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static bool eval_block(Evaluator *ev, Block *b, Value *v);
static bool eval_expr(Evaluator *ev, Expression *e, Value *v);
static bool block_enter(Block *b, Statement *stmts, U32 flags);
static void block_exit(Block *b, Statement *stmts);
static void evalr_create(Evaluator *ev) {
allocr_create(&ev->allocr);
ev->returning = NULL;
}
static void evalr_free(Evaluator *ev) {
allocr_free_all(&ev->allocr);
}
static inline void *evalr_malloc(Evaluator *ev, size_t bytes) {
return allocr_malloc(&ev->allocr, bytes);
}
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);
}
assert(0);
return 0;
}
/* size of a type at compile time */
static size_t compiler_sizeof(Type *t) {
switch (t->kind) {
case TYPE_BUILTIN:
return compiler_sizeof_builtin(t->builtin);
case TYPE_FN:
return sizeof t->fn;
case TYPE_PTR:
return sizeof t->ptr;
case TYPE_ARR:
return t->arr.n * compiler_sizeof(t->arr.of);
case TYPE_TUPLE:
return sizeof t->tuple;
case TYPE_SLICE:
return sizeof t->slice;
case TYPE_VOID:
case TYPE_UNKNOWN:
return 0;
}
assert(0);
return 0;
}
static bool builtin_truthiness(Value *v, BuiltinType b) {
switch (b) {
case BUILTIN_I8: return v->i8 != 0;
case BUILTIN_I16: return v->i16 != 0;
case BUILTIN_I32: return v->i32 != 0;
case BUILTIN_I64: return v->i64 != 0;
case BUILTIN_U8: return v->u8 != 0;
case BUILTIN_U16: return v->u16 != 0;
case BUILTIN_U32: return v->u32 != 0;
case BUILTIN_U64: return v->u64 != 0;
case BUILTIN_F32: return v->f32 != 0;
case BUILTIN_F64: return v->f64 != 0;
case BUILTIN_BOOL: return v->boolv;
case BUILTIN_CHAR: return v->charv != 0;
}
assert(0); return false;
}
static bool val_truthiness(Value *v, Type *t) {
switch (t->kind) {
case TYPE_VOID: return false;
case TYPE_UNKNOWN: assert(0); return false;
case TYPE_BUILTIN: return builtin_truthiness(v, t->builtin);
case TYPE_PTR: return v->ptr != NULL;
case TYPE_FN: return v->fn != NULL;
case TYPE_ARR: return t->arr.n > 0;
case TYPE_SLICE: return v->slice.n > 0;
case TYPE_TUPLE: break;
}
assert(0);
return false;
}
static I64 val_to_i64(Value *v, BuiltinType v_type) {
switch (v_type) {
case BUILTIN_I8: return (I64)v->i8;
case BUILTIN_I16: return (I64)v->i16;
case BUILTIN_I32: return (I64)v->i32;
case BUILTIN_I64: return (I64)v->i64;
case BUILTIN_U8: return (I64)v->u8;
case BUILTIN_U16: return (I64)v->u16;
case BUILTIN_U32: return (I64)v->u32;
case BUILTIN_U64: return (I64)v->u64;
default: break;
}
assert(0);
return 0;
}
static U64 val_to_u64(Value *v, BuiltinType v_type) {
if (v_type == BUILTIN_U64) return v->u64;
return (U64)val_to_i64(v, v_type);
}
static void i64_to_val(Value *v, BuiltinType v_type, I64 x) {
switch (v_type) {
case BUILTIN_I8:
v->i8 = (I8)x; break;
case BUILTIN_I16:
v->i16 = (I16)x; break;
case BUILTIN_I32:
v->i32 = (I32)x; break;
case BUILTIN_I64:
v->i64 = (I64)x; break;
case BUILTIN_U8:
v->u8 = (U8)x; break;
case BUILTIN_U16:
v->u16 = (U16)x; break;
case BUILTIN_U32:
v->u32 = (U32)x; break;
case BUILTIN_U64:
v->u64 = (U64)x; break;
default: assert(0); break;
}
}
static void u64_to_val(Value *v, BuiltinType v_type, U64 x) {
if (v_type == BUILTIN_U64)
v->u64 = x;
else
i64_to_val(v, v_type, (I64)x);
}
#define builtin_casts_to_int(x) \
case BUILTIN_I8: \
vout->i8 = (I8)vin->x; break; \
case BUILTIN_I16: \
vout->i16 = (I16)vin->x; break; \
case BUILTIN_I32: \
vout->i32 = (I32)vin->x; break; \
case BUILTIN_I64: \
vout->i64 = (I64)vin->x; break; \
case BUILTIN_U8: \
vout->u8 = (U8)vin->x; break; \
case BUILTIN_U16: \
vout->u16 = (U16)vin->x; break; \
case BUILTIN_U32: \
vout->u32 = (U32)vin->x; break; \
case BUILTIN_U64: \
vout->u64 = (U64)vin->x; break
#define builtin_casts_to_num(x) \
builtin_casts_to_int(x); \
case BUILTIN_F32: \
vout->f32 = (F32)vin->x; break; \
case BUILTIN_F64: \
vout->f64 = (F64)vin->x; break
#define builtin_int_casts(low, up) \
case BUILTIN_##up: \
switch (to) { \
builtin_casts_to_num(low); \
case BUILTIN_CHAR: vout->charv = (char)vin->low; break; \
case BUILTIN_BOOL: vout->boolv = vin->low != 0; break; \
} break
#define builtin_float_casts(low, up) \
case BUILTIN_##up: \
switch (to) { \
builtin_casts_to_num(low); \
case BUILTIN_BOOL: vout->boolv = vin->low != 0.0f; break; \
case BUILTIN_CHAR: \
assert(0); break; \
} break
static void val_builtin_cast(Value *vin, BuiltinType from, Value *vout, BuiltinType to) {
if (from == to) {
*vout = *vin;
return;
}
switch (from) {
builtin_int_casts(i8, I8);
builtin_int_casts(i16, I16);
builtin_int_casts(i32, I32);
builtin_int_casts(i64, I64);
builtin_int_casts(u8, U8);
builtin_int_casts(u16, U16);
builtin_int_casts(u32, U32);
builtin_int_casts(u64, U64);
builtin_float_casts(f32, F32);
builtin_float_casts(f64, F64);
case BUILTIN_BOOL: vout->boolv = builtin_truthiness(vin, from); break;
case BUILTIN_CHAR:
switch (to) {
builtin_casts_to_int(charv);
case BUILTIN_CHAR: /* handled at top of func */
case BUILTIN_F32:
case BUILTIN_F64:
case BUILTIN_BOOL:
assert(0); break;
}
break;
}
}
static void val_cast(Value *vin, Type *from, Value *vout, Type *to) {
if (to->kind == TYPE_BUILTIN && to->builtin == BUILTIN_BOOL) {
vout->boolv = val_truthiness(vin, from);
return;
}
switch (from->kind) {
case TYPE_VOID: assert(0); break;
case TYPE_UNKNOWN: assert(0); break;
case TYPE_TUPLE: assert(0); break;
case TYPE_BUILTIN:
switch (to->kind) {
case TYPE_BUILTIN:
val_builtin_cast(vin, from->builtin, vout, to->builtin);
break;
case TYPE_PTR:
switch (from->builtin) {
case BUILTIN_I8: vout->ptr = (void *)(U64)vin->i8; break;
case BUILTIN_I16: vout->ptr = (void *)(U64)vin->i16; break;
case BUILTIN_I32: vout->ptr = (void *)(U64)vin->i32; break;
case BUILTIN_I64: vout->ptr = (void *)(U64)vin->i64; break;
case BUILTIN_U8: vout->ptr = (void *)(U64)vin->u8; break;
case BUILTIN_U16: vout->ptr = (void *)(U64)vin->u16; break;
case BUILTIN_U32: vout->ptr = (void *)(U64)vin->u32; break;
case BUILTIN_U64: vout->ptr = (void *)(U64)vin->u64; break;
default: assert(0); break;
}
break;
case TYPE_SLICE:
case TYPE_VOID:
case TYPE_UNKNOWN:
case TYPE_TUPLE:
case TYPE_FN:
case TYPE_ARR:
assert(0);
break;
}
break;
case TYPE_FN:
switch (to->kind) {
case TYPE_PTR:
vout->ptr = (void *)vin->fn;
break;
case TYPE_FN:
vout->fn = vin->fn;
break;
case TYPE_SLICE:
case TYPE_UNKNOWN:
case TYPE_TUPLE:
case TYPE_VOID:
case TYPE_ARR:
case TYPE_BUILTIN:
assert(0); break;
}
break;
case TYPE_PTR:
switch (to->kind) {
case TYPE_BUILTIN:
switch (to->builtin) {
builtin_casts_to_int(ptr);
case BUILTIN_BOOL:
case BUILTIN_CHAR:
case BUILTIN_F32:
case BUILTIN_F64:
assert(0); break;
}
break;
case TYPE_ARR:
vout->arr = vin->ptr;
break;
case TYPE_PTR:
vout->ptr = vin->ptr;
break;
case TYPE_FN:
vout->fn = vin->ptr;
break;
case TYPE_SLICE:
case TYPE_UNKNOWN:
case TYPE_TUPLE:
case TYPE_VOID:
assert(0);
break;
}
break;
case TYPE_ARR:
switch (to->kind) {
case TYPE_PTR:
vout->ptr = vin->arr;
break;
case TYPE_ARR:
vout->arr = vin->arr;
break;
case TYPE_SLICE:
case TYPE_FN:
case TYPE_UNKNOWN:
case TYPE_TUPLE:
case TYPE_VOID:
case TYPE_BUILTIN:
assert(0); break;
}
break;
case TYPE_SLICE:
switch (to->kind) {
case TYPE_PTR:
vout->ptr = vin->slice.data;
break;
case TYPE_ARR:
vout->arr = vin->slice.data;
break;
case TYPE_SLICE:
vout->slice = vin->slice;
break;
case TYPE_FN:
case TYPE_UNKNOWN:
case TYPE_TUPLE:
case TYPE_VOID:
case TYPE_BUILTIN:
assert(0); break;
}
break;
}
}
/* type is the underlying type, not the pointer type. */
static void eval_deref(Value *v, void *ptr, Type *type) {
switch (type->kind) {
case TYPE_PTR: v->ptr = *(void **)ptr; break;
case TYPE_ARR: v->arr = ptr; break; /* when we have a pointer to an array, it points directly to the data in that array. */
case TYPE_FN: v->fn = *(FnExpr **)ptr; break;
case TYPE_TUPLE: v->tuple = *(Value **)ptr; break;
case TYPE_BUILTIN:
switch (type->builtin) {
case BUILTIN_I8: v->i8 = *(I8 *)ptr; break;
case BUILTIN_U8: v->u8 = *(U8 *)ptr; break;
case BUILTIN_I16: v->i16 = *(I16 *)ptr; break;
case BUILTIN_U16: v->u16 = *(U16 *)ptr; break;
case BUILTIN_I32: v->i32 = *(I32 *)ptr; break;
case BUILTIN_U32: v->u32 = *(U32 *)ptr; break;
case BUILTIN_I64: v->i64 = *(I64 *)ptr; break;
case BUILTIN_U64: v->u64 = *(U64 *)ptr; break;
case BUILTIN_F32: v->f32 = *(F32 *)ptr; break;
case BUILTIN_F64: v->f64 = *(F64 *)ptr; break;
case BUILTIN_CHAR: v->charv = *(char *)ptr; break;
case BUILTIN_BOOL: v->boolv = *(bool *)ptr; break;
}
break;
case TYPE_SLICE:
v->slice = *(Slice *)ptr;
break;
case TYPE_VOID:
case TYPE_UNKNOWN:
assert(0);
break;
}
}
/* inverse of eval_deref */
static void eval_deref_set(void *set, Value *to, Type *type) {
switch (type->kind) {
case TYPE_PTR: *(void **)set = to->ptr; break;
case TYPE_ARR: *(void **)set = to->arr; break;
case TYPE_FN: *(FnExpr **)set = to->fn; break;
case TYPE_TUPLE: *(Value **)set = to->tuple; break;
case TYPE_BUILTIN:
switch (type->builtin) {
case BUILTIN_I8: *(I8 *)set = to->i8; break;
case BUILTIN_U8: *(U8 *)set = to->u8; break;
case BUILTIN_I16: *(I16 *)set = to->i16; break;
case BUILTIN_U16: *(U16 *)set = to->u16; break;
case BUILTIN_I32: *(I32 *)set = to->i32; break;
case BUILTIN_U32: *(U32 *)set = to->u32; break;
case BUILTIN_I64: *(I64 *)set = to->i64; break;
case BUILTIN_U64: *(U64 *)set = to->u64; break;
case BUILTIN_F32: *(F32 *)set = to->f32; break;
case BUILTIN_F64: *(F64 *)set = to->f64; break;
case BUILTIN_CHAR: *(char *)set = to->charv; break;
case BUILTIN_BOOL: *(bool *)set = to->boolv; break;
}
break;
case TYPE_SLICE:
*(Slice *)set = to->slice;
break;
case TYPE_VOID:
case TYPE_UNKNOWN:
assert(0);
break;
}
}
static bool eval_val_ptr_at_index(Evaluator *ev, Location where, Value *arr, U64 i, Type *arr_type, Type *idx_type, void **ptr, Type **type) {
switch (arr_type->kind) {
case TYPE_ARR: {
U64 arr_sz = arr_type->arr.n;
if (i >= arr_sz) {
err_print(where, "Array out of bounds (%lu, array size = %lu)\n", (unsigned long)i, (unsigned long)arr_sz);
return false;
}
*ptr = (char *)arr->arr + compiler_sizeof(arr_type->arr.of) * i;
if (type) *type = arr_type->arr.of;
} break;
case TYPE_SLICE: {
U64 slice_sz = arr->slice.n;
if (i >= slice_sz) {
err_print(where, "Slice out of bounds (%lu, slice size = %lu)\n", (unsigned long)i, (unsigned long)slice_sz);
return false;
}
*ptr = (char *)arr->slice.data + compiler_sizeof(arr_type->slice) * i;
if (type) *type = arr_type->slice;
} break;
default: assert(0); break;
}
return true;
}
static bool eval_expr_ptr_at_index(Evaluator *ev, Expression *e, void **ptr, Type **type) {
Value arr;
if (!eval_expr(ev, e->binary.lhs, &arr)) return false;
Value index;
if (!eval_expr(ev, e->binary.rhs, &index)) return false;
Type *ltype = &e->binary.lhs->type;
Type *rtype = &e->binary.rhs->type;
U64 i;
assert(rtype->kind == TYPE_BUILTIN);
if (rtype->builtin == BUILTIN_U64) {
i = index.u64;
} else {
I64 signed_index = val_to_i64(&index, rtype->builtin);
if (signed_index < 0) {
err_print(e->where, "Array or slice out of bounds (index = %ld)\n", (long)signed_index);
return false;
}
i = (U64)signed_index;
}
return eval_val_ptr_at_index(ev, e->where, &arr, i, ltype, rtype, ptr, type);
}
static bool eval_set(Evaluator *ev, Expression *set, Value *to) {
switch (set->kind) {
case EXPR_IDENT: {
IdentDecl *id = ident_decl(set->ident);
if (!(id->flags & IDECL_FLAG_HAS_VAL)) {
err_print(set->where, "Cannot set value of run time variable at compile time.");
return false;
}
id->val = *to;
} break;
case EXPR_UNARY_OP:
switch (set->unary.op) {
case UNARY_DEREF: {
Value ptr;
if (!eval_expr(ev, set->unary.of, &ptr)) return false;
eval_deref_set(ptr.ptr, to, &set->type);
} break;
default: assert(0); break;
}
break;
case EXPR_BINARY_OP:
switch (set->binary.op) {
case BINARY_AT_INDEX: {
void *ptr;
Type *type;
if (!eval_expr_ptr_at_index(ev, set, &ptr, &type))
return false;
eval_deref_set(ptr, to, type);
} break;
default: break;
}
case EXPR_TUPLE:
/* TODO */
break;
default:
assert(0);
break;
}
return true;
}
static bool eval_expr(Evaluator *ev, Expression *e, Value *v) {
/* WARNING: macros ahead */
#define eval_unary_op_one(low, up, op) \
case BUILTIN_##up: \
v->low = (up)(op of.low); break
#define eval_unary_op_nums(builtin, op) \
eval_unary_op_one(i8, I8, op); \
eval_unary_op_one(i16, I16, op); \
eval_unary_op_one(i32, I32, op); \
eval_unary_op_one(i64, I64, op); \
eval_unary_op_one(u8, U8, op); \
eval_unary_op_one(u16, U16, op); \
eval_unary_op_one(u32, U32, op); \
eval_unary_op_one(u64, U64, op); \
eval_unary_op_one(f32, F32, op); \
eval_unary_op_one(f64, F64, op);
#define eval_unary_op_nums_only(op) \
switch (builtin) { \
eval_unary_op_nums(builtin, op); \
default: assert(0); break; \
}
#define eval_binary_op_one(low, up, op) \
case BUILTIN_##up: \
v->low = (up)(lhs.low op rhs.low); break
#define eval_binary_op_nums(builtin, op) \
eval_binary_op_one(i8, I8, op); \
eval_binary_op_one(i16, I16, op); \
eval_binary_op_one(i32, I32, op); \
eval_binary_op_one(i64, I64, op); \
eval_binary_op_one(u8, U8, op); \
eval_binary_op_one(u16, U16, op); \
eval_binary_op_one(u32, U32, op); \
eval_binary_op_one(u64, U64, op); \
eval_binary_op_one(f32, F32, op); \
eval_binary_op_one(f64, F64, op)
#define eval_binary_op_nums_only(op) \
val_cast(&lhs, &e->binary.lhs->type, &lhs, &e->type); \
val_cast(&rhs, &e->binary.rhs->type, &rhs, &e->type); \
assert(e->type.kind == TYPE_BUILTIN); \
switch (builtin) { \
eval_binary_op_nums(builtin, op); \
default: assert(0); break; \
}
#define eval_binary_bool_op_one(low, up, op) \
case BUILTIN_##up: \
v->boolv = lhs.low op rhs.low; break
#define eval_binary_bool_op_nums(builtin, op) \
eval_binary_bool_op_one(i8, I8, op); \
eval_binary_bool_op_one(i16, I16, op); \
eval_binary_bool_op_one(i32, I32, op); \
eval_binary_bool_op_one(i64, I64, op); \
eval_binary_bool_op_one(u8, U8, op); \
eval_binary_bool_op_one(u16, U16, op); \
eval_binary_bool_op_one(u32, U32, op); \
eval_binary_bool_op_one(u64, U64, op); \
eval_binary_bool_op_one(f32, F32, op); \
eval_binary_bool_op_one(f64, F64, op);
#define eval_binary_bool_op_nums_only(op) \
{Type *ltype=&e->binary.lhs->type, \
*rtype=&e->binary.rhs->type; \
Type *cast_to = ltype->flags & TYPE_FLAG_FLEXIBLE ? \
rtype : ltype; \
val_cast(&lhs, ltype, &lhs, cast_to); \
val_cast(&rhs, rtype, &rhs, cast_to); \
assert(e->type.kind == TYPE_BUILTIN); \
switch (builtin) { \
eval_binary_bool_op_nums(builtin, op); \
default:printf("%d\n",(int)builtin); \
assert(!"Invalid builtin to "#op); break; \
}}
switch (e->kind) {
case EXPR_UNARY_OP: {
Value of;
if (e->unary.op != UNARY_ADDRESS) {
if (!eval_expr(ev, e->unary.of, &of)) return false;
}
switch (e->unary.op) {
case UNARY_ADDRESS: {
Expression *o = e->unary.of;
switch (o->kind) {
case EXPR_IDENT: {
IdentDecl *id = ident_decl(o->ident);
if (!(id->flags & IDECL_FLAG_HAS_VAL)) {
err_print(e->where, "Cannot take address of run time variable at compile time.");
return false;
}
if (o->type.kind == TYPE_ARR)
v->ptr = id->val.arr; /* point directly to data */
else
v->ptr = &id->val;
} break;
case EXPR_UNARY_OP:
switch (o->unary.op) {
case UNARY_DEREF: {
Value ptr;
if (!eval_expr(ev, o, &ptr)) return false;
v->ptr = ptr.ptr;
} break;
default: assert(0); break;
}
break;
case EXPR_BINARY_OP:
switch (o->binary.op) {
case BINARY_AT_INDEX: {
void *ptr;
if (!eval_expr_ptr_at_index(ev, o, &ptr, NULL))
return false;
v->ptr = ptr;
} break;
default: break;
}
break;
default:
assert(0);
break;
}
} break;
case UNARY_DEREF:
eval_deref(v, of.ptr, &e->type);
break;
case UNARY_MINUS: {
BuiltinType builtin = e->type.builtin;
assert(e->type.kind == TYPE_BUILTIN);
eval_unary_op_nums_only(-);
} break;
case UNARY_NOT:
v->boolv = !val_truthiness(v, &e->unary.of->type);
break;
case UNARY_DEL:
if (e->unary.of->type.kind == TYPE_PTR)
free(of.ptr);
else {
assert(e->unary.of->type.kind == TYPE_SLICE);
free(of.slice.data);
}
break;
}
} break;
case EXPR_BINARY_OP: {
Value lhs, rhs;
/* TODO(eventually): short-circuiting */
if (e->binary.op != BINARY_SET)
if (!eval_expr(ev, e->binary.lhs, &lhs)) return false;
if (!eval_expr(ev, e->binary.rhs, &rhs)) return false;
BuiltinType builtin = e->binary.lhs->type.builtin;
switch (e->binary.op) {
case BINARY_ADD:
eval_binary_op_nums_only(+); break;
case BINARY_SUB:
eval_binary_op_nums_only(-); break;
case BINARY_MUL:
eval_binary_op_nums_only(*); break;
case BINARY_DIV:
eval_binary_op_nums_only(/); break;
case BINARY_LT:
eval_binary_bool_op_nums_only(<); break;
case BINARY_LE:
eval_binary_bool_op_nums_only(<=); break;
case BINARY_GT:
eval_binary_bool_op_nums_only(>); break;
case BINARY_GE:
eval_binary_bool_op_nums_only(>=); break;
case BINARY_EQ:
eval_binary_bool_op_nums_only(==); break;
case BINARY_NE:
eval_binary_bool_op_nums_only(!=); break;
case BINARY_SET:
if (!eval_set(ev, e->binary.lhs, &rhs)) return false;
break;
case BINARY_AT_INDEX: {
void *ptr;
Type *type;
eval_expr_ptr_at_index(ev, e, &ptr, &type);
eval_deref(v, ptr, type);
} break;
}
} break;
case EXPR_LITERAL_INT:
assert(e->type.kind == TYPE_BUILTIN);
u64_to_val(v, e->type.builtin, e->intl);
break;
case EXPR_LITERAL_FLOAT:
assert(e->type.kind == TYPE_BUILTIN);
if (e->type.builtin == BUILTIN_F32) {
v->f32 = (F32)e->floatl;
} else if (e->type.builtin == BUILTIN_F64) {
v->f64 = (F64)e->floatl;
} else {
assert(0);
}
break;
case EXPR_IF: {
IfExpr *i = &e->if_;
if (i->cond) {
Value cond;
if (!eval_expr(ev, i->cond, &cond)) return false;
if (val_truthiness(&cond, &i->cond->type)) {
if (!eval_block(ev, &i->body, v)) return false;
} else if (i->next_elif) {
if (!eval_expr(ev, i->next_elif, v)) return false;
}
} else {
if (!eval_block(ev, &i->body, v)) return false;
}
} break;
case EXPR_WHILE: {
Value cond;
WhileExpr *w = &e->while_;
while (1) {
if (w->cond) {
if (!eval_expr(ev, w->cond, &cond)) return false;
if (!val_truthiness(&cond, &w->cond->type))
break;
}
if (!eval_block(ev, &w->body, v)) return false;
}
} break;
case EXPR_BLOCK:
if (!eval_block(ev, &e->block, v)) return false;
break;
case EXPR_LITERAL_BOOL:
v->boolv = e->booll;
break;
case EXPR_LITERAL_CHAR:
v->charv = e->charl;
break;
case EXPR_LITERAL_STR:
v->slice.data = e->strl.str;
v->slice.n = e->strl.len;
break;
case EXPR_CAST: {
Value casted;
if (!eval_expr(ev, e->cast.expr, &casted)) return false;
val_cast(&casted, &e->cast.expr->type, v, &e->cast.type);
} break;
case EXPR_FN:
v->fn = &e->fn;
break;
case EXPR_IDENT: {
IdentDecl *idecl = ident_decl(e->ident);
Declaration *d = idecl->decl;
if (idecl->flags & IDECL_FLAG_HAS_VAL) {
*v = idecl->val;
} else if (d->flags & DECL_FLAG_CONST) {
if (!(d->flags & DECL_FLAG_FOUND_VAL)) {
if (!eval_expr(ev, &d->expr, &d->val)) return false;
d->flags |= DECL_FLAG_FOUND_VAL;
}
if (d->type.kind == TYPE_TUPLE) {
long index = 0;
arr_foreach(d->idents, Identifier, decl_i) {
if (*decl_i == e->ident) {
break;
}
index++;
assert(index < (long)arr_len(d->idents)); /* identifier got its declaration set to here, but it's not here */
}
*v = d->val.tuple[index];
} else {
*v = d->val;
}
} else {
char *s = ident_to_str(e->ident);
err_print(e->where, "Cannot evaluate non-constant '%s' at compile time.", s);
free(s);
return false;
}
} break;
case EXPR_TUPLE: {
size_t i, n = arr_len(e->tuple);
v->tuple = evalr_malloc(ev, n * sizeof *v->tuple);
for (i = 0; i < n; i++) {
if (!eval_expr(ev, &e->tuple[i], &v->tuple[i]))
return false;
}
} break;
case EXPR_DIRECT: {
DirectExpr *d = &e->direct;
switch (d->which) {
case DIRECT_C:
err_print(e->where, "Cannot run C code at compile time.");
return false;
case DIRECT_COUNT: assert(0); return false;
}
} break;
case EXPR_NEW:
/* it's not strictly necessary to do the if here */
if (e->new.n) {
Value n;
if (!eval_expr(ev, e->new.n, &n))
return false;
U64 n64 = val_to_u64(&n, e->new.n->type.builtin);
v->slice.data = err_calloc(n64, compiler_sizeof(&e->new.type));
v->slice.n = n64;
} else {
v->ptr = err_calloc(1, compiler_sizeof(&e->new.type));
}
break;
case EXPR_CALL: {
Value fnv;
if (!eval_expr(ev, e->call.fn, &fnv))
return false;
FnExpr *fn = fnv.fn;
/* set parameter declaration values */
Declaration *params = fn->params;
/* OPTIM (NOTE: currently needed for recursion) */
Value *args = NULL;
arr_resv(&args, arr_len(e->call.arg_exprs));
for (size_t i = 0; i < arr_len(e->call.arg_exprs); i++) {
if (!eval_expr(ev, &e->call.arg_exprs[i], &args[i]))
return false;
}
fn_enter(fn, 0);
long arg = 0;
arr_foreach(params, Declaration, p) {
arr_foreach(p->idents, Identifier, i) {
IdentDecl *id = ident_decl(*i);
id->val = args[arg];
id->flags |= IDECL_FLAG_HAS_VAL;
arg++;
}
}
arr_clear(&args);
if (!eval_block(ev, &fn->body, v)) {
fn_exit(fn);
return false;
}
if (ev->returning) {
*v = *ev->returning;
free(ev->returning);
ev->returning = NULL;
}
fn_exit(fn);
} break;
case EXPR_SLICE: {
SliceExpr *s = &e->slice;
Value ofv;
Type *of_type = &s->of->type;
if (!eval_expr(ev, s->of, &ofv))
return false;
U64 n = of_type->kind == TYPE_ARR ? of_type->arr.n : ofv.slice.n;
U64 from, to;
if (s->from) {
Value fromv;
if (!eval_expr(ev, s->from, &fromv))
return false;
assert(s->from->type.kind == TYPE_BUILTIN);
from = val_to_u64(&fromv, s->from->type.builtin);
} else {
from = 0;
}
if (s->to) {
Value tov;
if (!eval_expr(ev, s->to, &tov))
return false;
assert(s->to->type.kind == TYPE_BUILTIN);
to = val_to_u64(&tov, s->to->type.builtin);
} else {
to = n - 1;
}
/* TODO: is this the best check? (Go also checks if from > to) */
if (to > n) {
err_print(e->where, "Slice index out of bounds (to = %lu, length = %lu).", (unsigned long)to, (unsigned long)n);
return false;
}
void *ptr1, *ptr2;
if (from < to) {
if (!eval_val_ptr_at_index(ev, e->where, &ofv, from, of_type, &s->from->type, &ptr1, NULL))
return false;
if (!eval_val_ptr_at_index(ev, e->where, &ofv, to, of_type, &s->to->type, &ptr2, NULL))
return false;
v->slice.data = ptr1;
v->slice.n = to - from;
} else {
v->slice.data = NULL;
v->slice.n = 0;
}
} break;
}
return true;
}
static bool eval_decl(Evaluator *ev, Declaration *d) {
Value val = {0};
int has_expr = d->flags & DECL_FLAG_HAS_EXPR;
if (has_expr) {
if (!eval_expr(ev, &d->expr, &val))
return false;
d->flags |= DECL_FLAG_HAS_EXPR;
}
long index = 0;
arr_foreach(d->idents, Identifier, i) {
IdentDecl *id = ident_decl(*i);
if (has_expr && d->expr.kind == EXPR_TUPLE) {
id->val = val.tuple[index++];
} else if (!has_expr && d->type.kind == TYPE_ARR) {
/* "stack" array */
id->val.arr = err_calloc(d->type.arr.n, compiler_sizeof(d->type.arr.of));
} else {
id->val = val;
}
id->flags |= IDECL_FLAG_HAS_VAL;
}
return true;
}
static bool eval_stmt(Evaluator *ev, Statement *stmt) {
switch (stmt->kind) {
case STMT_DECL:
if (!eval_decl(ev, &stmt->decl)) return false;
break;
case STMT_EXPR: {
Value unused;
if (!eval_expr(ev, &stmt->expr, &unused))
return false;
} break;
case STMT_RET:
ev->returning = err_malloc(sizeof *ev->returning);
if (!eval_expr(ev, &stmt->ret.expr, ev->returning))
return false;
break;
}
return true;
}
static bool eval_block(Evaluator *ev, Block *b, Value *v) {
block_enter(b, b->stmts, 0);
arr_foreach(b->stmts, Statement, stmt) {
if (!eval_stmt(ev, stmt))
return false;
if (ev->returning) break;
}
if (!ev->returning && b->ret_expr) {
if (!eval_expr(ev, b->ret_expr, v))
return false;
}
block_exit(b, b->stmts);
return true;
}
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