//: A big convenience high-level languages provide is the ability to name memory
//: locations. In mu, a transform called 'transform_names' provides this
//: convenience.
:(scenario transform_names)
def main [
x:number <- copy 0
]
+name: assign x 1
+mem: storing 0 in location 1
:(scenarios transform)
:(scenario transform_names_fails_on_use_before_define)
% Hide_errors = true;
def main [
x:number <- copy y:number
]
+error: main: use before set: y
# todo: detect conditional defines
:(after "Transform.push_back(compute_container_metadata)") // we need sizes for all types
Transform.push_back(transform_names); // idempotent
:(before "End Globals")
map<recipe_ordinal, map<string, int> > Name;
//: the Name map is a global, so save it before tests and reset it for every
//: test, just to be safe.
:(before "End Globals")
map<recipe_ordinal, map<string, int> > Name_snapshot;
:(before "End save_snapshots")
Name_snapshot = Name;
:(before "End restore_snapshots")
Name = Name_snapshot;
:(code)
void transform_names(const recipe_ordinal r) {
recipe& caller = get(Recipe, r);
trace(9991, "transform") << "--- transform names for recipe " << caller.name << end();
//? cerr << "--- transform names for recipe " << caller.name << '\n';
bool names_used = false;
bool numeric_locations_used = false;
map<string, int>& names = Name[r];
// store the indices 'used' so far in the map
int& curr_idx = names[""];
++curr_idx; // avoid using index 0, benign skip in some other cases
for (int i = 0; i < SIZE(caller.steps); ++i) {
instruction& inst = caller.steps.at(i);
// End transform_names(inst) Special-cases
// map names to addresses
for (int in = 0; in < SIZE(inst.ingredients); ++in) {
if (is_disqualified(inst.ingredients.at(in), inst, caller.name)) continue;
if (is_numeric_location(inst.ingredients.at(in))) numeric_locations_used = true;
if (is_named_location(inst.ingredients.at(in))) names_used = true;
if (is_integer(inst.ingredients.at(in).name)) continue;
if (!already_transformed(inst.ingredients.at(in), names)) {
raise << maybe(caller.name) << "use before set: " << inst.ingredients.at(in).name << '\n' << end();
}
int v = lookup_name(inst.ingredients.at(in), r);
if (v >= 0) {
inst.ingredients.at(in).set_value(v);
}
else {
raise << maybe(caller.name) << "can't find a place to store " << inst.ingredients.at(in).name << '\n' << end();
return;
}
}
for (int out = 0; out < SIZE(inst.products); ++out) {
if (is_disqualified(inst.products.at(out), inst, caller.name)) continue;
if (is_numeric_location(inst.products.at(out))) numeric_locations_used = true;
if (is_named_location(inst.products.at(out))) names_used = true;
if (is_integer(inst.products.at(out).name)) continue;
if (names.find(inst.products.at(out).name) == names.end()) {
trace(9993, "name") << "assign " << inst.products.at(out).name << " " << curr_idx << end();
names[inst.products.at(out).name] = curr_idx;
curr_idx += size_of(inst.products.at(out));
}
int v = lookup_name(inst.products.at(out), r);
if (v >= 0) {
inst.products.at(out).set_value(v);
}
else {
raise << maybe(caller.name) << "can't find a place to store " << inst.products.at(out).name << '\n' << end();
return;
}
}
}
if (names_used && numeric_locations_used)
raise << maybe(caller.name) << "mixing variable names and numeric addresses\n" << end();
}
bool is_disqualified(/*mutable*/ reagent& x, const instruction& inst, const string& recipe_name) {
if (!x.type) {
// End Null-type is_disqualified Exceptions
raise << maybe(recipe_name) << "missing type for " << x.original_string << " in '" << to_original_string(inst) << "'\n" << end();
return true;
}
if (is_raw(x)) return true;
if (is_literal(x)) return true;
// End is_disqualified Cases
if (x.initialized) return true;
return false;
}
bool already_transformed(const reagent& r, const map<string, int>& names) {
return contains_key(names, r.name);
}
int lookup_name(const reagent& r, const recipe_ordinal default_recipe) {
return Name[default_recipe][r.name];
}
type_ordinal skip_addresses(type_tree* type) {
type_ordinal address = get(Type_ordinal, "address");
for (; type; type = type->right) {
if (type->value != address)
return type->value;
}
return -1;
}
int find_element_name(const type_ordinal t, const string& name, const string& recipe_name) {
const type_info& container = get(Type, t);
for (int i = 0; i < SIZE(container.elements); ++i)
if (container.elements.at(i).name == name) return i;
raise << maybe(recipe_name) << "unknown element " << name << " in container " << get(Type, t).name << '\n' << end();
return -1;
}
bool is_numeric_location(const reagent& x) {
if (is_literal(x)) return false;
if (is_raw(x)) return false;
if (x.name == "0") return false; // used for chaining lexical scopes
return is_integer(x.name);
}
bool is_named_location(const reagent& x) {
if (is_literal(x)) return false;
if (is_raw(x)) return false;
if (is_special_name(x.name)) return false;
return !is_integer(x.name);
}
bool is_special_name(const string& s) {
if (s == "_") return true;
if (s == "0") return true;
// End is_special_name Cases
return false;
}
:(scenario transform_names_supports_containers)
def main [
x:point <- merge 34, 35
y:number <- copy 3
]
+name: assign x 1
# skip location 2 because x occupies two locations
+name: assign y 3
:(scenario transform_names_supports_static_arrays)
def main [
x:array:number:3 <- create-array
y:number <- copy 3
]
+name: assign x 1
# skip locations 2, 3, 4 because x occupies four locations
+name: assign y 5
:(scenario transform_names_passes_dummy)
# _ is just a dummy result that never gets consumed
def main [
_, x:number <- copy 0, 1
]
+name: assign x 1
-name: assign _ 1
//: an escape hatch to suppress name conversion that we'll use later
:(scenarios run)
:(scenario transform_names_passes_raw)
% Hide_errors = true;
def main [
x:number/raw <- copy 0
]
-name: assign x 1
+error: can't write to location 0 in 'x:number/raw <- copy 0'
:(scenarios transform)
:(scenario transform_names_fails_when_mixing_names_and_numeric_locations)
% Hide_errors = true;
def main [
x:number <- copy 1:number
]
+error: main: mixing variable names and numeric addresses
:(scenario transform_names_fails_when_mixing_names_and_numeric_locations_2)
% Hide_errors = true;
def main [
x:number <- copy 1
1:number <- copy x:number
]
+error: main: mixing variable names and numeric addresses
:(scenario transform_names_does_not_fail_when_mixing_names_and_raw_locations)
def main [
x:number <- copy 1:number/raw
]
-error: main: mixing variable names and numeric addresses
$error: 0
:(scenario transform_names_does_not_fail_when_mixing_names_and_literals)
def main [
x:number <- copy 1
]
-error: main: mixing variable names and numeric addresses
$error: 0
//:: Support element names for containers in 'get' and 'get-location' and 'put'.
//: (get-location is implemented later)
:(scenario transform_names_transforms_container_elements)
def main [
p:address:point <- copy 0
a:number <- get *p:address:point, y:offset
b:number <- get *p:address:point, x:offset
]
+name: element y of type point is at offset 1
+name: element x of type point is at offset 0
:(before "End transform_names(inst) Special-cases")
// replace element names of containers with offsets
if (inst.name == "get" || inst.name == "get-location" || inst.name == "put") {
//: avoid raising any errors here; later layers will support overloading new
//: instructions with the same names (static dispatch), which could lead to
//: spurious errors
if (SIZE(inst.ingredients) < 2)
break; // error raised elsewhere
if (!is_literal(inst.ingredients.at(1)))
break; // error raised elsewhere
if (inst.ingredients.at(1).name.find_first_not_of("0123456789") != string::npos) {
// since first non-address in base type must be a container, we don't have to canonize
type_ordinal base_type = skip_addresses(inst.ingredients.at(0).type);
if (base_type == -1)
break; // error raised elsewhere
if (contains_key(Type, base_type)) { // otherwise we'll raise an error elsewhere
inst.ingredients.at(1).set_value(find_element_name(base_type, inst.ingredients.at(1).name, get(Recipe, r).name));
trace(9993, "name") << "element " << inst.ingredients.at(1).name << " of type " << get(Type, base_type).name << " is at offset " << no_scientific(inst.ingredients.at(1).value) << end();
}
}
}
//: this test is actually illegal so can't call run
:(scenarios transform)
:(scenario transform_names_handles_containers)
def main [
a:point <- copy 0/unsafe
b:number <- copy 0/unsafe
]
+name: assign a 1
+name: assign b 3
//:: Support variant names for exclusive containers in 'maybe-convert'.
:(scenarios run)
:(scenario transform_names_handles_exclusive_containers)
def main [
12:number <- copy 1
13:number <- copy 35
14:number <- copy 36
20:point, 22:boolean <- maybe-convert 12:number-or-point/unsafe, p:variant
]
+name: variant p of type number-or-point has tag 1
+mem: storing 1 in location 22
+mem: storing 35 in location 20
+mem: storing 36 in location 21
:(before "End transform_names(inst) Special-cases")
// convert variant names of exclusive containers
if (inst.name == "maybe-convert") {
if (SIZE(inst.ingredients) != 2) {
raise << maybe(get(Recipe, r).name) << "exactly 2 ingredients expected in '" << to_original_string(inst) << "'\n" << end();
break;
}
assert(is_literal(inst.ingredients.at(1)));
if (inst.ingredients.at(1).name.find_first_not_of("0123456789") != string::npos) {
// since first non-address in base type must be an exclusive container, we don't have to canonize
type_ordinal base_type = skip_addresses(inst.ingredients.at(0).type);
if (base_type == -1)
raise << maybe(get(Recipe, r).name) << "expected an exclusive-container in '" << to_original_string(inst) << "'\n" << end();
if (contains_key(Type, base_type)) { // otherwise we'll raise an error elsewhere
inst.ingredients.at(1).set_value(find_element_name(base_type, inst.ingredients.at(1).name, get(Recipe, r).name));
trace(9993, "name") << "variant " << inst.ingredients.at(1).name << " of type " << get(Type, base_type).name << " has tag " << no_scientific(inst.ingredients.at(1).value) << end();
}
}
}