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static bool call_arg_param_order(Allocator *allocr, FnExpr *fn, Location fn_where, Type *fn_type, Argument *args, Location where, U16 **param_indices);
static bool types_expr(Typer *tr, Expression *e);
/* resolved_to should have the same value as to, but not consist of any identifiers which aren't in scope right now */
static bool infer_from_expr(Typer *tr, Expression *match, Expression *to, Expression *resolved_to, Identifier *idents, Value *vals, Type *types) {
assert(!(match->flags & EXPR_FOUND_TYPE));
assert(to->flags & EXPR_FOUND_TYPE);
switch (match->kind) {
case EXPR_IDENT:
/* an identifier! maybe it's one of idents... */
arr_foreach(idents, Identifier, ident) {
if (*ident == match->ident) {
long idx = ident - idents;
types[idx] = to->type;
if (!eval_expr(tr->evalr, resolved_to, &vals[idx]))
return false;
Copier c = copier_create(tr->allocr, tr->block);
Value new_val;
copy_val_full(&c, &new_val, &vals[idx], &to->type);
vals[idx] = new_val;
break;
}
}
break;
case EXPR_CALL: {
while (to->kind == EXPR_IDENT) {
IdentDecl *idecl = ident_decl(to->ident);
if (idecl->kind == IDECL_DECL) {
Declaration *decl = idecl->decl;
int index = ident_index_in_decl(to->ident, decl);
Expression *expr = NULL;
if (decl->type.kind == TYPE_TUPLE) {
if (decl->expr.kind == EXPR_TUPLE) {
expr = &decl->expr.tuple[index];
}
} else {
expr = &decl->expr;
}
if (expr) to = expr;
} else break;
}
if (to->kind != EXPR_CALL) return true; /* give up */
Argument *m_args = match->call.args;
Expression *t_args = to->call.arg_exprs;
size_t nargs = arr_len(m_args);
U16 *order = NULL;
Expression *f = match->call.fn;
IdentDecl *idecl = ident_decl(f->ident);
bool is_direct_fn = idecl && idecl->kind == IDECL_DECL && (idecl->decl->flags & DECL_HAS_EXPR) && idecl->decl->expr.kind == EXPR_FN;
if (is_direct_fn) {
if (!types_expr(tr, f))
return false;
FnExpr *fn_decl = idecl->decl->expr.fn;
if (!call_arg_param_order(tr->allocr, fn_decl, idecl->decl->where, &f->type, m_args, match->where, &order))
return false;
}
for (size_t i = 0; i < nargs; ++i) {
Argument *m_arg = &m_args[i];
Expression *t_arg;
if (is_direct_fn) {
t_arg = &t_args[order[i]];
} else {
t_arg = &t_args[i];
}
if (t_arg->kind == EXPR_VAL) {
/* was evaluated, because it's const */
if (!infer_from_expr(tr, &m_arg->val, t_arg, t_arg, idents, vals, types))
return false;
}
}
} break;
default: break;
}
return true;
}
/* if match is not the same kind of type as to, returns true */
static bool infer_from_type(Typer *tr, Type *match, Type *to, Identifier *idents, Value *vals, Type *types) {
assert(to->flags & TYPE_IS_RESOLVED);
switch (match->kind) {
case TYPE_VOID:
case TYPE_UNKNOWN:
case TYPE_BUILTIN:
break; /* nothing we can do here */
case TYPE_TUPLE: {
if (to->kind != TYPE_TUPLE) return true;
if (arr_len(match->tuple) != arr_len(to->tuple)) return true;
Type *b = to->tuple;
arr_foreach(match->tuple, Type, a) {
if (!infer_from_type(tr, a, b, idents, vals, types))
return false;
++b;
}
} break;
case TYPE_FN: {
if (match->fn.constness || to->fn.constness) {
return true;
}
if (to->kind != TYPE_FN) return true;
if (arr_len(match->fn.types) != arr_len(to->fn.types)) return true;
size_t i, len = arr_len(match->fn.types);
for (i = 0; i < len; ++i) {
if (!infer_from_type(tr, &match->fn.types[i], &to->fn.types[i], idents, vals, types))
return false;
}
} break;
case TYPE_PTR:
if (to->kind != TYPE_PTR) return true;
if (!infer_from_type(tr, match->ptr, to->ptr, idents, vals, types))
return false;
break;
case TYPE_SLICE:
if (to->kind != TYPE_SLICE) return true;
if (!infer_from_type(tr, match->slice, to->slice, idents, vals, types))
return false;
break;
case TYPE_STRUCT: {
if (to->kind != TYPE_STRUCT) return true;
Field *fields_m = match->struc->fields;
Field *fields_t = to->struc->fields;
size_t i, len = arr_len(fields_m);
if (len != arr_len(fields_t)) return true;
for (i = 0; i < len; ++i) {
if (!infer_from_type(tr, &fields_m[i].type, &fields_t[i].type, idents, vals, types))
return false;
}
} break;
case TYPE_EXPR: {
Expression *to_expr = to->was_expr;
Expression e = {0};
e.kind = EXPR_TYPE;
e.typeval = *to;
e.flags = EXPR_FOUND_TYPE;
Type *type = &e.type;
type->flags = TYPE_IS_RESOLVED;
type->kind = TYPE_BUILTIN;
type->builtin = BUILTIN_TYPE;
if (!to_expr) {
to_expr = &e;
}
if (!infer_from_expr(tr, match->expr, to_expr, &e, idents, vals, types))
return false;
} break;
case TYPE_ARR: {
if (to->kind != TYPE_ARR) return true;
Expression to_n_expr = {0};
to_n_expr.kind = EXPR_LITERAL_INT;
to_n_expr.intl = to->arr.n;
to_n_expr.flags = EXPR_FOUND_TYPE;
Type *n_type = &to_n_expr.type;
n_type->kind = TYPE_BUILTIN;
n_type->builtin = BUILTIN_I64;
n_type->flags = TYPE_IS_RESOLVED;
if (!infer_from_expr(tr, match->arr.n_expr, &to_n_expr, &to_n_expr, idents, vals, types))
return false;
if (!infer_from_type(tr, match->arr.of, to->arr.of, idents, vals, types))
return false;
} break;
}
return true;
}
/*
match and to are dynamic arrays of equal size
idents is a dyn array of distinct identifiers
find the value of each ident by matching match[i] to to[i], i = 0..arr_len(match)-1
all the types in match must be unresolved, and all the types in to must be resolved
*/
static bool infer_ident_vals(Typer *tr, Type **match, Type **to, Identifier *idents, Value *vals, Type *types) {
size_t ntypes = arr_len(match);
size_t i;
size_t nidents = arr_len(idents);
Type *t = types;
for (i = 0; i < nidents; ++i) {
t->kind = TYPE_UNKNOWN;
++t;
}
for (i = 0; i < ntypes; ++i) {
if (!infer_from_type(tr, *match, *to, idents, vals, types))
return false;
++match, ++to;
}
return true;
}
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