//: Spaces help isolate recipes from each other. You can create them at will,
//: and all addresses in arguments are implicitly based on the 'default-space'
//: (unless they have the /raw property)
//: A space is just an array of any scalar location.
:(before "End Mu Types Initialization")
put(Type_abbreviations, "space", new_type_tree("address:array:location"));
//: Spaces are often called 'scopes' in other languages.
put(Type_abbreviations, "scope", new_type_tree("address:array:location"));
:(scenario set_default_space)
# if default-space is 10, and if an array of 5 locals lies from location 12 to 16 (inclusive),
# then local 0 is really location 12, local 1 is really location 13, and so on.
def main [
# pretend address:array:location; in practice we'll use 'new'
10:num <- copy 0 # refcount
11:num <- copy 5 # length
default-space:space <- copy 10/unsafe
1:num <- copy 23
]
+mem: storing 23 in location 13
:(scenario lookup_sidesteps_default_space)
def main [
# pretend pointer from outside (2000 reserved for refcount)
2001:num <- copy 34
# pretend address:array:location; in practice we'll use 'new"
1000:num <- copy 0 # refcount
1001:num <- copy 5 # length
# actual start of this recipe
default-space:space <- copy 1000/unsafe
1:&:num <- copy 2000/unsafe # even local variables always contain raw addresses
8:num/raw <- copy *1:&:num
]
+mem: storing 34 in location 8
//:: first disable name conversion for 'default-space'
:(scenario convert_names_passes_default_space)
% Hide_errors = true;
def main [
default-space:num, x:num <- copy 0, 1
]
+name: assign x 1
-name: assign default-space 1
:(before "End is_disqualified Special-cases")
if (x.name == "default-space")
x.initialized = true;
:(before "End is_special_name Special-cases")
if (s == "default-space") return true;
//:: now implement space support
:(before "End call Fields")
int default_space;
:(before "End call Constructor")
default_space = 0;
:(before "End canonize(x) Special-cases")
absolutize(x);
:(code)
void absolutize(reagent& x) {
if (is_raw(x) || is_dummy(x)) return;
if (x.name == "default-space") return;
if (!x.initialized)
raise << to_original_string(current_instruction()) << ": reagent not initialized: '" << x.original_string << "'\n" << end();
x.set_value(address(x.value, space_base(x)));
x.properties.push_back(pair<string, string_tree*>("raw", NULL));
assert(is_raw(x));
}
//: hook replaced in a later layer
int space_base(const reagent& x) {
return current_call().default_space ? (current_call().default_space+/*skip refcount*/1) : 0;
}
int address(int offset, int base) {
assert(offset >= 0);
if (base == 0) return offset; // raw
int size = get_or_insert(Memory, base);
if (offset >= size) {
// todo: test
raise << "location " << offset << " is out of bounds " << size << " at " << base << '\n' << end();
return 0;
}
return base + /*skip length*/1 + offset;
}
//:: reads and writes to the 'default-space' variable have special behavior
:(after "Begin Preprocess write_memory(x, data)")
if (x.name == "default-space") {
if (!scalar(data) || !is_space(x))
raise << maybe(current_recipe_name()) << "'default-space' should be of type address:array:location, but is " << to_string(x.type) << '\n' << end();
current_call().default_space = data.at(0);
return;
}
:(code)
bool is_space(const reagent& r) {
return is_address_of_array_of_numbers(r);
}
:(scenario get_default_space)
def main [
default-space:space <- copy 10/unsafe
1:space/raw <- copy default-space:space
]
+mem: storing 10 in location 1
:(after "Begin Preprocess read_memory(x)")
if (x.name == "default-space") {
vector<double> result;
result.push_back(current_call().default_space);
return result;
}
//:: fix 'get'
:(scenario lookup_sidesteps_default_space_in_get)
def main [
# pretend pointer to container from outside (2000 reserved for refcount)
2001:num <- copy 34
2002:num <- copy 35
# pretend address:array:location; in practice we'll use 'new'
1000:num <- copy 0 # refcount
1001:num <- copy 5 # length
# actual start of this recipe
default-space:space <- copy 1000/unsafe
1:&:point <- copy 2000/unsafe
9:num/raw <- get *1:&:point, 1:offset
]
+mem: storing 35 in location 9
:(before "Read element" following "case GET:")
element.properties.push_back(pair<string, string_tree*>("raw", NULL));
//:: fix 'index'
:(scenario lookup_sidesteps_default_space_in_index)
def main [
# pretend pointer to array from outside (2000 reserved for refcount)
2001:num <- copy 2 # length
2002:num <- copy 34
2003:num <- copy 35
# pretend address:array:location; in practice we'll use 'new'
1000:num <- copy 0 # refcount
1001:num <- copy 5 # length
# actual start of this recipe
default-space:space <- copy 1000/unsafe
1:&:@:num <- copy 2000/unsafe
9:num/raw <- index *1:&:@:num, 1
]
+mem: storing 35 in location 9
:(before "Read element" following "case INDEX:")
element.properties.push_back(pair<string, string_tree*>("raw", NULL));
//:: 'new-default-space' is a convenience operation to automatically deduce
//:: the amount of space to allocate in a default space with names
:(scenario new_default_space)
def main [
new-default-space
x:num <- copy 0
y:num <- copy 3
]
# allocate space for x and y, as well as the chaining slot at 0
+mem: array length is 3
:(before "End is_disqualified Special-cases")
if (x.name == "number-of-locals")
x.initialized = true;
:(before "End is_special_name Special-cases")
if (s == "number-of-locals") return true;
:(before "End Rewrite Instruction(curr, recipe result)")
// rewrite 'new-default-space' to
// ```
// default-space:space <- new location:type, number-of-locals:literal
// ```
// where number-of-locals is Name[recipe][""]
if (curr.name == "new-default-space") {
rewrite_default_space_instruction(curr);
}
:(after "Begin Preprocess read_memory(x)")
if (x.name == "number-of-locals") {
vector<double> result;
result.push_back(Name[get(Recipe_ordinal, current_recipe_name())][""]);
if (result.back() == 0)
raise << "no space allocated for default-space in recipe " << current_recipe_name() << "; are you using names?\n" << end();
return result;
}
:(after "Begin Preprocess write_memory(x, data)")
if (x.name == "number-of-locals") {
raise << maybe(current_recipe_name()) << "can't write to special name 'number-of-locals'\n" << end();
return;
}
//:: 'local-scope' is like 'new-default-space' except that we'll reclaim the
//:: default-space when the routine exits
:(scenario local_scope)
def main [
1:&:@:location <- foo
2:&:@:location <- foo
3:bool <- equal 1:&, 2:&
]
def foo [
local-scope
x:num <- copy 34
return default-space:space
]
# both calls to foo should have received the same default-space
+mem: storing 1 in location 3
:(scenario local_scope_frees_up_addresses)
def main [
local-scope
x:text <- new [abc]
]
+mem: clearing x:text
:(before "End Rewrite Instruction(curr, recipe result)")
if (curr.name == "local-scope") {
rewrite_default_space_instruction(curr);
}
//: todo: do this in a transform, rather than magically in the 'return' instruction
:(after "Falling Through End Of Recipe")
try_reclaim_locals();
:(after "Starting Reply")
try_reclaim_locals();
:(code)
void try_reclaim_locals() {
if (!Reclaim_memory) return;
// only reclaim routines starting with 'local-scope'
const recipe_ordinal r = get(Recipe_ordinal, current_recipe_name());
const recipe& exiting_recipe = get(Recipe, r);
if (exiting_recipe.steps.empty()) return;
const instruction& inst = exiting_recipe.steps.at(0);
if (inst.name_before_rewrite != "local-scope") return;
// reclaim any local variables unless they're being returned
vector<double> zeros;
for (int i = /*leave default space for last*/1; i < SIZE(exiting_recipe.steps); ++i) {
const instruction& inst = exiting_recipe.steps.at(i);
for (int i = 0; i < SIZE(inst.products); ++i) {
const reagent& product = inst.products.at(i);
// local variables only
if (has_property(product, "lookup")) continue;
if (has_property(product, "raw")) continue; // tests often want to check such locations after they run
if (escaping(product)) continue;
// End Checks For Reclaiming Locals
trace(9999, "mem") << "clearing " << product.original_string << end();
zeros.resize(size_of(product));
write_memory(product, zeros);
}
}
trace(9999, "mem") << "automatically abandoning " << current_call().default_space << end();
abandon(current_call().default_space,
inst.products.at(0).type->right,
/*refcount*/1 + /*array length*/1 + /*number-of-locals*/Name[r][""]);
}
//: Reclaiming local variables above requires remembering what name an
//: instruction had before any rewrites or transforms.
:(before "End instruction Fields")
string name_before_rewrite;
:(before "End instruction Clear")
name_before_rewrite.clear();
:(before "End next_instruction(curr)")
curr->name_before_rewrite = curr->name;
:(code)
// is this reagent one of the values returned by the current (return) instruction?
// is the corresponding ingredient saved in the caller?
bool escaping(const reagent& r) {
assert(Current_routine); // run-time only
// nothing escapes when you fall through past end of recipe
if (current_step_index() >= SIZE(Current_routine->steps())) return false;
for (long long i = 0; i < SIZE(current_instruction().ingredients); ++i) {
if (r == current_instruction().ingredients.at(i)) {
if (caller_uses_product(i))
return true;
}
}
return false;
}
//: since we don't decrement refcounts for escaping values above, make sure we
//: don't increment them when the caller saves them either
:(before "End should_update_refcounts() Special-cases")
if (Writing_products_of_instruction) {
const instruction& inst = current_instruction();
// should_update_refcounts() Special-cases When Writing Products Of Primitive Instructions
if (inst.operation < MAX_PRIMITIVE_RECIPES) return true;
if (!contains_key(Recipe, inst.operation)) return true;
const recipe& callee = get(Recipe, inst.operation);
if (callee.steps.empty()) return true;
return callee.steps.at(0).name_before_rewrite != "local-scope"; // callees that call local-scope are already dealt with before return
}
:(code)
bool caller_uses_product(int product_index) {
assert(Current_routine); // run-time only
assert(!Current_routine->calls.empty());
if (Current_routine->calls.size() == 1) return false;
const call& caller = *++Current_routine->calls.begin();
const instruction& caller_inst = to_instruction(caller);
if (product_index >= SIZE(caller_inst.products)) return false;
return !is_dummy(caller_inst.products.at(product_index));
}
void rewrite_default_space_instruction(instruction& curr) {
if (!curr.ingredients.empty())
raise << "'" << to_original_string(curr) << "' can't take any ingredients\n" << end();
curr.name = "new";
curr.ingredients.push_back(reagent("location:type"));
curr.ingredients.push_back(reagent("number-of-locals:literal"));
if (!curr.products.empty())
raise << "new-default-space can't take any results\n" << end();
curr.products.push_back(reagent("default-space:space"));
}
:(scenario local_scope_frees_up_addresses_inside_containers)
container foo [
x:num
y:&:num
]
def main [
local-scope
x:&:num <- new number:type
y:foo <- merge 34, x:&:num
# x and y are both cleared when main returns
]
+mem: clearing x:&:num
+mem: decrementing refcount of 1006: 2 -> 1
+mem: clearing y:foo
+mem: decrementing refcount of 1006: 1 -> 0
+mem: automatically abandoning 1006
:(scenario local_scope_returns_addresses_inside_containers)
container foo [
x:num
y:&:num
]
def f [
local-scope
x:&:num <- new number:type
*x:&:num <- copy 12
y:foo <- merge 34, x:&:num
# since y is 'escaping' f, it should not be cleared
return y:foo
]
def main [
1:foo <- f
3:num <- get 1:foo, x:offset
4:&:num <- get 1:foo, y:offset
5:num <- copy *4:&:num
1:foo <- put 1:foo, y:offset, 0
4:&:num <- copy 0
]
+mem: storing 34 in location 1
+mem: storing 1006 in location 2
+mem: storing 34 in location 3
# refcount of 1:foo shouldn't include any stray ones from f
+run: {4: ("address" "number")} <- get {1: "foo"}, {y: "offset"}
+mem: incrementing refcount of 1006: 1 -> 2
# 1:foo wasn't abandoned/cleared
+run: {5: "number"} <- copy {4: ("address" "number"), "lookup": ()}
+mem: storing 12 in location 5
+run: {1: "foo"} <- put {1: "foo"}, {y: "offset"}, {0: "literal"}
+mem: decrementing refcount of 1006: 2 -> 1
+run: {4: ("address" "number")} <- copy {0: "literal"}
+mem: decrementing refcount of 1006: 1 -> 0
+mem: automatically abandoning 1006
:(scenario local_scope_claims_return_values_when_not_saved)
def f [
local-scope
x:&:num <- new number:type
return x:&:num
]
def main [
f # doesn't save result
]
# x reclaimed
+mem: automatically abandoning 1004
# f's local scope reclaimed
+mem: automatically abandoning 1000
//:: all recipes must set default-space one way or another
:(before "End Globals")
bool Hide_missing_default_space_errors = true;
:(before "End Checks")
Transform.push_back(check_default_space); // idempotent
:(code)
void check_default_space(const recipe_ordinal r) {
if (Hide_missing_default_space_errors) return; // skip previous core tests; this is only for Mu code
const recipe& caller = get(Recipe, r);
// End check_default_space Special-cases
// assume recipes with only numeric addresses know what they're doing (usually tests)
if (!contains_non_special_name(r)) return;
trace(9991, "transform") << "--- check that recipe " << caller.name << " sets default-space" << end();
if (caller.steps.empty()) return;
if (caller.steps.at(0).products.empty()
|| caller.steps.at(0).products.at(0).name != "default-space") {
raise << caller.name << " does not seem to start with 'local-scope' or 'default-space'\n" << end();
}
}
:(after "Load Mu Prelude")
Hide_missing_default_space_errors = false;
:(after "Test Runs")
Hide_missing_default_space_errors = true;
:(after "Running Main")
Hide_missing_default_space_errors = false;
:(code)
bool contains_non_special_name(const recipe_ordinal r) {
for (map<string, int>::iterator p = Name[r].begin(); p != Name[r].end(); ++p) {
if (p->first.empty()) continue;
if (p->first.find("stash_") == 0) continue; // generated by rewrite_stashes_to_text (cross-layer)
if (!is_special_name(p->first))
return true;
}
return false;
}
// reagent comparison -- only between reagents in a single recipe
bool operator==(const reagent& a, const reagent& b) {
if (a.name != b.name) return false;
if (property(a, "space") != property(b, "space")) return false;
return true;
}
bool operator<(const reagent& a, const reagent& b) {
int aspace = 0, bspace = 0;
if (has_property(a, "space")) aspace = to_integer(property(a, "space")->value);
if (has_property(b, "space")) bspace = to_integer(property(b, "space")->value);
if (aspace != bspace) return aspace < bspace;
return a.name < b.name;
}