
o == BINARY_SET_MUL ||
o == BINARY_SET_DIV) {
t->kind = TYPE_VOID; /* actually, it's just void */
}
break;
}
case BINARY_AT_INDEX:
if ((lhs_type->kind == TYPE_ARR || lhs_type->kind == TYPE_SLICE || type_is_builtin(lhs_type, BUILTIN_VARARGS)) &&
(rhs_type->kind != TYPE_BUILTIN || !type_builtin_is_numerical(rhs_type->builtin))) {
err_print(e->where, "The index of an array must be a builtin numerical type.");
return false;
}
if (lhs_type->kind == TYPE_PTR) {
if (lhs_type->ptr->kind == TYPE_STRUCT
|| type_is_builtin(lhs_type->ptr, BUILTIN_NMS)) {
lhs_type = lhs_type->ptr;
}
}
switch (lhs_type->kind) {
case TYPE_ARR:
*t = *lhs_type->arr.of;
break;
case TYPE_SLICE:
*t = *lhs_type->slice;
break;
case TYPE_STRUCT: {
/* allow accessing struct members with a string */
if (!type_is_slicechar(rhs_type)) {
char *s = type_to_str(rhs_type);
err_print(e->where, "Expected a string for struct member access with [], but got type %s.", s);
return false;
}
Value field_name;
/* replace with BINARY_DOT */
e->binary.op = BINARY_DOT;
bool is_field = false;
if (!eval_expr(tr->evalr, rhs, &field_name)) return false;
arr_foreach(lhs_type->struc->fields, Field, f) {
if (ident_eq_str(f->name, field_name.slice.data)) {
is_field = true;
*t = *f->type;
e->binary.dot.field = f;
}
}
if (!is_field) {
char *fstr = err_malloc((size_t)(field_name.slice.n + 1));
memcpy(fstr, field_name.slice.data, (size_t)field_name.slice.n);
fstr[field_name.slice.n] = 0; /* null-terminate */
char *typestr = type_to_str(lhs_type);
err_print(e->where, "%s is not a field of structure %s.", fstr, typestr);
free(fstr); free(typestr);
return false;
}
} break;
case TYPE_BUILTIN:
if (lhs_type->builtin == BUILTIN_NMS) {
/* allow accessing namespace members with a string */
if (!type_is_slicechar(rhs_type)) {
char *s = type_to_str(rhs_type);
err_print(e->where, "Expected a string for namsepace member access with [], but got type %s.", s);
return false;
}
Value nms_val;
if (!eval_expr(tr->evalr, lhs, &nms_val))
return false;
Namespace *nms = nms_val.nms;
lhs->kind = EXPR_VAL;
lhs->val.nms = nms;
Value member_name;
if (!eval_expr(tr->evalr, rhs, &member_name)) return false;
e->binary.op = BINARY_DOT;
e->binary.rhs->kind = EXPR_IDENT;
e->binary.rhs->ident = ident_get_with_len(&nms->body.idents, member_name.slice.data, (size_t)member_name.slice.n);
if (!type_of_ident(tr, rhs->where, &e->binary.rhs->ident, t)) {
return false;
}
break;
} else if (lhs_type->builtin == BUILTIN_VARARGS) {
assert(lhs->kind == EXPR_IDENT);
assert(lhs->ident->decl_kind == IDECL_DECL);
Declaration *decl = lhs->ident->decl;
assert(decl->flags & DECL_IS_PARAM);
Value index_val;
if (!eval_expr(tr->evalr, rhs, &index_val))
return false;
/* NOTE: rhs->type was checked above */
I64 i = val_to_i64(index_val, rhs->type.builtin);
VarArg *varargs = decl->val.varargs;
if (i < 0 || i >= (I64)arr_len(varargs)) {
err_print(e->where, "Index out of bounds for varargs access (index = " I64_FMT ", length = %lu).", i, (unsigned long)arr_len(varargs));
return 0;
}
VarArg *vararg = &varargs[i];
if (decl->flags & DECL_IS_CONST) {
/* replace with value */
e->kind = EXPR_VAL;
e->type = *vararg->type;
copy_val(tr->allocr, &e->val, vararg->val, &e->type);
} else {
/* just use vararg's type */
rhs->kind = EXPR_VAL;
rhs->val.i64 = i;
rhs->type.builtin = BUILTIN_I64;
*t = *vararg->type;
}
break;
}
/* fallthrough */
default: {
char *s = type_to_str(lhs_type);
err_print(e->where, "Cannot subscript type %s", s);
free(s);
return false;
}
}
break;
case BINARY_DOT: {
if (!types_expr(tr, lhs)) return false;
Type *struct_type = lhs_type;
if (struct_type->kind == TYPE_UNKNOWN) return true;
if (struct_type->kind == TYPE_PTR)
struct_type = struct_type->ptr;
if (rhs->kind != EXPR_IDENT) {
err_print(rhs->where, "Expected identifier for struct member access, but got %s.",
expr_kind_to_str(rhs->kind));
return false;
}
if (type_is_builtin(struct_type, BUILTIN_TYPE)) {
/* accessing struct constant/parameter with a Type */
Value lval = {0};
if (!eval_expr(tr->evalr, lhs, &lval))
return false;
lhs->kind = EXPR_VAL;
lhs->flags = EXPR_FOUND_TYPE;
lhs->val = lval;
Type *struc = lhs->val.type;
if (struc->kind != TYPE_STRUCT) {
char *s = type_to_str(struc);
err_print(lhs->where, "Cannot access member from non-struct type (%s).", s);
free(s);
return false;
}
if (!get_struct_constant(struc->struc, rhs->ident, e))
return false;
break;
} else if (struct_type->kind == TYPE_STRUCT) {
bool is_field = false;
arr_foreach(struct_type->struc->fields, Field, f) {
if (ident_eq(f->name, rhs->ident)) {
is_field = true;
*t = *f->type;
e->binary.dot.field = f;
}
}
if (!is_field) {
if (!get_struct_constant(struct_type->struc, rhs->ident, e))
return false;
break;
}
} else if (struct_type->kind == TYPE_SLICE || struct_type->kind == TYPE_ARR || type_is_builtin(struct_type, BUILTIN_VARARGS)) {
if (ident_eq_str(rhs->ident, "data") && struct_type->kind == TYPE_SLICE) {
/* allow access of slice pointer */
t->kind = TYPE_PTR;
t->ptr = typer_calloc(tr, 1, sizeof *t->ptr);
t->ptr->kind = TYPE_VOID;
t->ptr->flags = TYPE_IS_RESOLVED;
break;
}
if (!ident_eq_str(rhs->ident, "len")) {
char *s = type_to_str(struct_type);
err_print(rhs->where, "Field of %s must be .len", s);
free(s);
return false;
}
/* length of slice/arr is i64 */
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_I64;
Expression *of = lhs;
if (type_is_builtin(struct_type, BUILTIN_VARARGS)) {
/* replace with val */
assert(of->kind == EXPR_IDENT);
Identifier ident = of->ident;
assert(ident->decl_kind == IDECL_DECL);
Declaration *decl = ident->decl;
e->kind = EXPR_VAL;
e->val.i64 = (I64)arr_len(decl->val.varargs);
} else {
/* change expr to UNARY_LEN */
e->kind = EXPR_UNARY_OP;
e->unary.op = UNARY_LEN;
e->unary.of = of;
}
} else if (type_is_builtin(struct_type, BUILTIN_NMS)) {
Value nms_val;
if (!eval_expr(tr->evalr, lhs, &nms_val))
return false;
Namespace *nms = nms_val.nms;
lhs->kind = EXPR_VAL;
lhs->val.nms = nms;
Block *prev = tr->block;
/* briefly pretend we are in the namespace */
tr->block = &nms->body;
if (!type_of_ident(tr, rhs->where, &rhs->ident, t)) {
return false;
}
tr->block = prev;
} else {
char *s = type_to_str(lhs_type);
err_print(e->where, "Operator . applied to type %s, which is not a structure or pointer to structure.", s);
free(s);
return false;
}
} break;
} break;
} break;
case EXPR_TUPLE:
t->kind = TYPE_TUPLE;
t->tuple = NULL;
arr_foreach(e->tuple, Expression, x) {
Type *x_type = typer_arr_add(tr, &t->tuple);
if (!types_expr(tr, x))
return false;
*x_type = x->type;
}
break;
case EXPR_SLICE: {
t->kind = TYPE_SLICE;
SliceExpr *s = &e->slice;
if (!types_expr(tr, s->of))
return false;
if (e->slice.from && !types_expr(tr, s->from))
return false;
if (e->slice.to && !types_expr(tr, s->to))
return false;
switch (s->of->type.kind) {
case TYPE_ARR:
t->slice = s->of->type.arr.of;
break;
case TYPE_SLICE:
t->slice = s->of->type.slice;
break;
default: {
char *str = type_to_str(&s->of->type);
err_print(e->where, "Cannot take slice of non-array, non-slice type %s.", str);
free(str);
return false;
}
}
break;
}
case EXPR_TYPE: {
Type *tval = e->typeval;
if (tval->kind == TYPE_STRUCT && tval->struc->params) {
/* don't try to resolve this */
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_TYPE;
break;
}
if (!type_resolve(tr, tval, e->where))
return false;
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_TYPE;
} break;
case EXPR_NMS: {
Namespace *prev_nms = tr->nms;
Namespace *n = tr->nms = e->nms;
n->points_to = NULL;
n->body.flags |= BLOCK_IS_NMS;
if (!types_block(tr, &n->body)) {
tr->nms = prev_nms;
return false;
}
tr->nms = prev_nms;
n->associated_ident = NULL; /* set when we type the declaration which contains this namespace */
t->kind = TYPE_BUILTIN;
t->builtin = BUILTIN_NMS;
} break;
case EXPR_VAL:
assert(0);
return false;
}
ret:
assert(t->flags & TYPE_IS_RESOLVED);
return true;
}
static Status types_block(Typer *tr, Block *b) {
if (b->flags & BLOCK_FOUND_TYPES)
return true;
if (b->flags & BLOCK_FINDING_TYPES) {
err_print(b->where, "A circular dependency was found when finding types in this block.\n"
"You are using recursion in a way that is not allowed by this language. Sorry!");
return false;
}
b->flags |= BLOCK_FINDING_TYPES;
typer_block_enter(tr, b);
bool success = true;
arr_foreach(b->stmts, Statement, s) {
if (!types_stmt(tr, s)) {
success = false;
continue;
}
if (s->kind == STMT_EXPR && (s->flags & STMT_EXPR_NO_SEMICOLON)) {
/* not voided */
Expression *e = &s->expr;
if (e->type.kind == TYPE_VOID) {
if (!(e->kind == EXPR_BLOCK
|| e->kind == EXPR_IF
|| e->kind == EXPR_WHILE
|| e->kind == EXPR_FOR)) {
err_print(e->where, "void expression must be followed by ;");
success = false;
goto ret;
}
} else {
if (s != (Statement *)arr_last(b->stmts)) {
err_print(e->where, "Return value must be the last statement in a block.");
success = false;
goto ret;
}
b->ret_expr = typer_malloc(tr, sizeof *b->ret_expr);
*b->ret_expr = *e;
arr_remove_lasta(&b->stmts, tr->allocr);
}
}
}
ret:
typer_block_exit(tr);
b->flags |= BLOCK_FOUND_TYPES;
b->flags &= (BlockFlags)~(BlockFlags)BLOCK_FINDING_TYPES;
return success;
}
static Status types_decl(Typer *tr, Declaration *d) {
if (d->flags & DECL_FOUND_TYPE) return true;
bool success = true;
if ((d->flags & DECL_HAS_EXPR)
&& d->expr.kind == EXPR_TYPE
&& d->expr.typeval->kind == TYPE_STRUCT) {
d->expr.typeval->struc->name = d->idents[0];
}
if (d->flags & DECL_INFER) {
d->type.kind = TYPE_UNKNOWN;
d->type.flags = 0;
return true;
}
Declaration **dptr = typer_arr_add(tr, &tr->in_decls);
*dptr = d;
if (d->flags & DECL_ANNOTATES_TYPE) {
/* type supplied */
assert(d->type.kind != TYPE_VOID); /* there's no way to annotate void */
if (!type_resolve(tr, &d->type, d->where)) {
success = false;
goto ret;
}
}
if (d->flags & DECL_HAS_EXPR) {
if (!types_expr(tr, &d->expr)) {
success = false;
goto ret;
}
assert(d->expr.type.flags & TYPE_IS_RESOLVED);
if (d->flags & DECL_ANNOTATES_TYPE) {
if (!type_must_eq(d->expr.where, &d->type, &d->expr.type)) {
success = false;
goto ret;
}
d->expr.type = d->type;
} else {
if (d->expr.type.kind == TYPE_VOID) {
/* e.g. x := (fn(){})(); */
err_print(d->expr.where, "Use of void value.");
success = false;
goto ret;
}
d->type = d->expr.type;
d->type.flags &= (TypeFlags)~(TypeFlags)TYPE_IS_FLEXIBLE; /* x := 5; => x is not flexible */
}
bool need_value = (d->flags & DECL_IS_CONST) ||
((tr->block == NULL || (tr->block->flags & BLOCK_IS_NMS)) && tr->fn == NULL);
if (need_value) {
if (!(d->flags & DECL_FOUND_VAL)) {
Value val;
if (!eval_expr(tr->evalr, &d->expr, &val)) {
success = false;
goto ret;
}
copy_val(tr->allocr, &d->val, val, &d->type);
d->flags |= DECL_FOUND_VAL;
}
}
}
for (size_t i = 0; i < arr_len(d->idents); ++i) {
Type *t = d->type.kind == TYPE_TUPLE ? &d->type.tuple[i] : &d->type;
if (type_is_compileonly(&d->type)) {
if (!(d->flags & DECL_IS_CONST)) {
char *s = type_to_str(&d->type);
err_print(d->where, "Declarations with type %s must be constant.", s);
free(s);
success = false;
goto ret;
}
}
if (type_is_builtin(t, BUILTIN_TYPE)) {
if (d->flags & DECL_HAS_EXPR) {
Value *val = d->type.kind == TYPE_TUPLE ? &d->val.tuple[i] : &d->val;
if (val->type->kind == TYPE_STRUCT && val->type->struc->params) {
/* don't resolve it because it's not really complete */
} else {
if (!type_resolve(tr, val->type, d->where)) return false;
}
}
} else if (!(d->flags & DECL_IS_CONST) && t->kind == TYPE_FN && t->fn.constness) {
for (size_t p = 0; p < arr_len(t->fn.types)-1; ++p) {
if (t->fn.constness[p] == CONSTNESS_YES) {
err_print(d->where, "You can't have a pointer to a function with constant parameters.");
success = false;
goto ret;
}
}
/* make constness NULL, so that semi-constant parameters turn into non-constant arguments */
t->fn.constness = NULL;
}
}
size_t n_idents; n_idents = arr_len(d->idents);
if (d->type.kind == TYPE_TUPLE) {
if (n_idents != arr_len(d->type.tuple)) {
err_print(d->where, "Expected to have %lu things declared in declaration, but got %lu.", (unsigned long)arr_len(d->type.tuple), (unsigned long)n_idents);
success = false;
goto ret;
}
}
if (d->type.kind == TYPE_UNKNOWN) {
if (!d->where.file->ctx->have_errored) /* don't do an error if we haven't already done one, because it might be because of that */
err_print(d->where, "Can't determine type of declaration.");
success = false;
goto ret;
}
if (type_is_builtin(&d->type, BUILTIN_VARARGS) && !(d->flags & DECL_IS_PARAM)) {
err_print(d->where, "Only parameters can be varargs.");
success = false;
goto ret;
}
if (d->flags & DECL_IS_CONST) {
if (d->type.kind == TYPE_PTR) {
err_print(d->where, "You can't have a constant pointer.");
success = false;
goto ret;
}
}
if (n_idents == 1 && (d->flags & DECL_HAS_EXPR) && d->expr.kind == EXPR_NMS) {
bool is_at_top_level = true;
typedef Block *BlockPtr;
arr_foreach(tr->blocks, BlockPtr, b) {
if (*b && !((*b)->flags & BLOCK_IS_NMS)) {
is_at_top_level = false;
break;
}
}
if (is_at_top_level)
d->expr.nms->associated_ident = d->idents[0];
}
if (tr->nms && tr->block == &tr->nms->body) {
arr_foreach(d->idents, Identifier, ident) {
(*ident)->nms = tr->nms;
}
}
ret:
/* pretend we found the type even if we didn't to prevent too many errors */
d->flags |= DECL_FOUND_TYPE;
if (!success) {
/* use unknown type if we didn't get the type */
d->type.flags = TYPE_IS_RESOLVED;
d->type.was_expr = NULL;
d->type.kind = TYPE_UNKNOWN;
tr->evalr->enabled = false; /* disable evaluator completely so that it doesn't accidentally try to access this declaration */
}
arr_remove_lasta(&tr->in_decls, tr->allocr);
return success;
}
static bool expr_is_usable(Expression *e) {
if (e->kind == EXPR_IDENT) return true;
if (e->kind == EXPR_BINARY_OP && e->binary.op == BINARY_DOT)
return expr_is_usable(e->binary.lhs);
return false;
}
static Status types_stmt(Typer *tr, Statement *s) {
if (s->flags & STMT_TYPED) return true;
switch (s->kind) {
case STMT_EXPR:
if (!types_expr(tr, &s->expr)) {
return false;
}
if (!(s->flags & STMT_EXPR_NO_SEMICOLON)) {
if (s->expr.kind == EXPR_TUPLE) {
err_print(s->where, "Statement of a tuple is not allowed. Use a semicolon instead of a comma here.");
return false;
}
Type *t = &s->expr.type;
if (type_is_compileonly(t)) {
char *str = type_to_str(t);
warn_print(s->where, "This expression has a compile-only type (%s), so this statement will not actually be outputted in C code.", str);
free(str);
}
}
if (tr->block == NULL) {
/* evaluate expression statements at global scope */
if (s->expr.kind != EXPR_C) {
if (!eval_stmt(tr->evalr, s))
return false;
}
}
break;
case STMT_DECL:
if (!types_decl(tr, s->decl)) {
return false;
}
break;
case STMT_RET:
if (!tr->fn) {
err_print(s->where, "return outside of a function.");
return false;
}
s->ret.referring_to = &tr->fn->body;
if (s->ret.flags & RET_HAS_EXPR) {
if (tr->fn->ret_type.kind == TYPE_VOID) {
err_print(s->where, "Return value in a void function.");
return false;
}
if (tr->fn->ret_decls) {
err_print(s->where, "Return expression in a function with named return values.");
return false;
}
if (!types_expr(tr, &s->ret.expr))
return false;
if (!type_eq(&tr->fn->ret_type, &s->ret.expr.type)) {
char *got = type_to_str(&s->ret.expr.type);
char *expected = type_to_str(&tr->fn->ret_type);
err_print(s->where, "Returning type %s in function which returns %s.", got, expected);
return false;
}
} else {
if (tr->fn->ret_type.kind != TYPE_VOID
&& !tr->fn->ret_decls) {
err_print(s->where, "No return value in non-void function.");
return false;
}
}
break;
case STMT_INCLUDE: {
char *filename = eval_expr_as_cstr(tr, &s->inc.filename, "import filename");
if (!filename)
return false;
size_t filename_len = strlen(filename);
IncludedFile *inc_f = NULL;
if (s->flags & STMT_INC_TO_NMS) {
if (!(s->inc.flags & INC_FORCED)) {
inc_f = str_hash_table_get(&tr->included_files, filename, filename_len);
if (inc_f) {
tr->nms->body.idents = inc_f->main_nms->body.idents;
tr->nms->body.idents.scope = &tr->nms->body;
tr->nms->points_to = inc_f->main_nms;
s->inc.inc_file = inc_f;
s->inc.stmts = inc_f->stmts;
break;
}
}
s->inc.inc_file = inc_f = str_hash_table_insert(&tr->included_files, filename, filename_len);
inc_f->main_nms = tr->nms;
}
char *contents = read_file_contents(tr->allocr, filename, s->where);
if (!contents)
return false;
Tokenizer tokr;
tokr_create(&tokr, tr->err_ctx, tr->allocr);
File *file = typer_calloc(tr, 1, sizeof *file);
file->filename = filename;
file->contents = contents;
file->ctx = tr->err_ctx;
if (!tokenize_file(&tokr, file))
return false;
Parser parser;
parser_create(&parser, tr->globals, &tokr, tr->allocr);
parser.block = tr->block;
ParsedFile parsed_file;
if (!parse_file(&parser, &parsed_file)) {
return false;
}
Statement *stmts_inc = parsed_file.stmts;
if (inc_f) {
inc_f->stmts = stmts_inc;
}
s->inc.stmts = stmts_inc;
arr_foreach(stmts_inc, Statement, s_incd) {
if (!types_stmt(tr, s_incd))
return false;
}
} break;
case STMT_MESSAGE: {
Message *m = &s->message;
char *text = eval_expr_as_cstr(tr, &m->text, "message");
if (!text)
return false;
switch (m->kind) {
case MESSAGE_INFO:
info_print(s->where, "%s", text);
break;
case MESSAGE_WARN:
warn_print(s->where, "%s", text);
break;
case MESSAGE_ERROR:
err_print(s->where, "%s", text);
return false;
}
} break;
case STMT_BREAK:
case STMT_CONT: {
/* make sure we are actually in a loop */
Block *block;
for (block = tr->block; block; block = block->parent) {
if (block->flags & BLOCK_IS_LOOP) {
s->referring_to = block;
break;
}
}
if (!block) {
err_print(s->where, "%s not in loop.", s->kind == STMT_BREAK ? "break" : "continue");
return false;
}
} break;
case STMT_DEFER:
if (!types_stmt(tr, s->defer))
return false;
if (s->defer->kind == STMT_DEFER) {
err_print(s->where, "You can't defer a defer!");
return false;
}
if (s->defer->kind == STMT_DECL) {
err_print(s->where, "Deferring a declaration doesn't make sense!");
return false;
}
break;
case STMT_USE: {
Expression *e = &s->use;
if (!types_expr(tr, e))
return false;
if (e->type.kind != TYPE_STRUCT && !type_is_builtin(&e->type, BUILTIN_NMS)) {
char *str = type_to_str(&e->type);
err_print(s->where, "You cannot use something of type %s (only Namespaces and structs).", str);
free(str);
return false;
}
if (!expr_is_usable(e)) {
err_print(e->where, "You can't use this value. You should probably assign it to a variable.");
return false;
}
UsedExpr *u = arr_add(&tr->used);
u->scope = tr->block;
u->stmt = s;
} break;
}
s->flags |= STMT_TYPED;
return true;
}
static void typer_create(Typer *tr, Evaluator *ev, File *file, ErrCtx *err_ctx, Allocator *allocr, Identifiers *idents) {
tr->used = NULL;
tr->block = NULL;
tr->blocks = NULL;
tr->fn = NULL;
tr->nms = NULL;
tr->evalr = ev;
tr->file = file;
tr->err_ctx = err_ctx;
tr->in_decls = NULL;
tr->in_fors = NULL;
tr->allocr = allocr;
tr->globals = idents;
*(Block **)arr_adda(&tr->blocks, allocr) = NULL;
str_hash_table_create(&tr->included_files, sizeof(IncludedFile), tr->allocr);
}
static Status types_file(Typer *tr, ParsedFile *f) {
bool ret = true;
tr->parsed_file = f;
arr_foreach(f->stmts, Statement, s) {
if (!types_stmt(tr, s)) {
ret = false;
}
}
assert(tr->block == NULL);
return ret;
}
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