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|
//: Update refcounts when copying addresses.
//: The top of the address layer has more on refcounts.
:(scenario refcounts)
def main [
1:address:num <- copy 1000/unsafe
2:address:num <- copy 1:address:num
1:address:num <- copy 0
2:address:num <- copy 0
]
+run: {1: ("address" "number")} <- copy {1000: "literal", "unsafe": ()}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: ("address" "number")} <- copy {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {1: ("address" "number")} <- copy {0: "literal"}
+mem: decrementing refcount of 1000: 2 -> 1
+run: {2: ("address" "number")} <- copy {0: "literal"}
+mem: decrementing refcount of 1000: 1 -> 0
:(after "Writing Instruction Product(i)")
if (is_primitive(current_instruction().operation)) {
reagent/*copy*/ tmp = current_instruction().products.at(i);
canonize(tmp);
update_any_refcounts(tmp, products.at(i));
}
:(before "End Globals")
bool Reclaim_memory = true;
:(before "End Commandline Options(*arg)")
else if (is_equal(*arg, "--no-reclaim")) {
cerr << "Disabling memory reclamation. Some tests will fail.\n";
Reclaim_memory = false;
}
:(code)
void update_any_refcounts(const reagent& canonized_x, const vector<double>& data) {
if (!Reclaim_memory) return;
increment_any_refcounts(canonized_x, data); // increment first so we don't reclaim on x <- copy x
decrement_any_refcounts(canonized_x);
}
void increment_any_refcounts(const reagent& canonized_x, const vector<double>& data) {
if (is_mu_address(canonized_x)) {
assert(scalar(data));
assert(!canonized_x.metadata.size);
increment_refcount(data.at(0));
}
// End Increment Refcounts(canonized_x)
}
void increment_refcount(int new_address) {
assert(new_address >= 0);
if (new_address == 0) return;
++Total_refcount_updates;
int new_refcount = get_or_insert(Memory, new_address);
trace("mem") << "incrementing refcount of " << new_address << ": " << new_refcount << " -> " << new_refcount+1 << end();
put(Memory, new_address, new_refcount+1);
}
void decrement_any_refcounts(const reagent& canonized_x) {
// Begin Decrement Refcounts(canonized_x)
if (is_mu_address(canonized_x) && canonized_x.value != 0) {
assert(!canonized_x.metadata.size);
decrement_refcount(get_or_insert(Memory, canonized_x.value), payload_type(canonized_x.type), payload_size(canonized_x));
}
// End Decrement Refcounts(canonized_x)
}
void decrement_refcount(int old_address, const type_tree* payload_type, int payload_size) {
assert(old_address >= 0);
if (old_address == 0) return;
++Total_refcount_updates;
int old_refcount = get_or_insert(Memory, old_address);
trace("mem") << "decrementing refcount of " << old_address << ": " << old_refcount << " -> " << old_refcount-1 << end();
--old_refcount;
put(Memory, old_address, old_refcount);
if (old_refcount < 0) {
cerr << "Negative refcount!!! " << old_address << ' ' << old_refcount << '\n';
if (Trace_stream) Trace_stream->dump();
exit(1);
}
// End Decrement Refcount(old_address, payload_type, payload_size)
}
int payload_size(reagent/*copy*/ x) {
x.properties.push_back(pair<string, string_tree*>("lookup", NULL));
lookup_memory_core(x, /*check for nulls*/false);
return size_of(x) + /*refcount*/1;
}
:(scenario refcounts_reflexive)
def main [
1:address:num <- new number:type
# idempotent copies leave refcount unchanged
1:address:num <- copy 1:address:num
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {1: ("address" "number")} <- copy {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+mem: decrementing refcount of 1000: 2 -> 1
:(scenario refcounts_call)
def main [
1:address:num <- new number:type
# passing in addresses to recipes increments refcount
foo 1:address:num
# return does NOT yet decrement refcount; memory must be explicitly managed
1:address:num <- new number:type
]
def foo [
2:address:num <- next-ingredient
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: foo {1: ("address" "number")}
# leave ambiguous precisely when the next increment happens
+mem: incrementing refcount of 1000: 1 -> 2
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: decrementing refcount of 1000: 2 -> 1
//: fix up any instructions that don't follow the usual flow of read_memory
//: before the RUN switch, and write_memory after
:(scenario refcounts_put)
container foo [
x:address:num
]
def main [
1:address:num <- new number:type
2:address:foo <- new foo:type
*2:address:foo <- put *2:address:foo, x:offset, 1:address:num
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: ("address" "foo")} <- new {foo: "type"}
+mem: incrementing refcount of 1002: 0 -> 1
+run: {2: ("address" "foo"), "lookup": ()} <- put {2: ("address" "foo"), "lookup": ()}, {x: "offset"}, {1: ("address" "number")}
# put increments refcount
+mem: incrementing refcount of 1000: 1 -> 2
:(after "Write Memory in PUT in Run")
reagent/*copy*/ element = element_type(base.type, offset);
assert(!has_property(element, "lookup"));
element.set_value(address);
update_any_refcounts(element, ingredients.at(2));
:(scenario refcounts_put_index)
def main [
1:address:num <- new number:type
2:address:array:address:num <- new {(address number): type}, 3
*2:address:array:address:num <- put-index *2:address:array:address:num, 0, 1:address:num
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: ("address" "array" "address" "number")} <- new {(address number): "type"}, {3: "literal"}
+mem: incrementing refcount of 1002: 0 -> 1
+run: {2: ("address" "array" "address" "number"), "lookup": ()} <- put-index {2: ("address" "array" "address" "number"), "lookup": ()}, {0: "literal"}, {1: ("address" "number")}
# put-index increments refcount
+mem: incrementing refcount of 1000: 1 -> 2
:(after "Write Memory in PUT_INDEX in Run")
reagent/*local*/ element;
element.set_value(address);
element.type = copy_array_element(base.type);
update_any_refcounts(element, value);
:(scenario refcounts_maybe_convert)
exclusive-container foo [
x:num
p:address:num
]
def main [
1:address:num <- new number:type
2:foo <- merge 1/p, 1:address:num
4:address:num, 5:bool <- maybe-convert 2:foo, 1:variant/p
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
# merging in an address increments refcount
+run: {2: "foo"} <- merge {1: "literal", "p": ()}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {4: ("address" "number")}, {5: "boolean"} <- maybe-convert {2: "foo"}, {1: "variant", "p": ()}
# maybe-convert increments refcount on success
+mem: incrementing refcount of 1000: 2 -> 3
:(after "Write Memory in Successful MAYBE_CONVERT")
// todo: double-check data here as well
vector<double> data;
for (int i = 0; i < size_of(product); ++i)
data.push_back(get_or_insert(Memory, base_address+/*skip tag*/1+i));
update_any_refcounts(product, data);
//:: manage refcounts in instructions that copy multiple locations at a time
:(scenario refcounts_copy_nested)
container foo [
x:address:num # address inside container
]
def main [
1:address:num <- new number:type
2:address:foo <- new foo:type
*2:address:foo <- put *2:address:foo, x:offset, 1:address:num
3:foo <- copy *2:address:foo
]
+transform: compute address offsets for container foo
+transform: checking container foo, element 0
+transform: address at offset 0
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: ("address" "foo"), "lookup": ()} <- put {2: ("address" "foo"), "lookup": ()}, {x: "offset"}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
# copying a container increments refcounts of any contained addresses
+run: {3: "foo"} <- copy {2: ("address" "foo"), "lookup": ()}
+mem: incrementing refcount of 1000: 2 -> 3
:(before "End type_tree Definition")
struct address_element_info {
// Where inside a container type (after flattening nested containers!) the
// address lies
int offset;
// All the information we need to compute sizes of items inside an address
// inside a container. 'payload_type' doesn't need to be a full-scale
// reagent because an address inside a container can never be an array, and
// because arrays are the only type that need to know their location to
// compute their size.
const type_tree* payload_type;
address_element_info(int o, const type_tree* p);
address_element_info(const address_element_info& other);
~address_element_info();
address_element_info& operator=(const address_element_info& other);
};
:(code)
address_element_info::address_element_info(int o, const type_tree* p) {
offset = o;
payload_type = p;
}
address_element_info::address_element_info(const address_element_info& other) {
offset = other.offset;
payload_type = copy(other.payload_type);
}
address_element_info::~address_element_info() {
if (payload_type) {
delete payload_type;
payload_type = NULL;
}
}
address_element_info& address_element_info::operator=(const address_element_info& other) {
offset = other.offset;
if (payload_type) delete payload_type;
payload_type = copy(other.payload_type);
return *this;
}
:(before "End type_tree Definition")
// For exclusive containers we might sometimes have an address at some offset
// if some other offset has a specific tag. This struct encapsulates such
// guards.
struct tag_condition_info {
int offset;
int tag;
tag_condition_info(int o, int t) :offset(o), tag(t) {}
};
:(before "End container_metadata Fields")
// a list of facts of the form:
//
// IF offset o1 has tag t2 AND offset o2 has tag t2 AND .., THEN
// for all address_element_infos:
// you need to update refcounts for the address at offset pointing to a payload of type payload_type (just in case we need to abandon something in the process)
map<set<tag_condition_info>, set<address_element_info> > address;
:(code)
bool operator<(const set<tag_condition_info>& a, const set<tag_condition_info>& b) {
if (a.size() != b.size()) return a.size() < b.size();
for (set<tag_condition_info>::const_iterator pa = a.begin(), pb = b.begin(); pa != a.end(); ++pa, ++pb) {
if (pa->offset != pb->offset) return pa->offset < pb->offset;
if (pa->tag != pb->tag) return pa->tag < pb->tag;
}
return false; // equal
}
bool operator<(const tag_condition_info& a, const tag_condition_info& b) {
if (a.offset != b.offset) return a.offset < b.offset;
if (a.tag != b.tag) return a.tag < b.tag;
return false; // equal
}
bool operator<(const set<address_element_info>& a, const set<address_element_info>& b) {
if (a.size() != b.size()) return a.size() < b.size();
for (set<address_element_info>::const_iterator pa = a.begin(), pb = b.begin(); pa != a.end(); ++pa, ++pb) {
if (pa->offset != pb->offset) return pa->offset < pb->offset;
}
return false; // equal
}
bool operator<(const address_element_info& a, const address_element_info& b) {
if (a.offset != b.offset) return a.offset < b.offset;
return false; // equal
}
//: populate metadata.address in a separate transform, because it requires
//: already knowing the sizes of all types
:(after "Transform.push_back(compute_container_sizes)")
Transform.push_back(compute_container_address_offsets); // idempotent
:(code)
void compute_container_address_offsets(const recipe_ordinal r) {
recipe& caller = get(Recipe, r);
trace(9992, "transform") << "--- compute address offsets for " << caller.name << end();
for (int i = 0; i < SIZE(caller.steps); ++i) {
instruction& inst = caller.steps.at(i);
trace(9993, "transform") << "- compute address offsets for " << to_string(inst) << end();
for (int i = 0; i < SIZE(inst.ingredients); ++i)
compute_container_address_offsets(inst.ingredients.at(i), " in '"+inst.original_string+"'");
for (int i = 0; i < SIZE(inst.products); ++i)
compute_container_address_offsets(inst.products.at(i), " in '"+inst.original_string+"'");
}
}
void compute_container_address_offsets(reagent& r, const string& location_for_error_messages) {
if (is_literal(r) || is_dummy(r)) return;
compute_container_address_offsets(r.type, location_for_error_messages);
if (contains_key(Container_metadata, r.type))
r.metadata = get(Container_metadata, r.type);
}
// the recursive structure of this function needs to exactly match
// compute_container_sizes
void compute_container_address_offsets(const type_tree* type, const string& location_for_error_messages) {
if (!type) return;
if (!type->atom) {
if (!type->left->atom) {
raise << "invalid type " << to_string(type) << location_for_error_messages << '\n' << end();
return;
}
if (type->left->name == "address")
compute_container_address_offsets(payload_type(type), location_for_error_messages);
else if (type->left->name == "array")
compute_container_address_offsets(array_element(type), location_for_error_messages);
// End compute_container_address_offsets Non-atom Special-cases
}
const type_tree* base_type = type;
// Update base_type in compute_container_address_offsets
if (!contains_key(Type, base_type->value)) return; // error raised elsewhere
type_info& info = get(Type, base_type->value);
if (info.kind == CONTAINER) {
compute_container_address_offsets(info, type, location_for_error_messages);
}
if (info.kind == EXCLUSIVE_CONTAINER) {
compute_exclusive_container_address_offsets(info, type, location_for_error_messages);
}
}
void compute_container_address_offsets(const type_info& container_info, const type_tree* full_type, const string& location_for_error_messages) {
container_metadata& metadata = get(Container_metadata, full_type);
if (!metadata.address.empty()) return;
trace(9994, "transform") << "compute address offsets for container " << container_info.name << end();
append_addresses(0, full_type, metadata.address, set<tag_condition_info>(), location_for_error_messages);
}
void compute_exclusive_container_address_offsets(const type_info& exclusive_container_info, const type_tree* full_type, const string& location_for_error_messages) {
container_metadata& metadata = get(Container_metadata, full_type);
trace(9994, "transform") << "compute address offsets for exclusive container " << exclusive_container_info.name << end();
for (int tag = 0; tag < SIZE(exclusive_container_info.elements); ++tag) {
set<tag_condition_info> key;
key.insert(tag_condition_info(/*tag is at offset*/0, tag));
append_addresses(/*skip tag offset*/1, variant_type(full_type, tag).type, metadata.address, key, location_for_error_messages);
}
}
void append_addresses(int base_offset, const type_tree* type, map<set<tag_condition_info>, set<address_element_info> >& out, const set<tag_condition_info>& key, const string& location_for_error_messages) {
if (is_mu_address(type)) {
get_or_insert(out, key).insert(address_element_info(base_offset, new type_tree(*payload_type(type))));
return;
}
const type_tree* base_type = type;
// Update base_type in append_container_address_offsets
const type_info& info = get(Type, base_type->value);
if (info.kind == CONTAINER) {
for (int curr_index = 0, curr_offset = base_offset; curr_index < SIZE(info.elements); ++curr_index) {
trace(9993, "transform") << "checking container " << base_type->name << ", element " << curr_index << end();
reagent/*copy*/ element = element_type(type, curr_index); // not base_type
// Compute Container Address Offset(element)
if (is_mu_address(element)) {
trace(9993, "transform") << "address at offset " << curr_offset << end();
get_or_insert(out, key).insert(address_element_info(curr_offset, new type_tree(*payload_type(element.type))));
++curr_offset;
}
else if (is_mu_array(element)) {
curr_offset += /*array length*/1;
const type_tree* array_element_type = array_element(element.type);
int array_element_size = size_of(array_element_type);
for (int i = 0; i < static_array_length(element.type); ++i) {
append_addresses(curr_offset, array_element_type, out, key, location_for_error_messages);
curr_offset += array_element_size;
}
}
else if (is_mu_container(element)) {
append_addresses(curr_offset, element.type, out, key, location_for_error_messages);
curr_offset += size_of(element);
}
else if (is_mu_exclusive_container(element)) {
const type_tree* element_base_type = element.type;
// Update element_base_type For Exclusive Container in append_addresses
const type_info& element_info = get(Type, element_base_type->value);
for (int tag = 0; tag < SIZE(element_info.elements); ++tag) {
set<tag_condition_info> new_key = key;
new_key.insert(tag_condition_info(curr_offset, tag));
if (!contains_key(out, new_key))
append_addresses(curr_offset+/*skip tag*/1, variant_type(element.type, tag).type, out, new_key, location_for_error_messages);
}
curr_offset += size_of(element);
}
else {
// non-address primitive
++curr_offset;
}
}
}
else if (info.kind == EXCLUSIVE_CONTAINER) {
for (int tag = 0; tag < SIZE(info.elements); ++tag) {
set<tag_condition_info> new_key = key;
new_key.insert(tag_condition_info(base_offset, tag));
if (!contains_key(out, new_key))
append_addresses(base_offset+/*skip tag*/1, variant_type(type, tag).type, out, new_key, location_for_error_messages);
}
}
}
//: for the following unit tests we'll do the work of the transform by hand
:(before "End Unit Tests")
void test_container_address_offsets_empty() {
int old_size = SIZE(Container_metadata);
// define a container with no addresses
reagent r("x:point");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// scan
compute_container_address_offsets(r, "");
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// the reagent we scanned knows it has no addresses
CHECK(r.metadata.address.empty());
// the global table contains an identical entry
CHECK(contains_key(Container_metadata, r.type));
CHECK(get(Container_metadata, r.type).address.empty());
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
}
void test_container_address_offsets() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0 that we have the size for
run("container foo [\n"
" x:address:num\n"
"]\n");
reagent r("x:foo");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// scan
compute_container_address_offsets(r, "");
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// the reagent we scanned knows it has an address at offset 0
CHECK_EQ(SIZE(r.metadata.address), 1);
CHECK(contains_key(r.metadata.address, set<tag_condition_info>()));
const set<address_element_info>& address_offsets = get(r.metadata.address, set<tag_condition_info>()); // unconditional for containers
CHECK_EQ(SIZE(address_offsets), 1);
CHECK_EQ(address_offsets.begin()->offset, 0);
CHECK(address_offsets.begin()->payload_type->atom);
CHECK_EQ(address_offsets.begin()->payload_type->name, "number");
// the global table contains an identical entry
CHECK(contains_key(Container_metadata, r.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, r.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
}
void test_container_address_offsets_2() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 1 that we have the size for
run("container foo [\n"
" x:num\n"
" y:address:num\n"
"]\n");
reagent r("x:foo");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scan
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// the reagent we scanned knows it has an address at offset 1
CHECK_EQ(SIZE(r.metadata.address), 1);
CHECK(contains_key(r.metadata.address, set<tag_condition_info>()));
const set<address_element_info>& address_offsets = get(r.metadata.address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets), 1);
CHECK_EQ(address_offsets.begin()->offset, 1); //
CHECK(address_offsets.begin()->payload_type->atom);
CHECK_EQ(address_offsets.begin()->payload_type->name, "number");
// the global table contains an identical entry
CHECK(contains_key(Container_metadata, r.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, r.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 1); //
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
void test_container_address_offsets_nested() {
int old_size = SIZE(Container_metadata);
// define a container with a nested container containing an address
run("container foo [\n"
" x:address:num\n"
" y:num\n"
"]\n"
"container bar [\n"
" p:point\n"
" f:foo\n" // nested container containing address
"]\n");
reagent r("x:bar");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains entries for bar and included types: point and foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 3);
// scan
compute_container_address_offsets(r, "");
// the reagent we scanned knows it has an address at offset 2
CHECK_EQ(SIZE(r.metadata.address), 1);
CHECK(contains_key(r.metadata.address, set<tag_condition_info>()));
const set<address_element_info>& address_offsets = get(r.metadata.address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets), 1);
CHECK_EQ(address_offsets.begin()->offset, 2); //
CHECK(address_offsets.begin()->payload_type->atom);
CHECK_EQ(address_offsets.begin()->payload_type->name, "number");
// the global table also knows its address offset
CHECK(contains_key(Container_metadata, r.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, r.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 2); //
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 3);
}
void test_container_address_offsets_from_address() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0
run("container foo [\n"
" x:address:num\n"
"]\n");
reagent r("x:address:foo");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scan an address to the container
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scanning precomputed metadata for the container
reagent container("x:foo");
CHECK(contains_key(Container_metadata, container.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, container.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
void test_container_address_offsets_from_array() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0
run("container foo [\n"
" x:address:num\n"
"]\n");
reagent r("x:array:foo");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scan an array of the container
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scanning precomputed metadata for the container
reagent container("x:foo");
CHECK(contains_key(Container_metadata, container.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, container.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
void test_container_address_offsets_from_address_to_array() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0
run("container foo [\n"
" x:address:num\n"
"]\n");
reagent r("x:address:array:foo");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scan an address to an array of the container
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scanning precomputed metadata for the container
reagent container("x:foo");
CHECK(contains_key(Container_metadata, container.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, container.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
void test_container_address_offsets_from_static_array() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0
run("container foo [\n"
" x:address:num\n"
"]\n");
reagent r("x:array:foo:10");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scan a static array of the container
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scanning precomputed metadata for the container
reagent container("x:foo");
CHECK(contains_key(Container_metadata, container.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, container.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
void test_container_address_offsets_from_address_to_static_array() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0
run("container foo [\n"
" x:address:num\n"
"]\n");
reagent r("x:address:array:foo:10");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scan an address to a static array of the container
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scanning precomputed metadata for the container
reagent container("x:foo");
CHECK(contains_key(Container_metadata, container.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, container.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
void test_container_address_offsets_from_repeated_address_and_array_types() {
int old_size = SIZE(Container_metadata);
// define a container with an address at offset 0
run("container foo [\n"
" x:address:num\n"
"]\n");
// scan a deep nest of 'address' and 'array' types modifying a container
reagent r("x:address:array:address:address:array:foo:10");
compute_container_sizes(r, ""); // need to first pre-populate the metadata
// global metadata contains just the entry for foo
// no entries for non-container types or other junk
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
compute_container_address_offsets(r, "");
// compute_container_address_offsets creates no new entries
CHECK_EQ(SIZE(Container_metadata)-old_size, 1);
// scanning precomputed metadata for the container
reagent container("x:foo");
CHECK(contains_key(Container_metadata, container.type));
const set<address_element_info>& address_offsets2 = get(get(Container_metadata, container.type).address, set<tag_condition_info>());
CHECK_EQ(SIZE(address_offsets2), 1);
CHECK_EQ(address_offsets2.begin()->offset, 0);
CHECK(address_offsets2.begin()->payload_type->atom);
CHECK_EQ(address_offsets2.begin()->payload_type->name, "number");
}
//: use metadata.address to update refcounts within containers, arrays and
//: exclusive containers
:(before "End Increment Refcounts(canonized_x)")
if (is_mu_container(canonized_x) || is_mu_exclusive_container(canonized_x)) {
const container_metadata& metadata = get(Container_metadata, canonized_x.type);
for (map<set<tag_condition_info>, set<address_element_info> >::const_iterator p = metadata.address.begin(); p != metadata.address.end(); ++p) {
if (!all_match(data, p->first)) continue;
for (set<address_element_info>::const_iterator info = p->second.begin(); info != p->second.end(); ++info)
increment_refcount(data.at(info->offset));
}
}
:(before "End Decrement Refcounts(canonized_x)")
if (is_mu_container(canonized_x) || is_mu_exclusive_container(canonized_x)) {
trace("mem") << "need to read old value of '" << to_string(canonized_x) << "' to figure out what refcounts to decrement" << end();
// read from canonized_x but without canonizing again
reagent/*copy*/ tmp = canonized_x;
tmp.properties.push_back(pair<string, string_tree*>("raw", NULL));
vector<double> data = read_memory(tmp);
trace("mem") << "done reading old value of '" << to_string(canonized_x) << "'" << end();
const container_metadata& metadata = get(Container_metadata, canonized_x.type);
for (map<set<tag_condition_info>, set<address_element_info> >::const_iterator p = metadata.address.begin(); p != metadata.address.end(); ++p) {
if (!all_match(data, p->first)) continue;
for (set<address_element_info>::const_iterator info = p->second.begin(); info != p->second.end(); ++info) {
int element_address = get_or_insert(Memory, canonized_x.value + info->offset);
reagent/*local*/ element;
element.set_value(element_address+/*skip refcount*/1);
element.type = new type_tree(*info->payload_type);
decrement_refcount(element_address, info->payload_type, size_of(element)+/*refcount*/1);
}
}
}
:(code)
bool all_match(const vector<double>& data, const set<tag_condition_info>& conditions) {
for (set<tag_condition_info>::const_iterator p = conditions.begin(); p != conditions.end(); ++p) {
if (data.at(p->offset) != p->tag)
return false;
}
return true;
}
:(scenario refcounts_put_container)
container foo [
a:bar # contains an address
]
container bar [
x:address:num
]
def main [
1:address:num <- new number:type
2:bar <- merge 1:address:num
3:address:foo <- new foo:type
*3:address:foo <- put *3:address:foo, a:offset, 2:bar
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: "bar"} <- merge {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {3: ("address" "foo"), "lookup": ()} <- put {3: ("address" "foo"), "lookup": ()}, {a: "offset"}, {2: "bar"}
# put increments refcount inside container
+mem: incrementing refcount of 1000: 2 -> 3
:(scenario refcounts_put_index_array)
container bar [
x:address:num
]
def main [
1:address:num <- new number:type
2:bar <- merge 1:address:num
3:address:array:bar <- new bar:type, 3
*3:address:array:bar <- put-index *3:address:array:bar, 0, 2:bar
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: "bar"} <- merge {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {3: ("address" "array" "bar"), "lookup": ()} <- put-index {3: ("address" "array" "bar"), "lookup": ()}, {0: "literal"}, {2: "bar"}
# put-index increments refcount inside container
+mem: incrementing refcount of 1000: 2 -> 3
:(scenario refcounts_maybe_convert_container)
exclusive-container foo [
a:num
b:bar # contains an address
]
container bar [
x:address:num
]
def main [
1:address:num <- new number:type
2:bar <- merge 1:address:num
3:foo <- merge 1/b, 2:bar
5:bar, 6:bool <- maybe-convert 3:foo, 1:variant/b
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: "bar"} <- merge {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {3: "foo"} <- merge {1: "literal", "b": ()}, {2: "bar"}
+mem: incrementing refcount of 1000: 2 -> 3
+run: {5: "bar"}, {6: "boolean"} <- maybe-convert {3: "foo"}, {1: "variant", "b": ()}
+mem: incrementing refcount of 1000: 3 -> 4
:(scenario refcounts_copy_doubly_nested)
container foo [
a:bar # no addresses
b:curr # contains addresses
]
container bar [
x:num
y:num
]
container curr [
x:num
y:address:num # address inside container inside container
]
def main [
1:address:num <- new number:type
2:address:curr <- new curr:type
*2:address:curr <- put *2:address:curr, 1:offset/y, 1:address:num
3:address:foo <- new foo:type
*3:address:foo <- put *3:address:foo, 1:offset/b, *2:address:curr
4:foo <- copy *3:address:foo
]
+transform: compute address offsets for container foo
+transform: checking container foo, element 1
+transform: address at offset 3
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
# storing an address in a container updates its refcount
+run: {2: ("address" "curr"), "lookup": ()} <- put {2: ("address" "curr"), "lookup": ()}, {1: "offset", "y": ()}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
# storing a container in a container updates refcounts of any contained addresses
+run: {3: ("address" "foo"), "lookup": ()} <- put {3: ("address" "foo"), "lookup": ()}, {1: "offset", "b": ()}, {2: ("address" "curr"), "lookup": ()}
+mem: incrementing refcount of 1000: 2 -> 3
# copying a container containing a container containing an address updates refcount
+run: {4: "foo"} <- copy {3: ("address" "foo"), "lookup": ()}
+mem: incrementing refcount of 1000: 3 -> 4
:(scenario refcounts_copy_exclusive_container_within_container)
container foo [
a:num
b:bar
]
exclusive-container bar [
x:num
y:num
z:address:num
]
def main [
1:address:num <- new number:type
2:bar <- merge 0/x, 34
3:foo <- merge 12, 2:bar
5:bar <- merge 1/y, 35
6:foo <- merge 13, 5:bar
8:bar <- merge 2/z, 1:address:num
9:foo <- merge 14, 8:bar
11:foo <- copy 9:foo
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
# no change while merging items of other types
+run: {8: "bar"} <- merge {2: "literal", "z": ()}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {9: "foo"} <- merge {14: "literal"}, {8: "bar"}
+mem: incrementing refcount of 1000: 2 -> 3
+run: {11: "foo"} <- copy {9: "foo"}
+mem: incrementing refcount of 1000: 3 -> 4
:(scenario refcounts_copy_container_within_exclusive_container)
exclusive-container foo [
a:num
b:bar
]
container bar [
x:num
y:num
z:address:num
]
def main [
1:address:num <- new number:type
2:foo <- merge 0/a, 34
6:foo <- merge 0/a, 35
10:bar <- merge 2/x, 15/y, 1:address:num
13:foo <- merge 1/b, 10:bar
17:foo <- copy 13:foo
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
# no change while merging items of other types
+run: {10: "bar"} <- merge {2: "literal", "x": ()}, {15: "literal", "y": ()}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {13: "foo"} <- merge {1: "literal", "b": ()}, {10: "bar"}
+mem: incrementing refcount of 1000: 2 -> 3
+run: {17: "foo"} <- copy {13: "foo"}
+mem: incrementing refcount of 1000: 3 -> 4
:(scenario refcounts_copy_exclusive_container_within_exclusive_container)
exclusive-container foo [
a:num
b:bar
]
exclusive-container bar [
x:num
y:address:num
]
def main [
1:address:num <- new number:type
10:foo <- merge 1/b, 1/y, 1:address:num
20:foo <- copy 10:foo
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
# no change while merging items of other types
+run: {10: "foo"} <- merge {1: "literal", "b": ()}, {1: "literal", "y": ()}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {20: "foo"} <- copy {10: "foo"}
+mem: incrementing refcount of 1000: 2 -> 3
:(scenario refcounts_copy_array_within_container)
container foo [
x:address:array:num
]
def main [
1:address:array:num <- new number:type, 3
2:foo <- merge 1:address:array:num
3:address:array:num <- new number:type, 5
2:foo <- merge 3:address:array:num
]
+run: {1: ("address" "array" "number")} <- new {number: "type"}, {3: "literal"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: "foo"} <- merge {1: ("address" "array" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: {2: "foo"} <- merge {3: ("address" "array" "number")}
+mem: decrementing refcount of 1000: 2 -> 1
:(scenario refcounts_copy_address_within_static_array_within_container)
container foo [
a:array:bar:3
b:address:num
]
container bar [
y:num
z:address:num
]
def main [
1:address:num <- new number:type
2:bar <- merge 34, 1:address:num
10:array:bar:3 <- create-array
put-index 10:array:bar:3, 1, 2:bar
20:foo <- merge 10:array:bar:3, 1:address:num
1:address:num <- copy 0
2:bar <- merge 34, 1:address:num
put-index 10:array:bar:3, 1, 2:bar
20:foo <- merge 10:array:bar:3, 1:address:num
]
+run: {1: ("address" "number")} <- new {number: "type"}
+mem: incrementing refcount of 1000: 0 -> 1
+run: {2: "bar"} <- merge {34: "literal"}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 1 -> 2
+run: put-index {10: ("array" "bar" "3")}, {1: "literal"}, {2: "bar"}
+mem: incrementing refcount of 1000: 2 -> 3
+run: {20: "foo"} <- merge {10: ("array" "bar" "3")}, {1: ("address" "number")}
+mem: incrementing refcount of 1000: 3 -> 4
+mem: incrementing refcount of 1000: 4 -> 5
+run: {1: ("address" "number")} <- copy {0: "literal"}
+mem: decrementing refcount of 1000: 5 -> 4
+run: {2: "bar"} <- merge {34: "literal"}, {1: ("address" "number")}
+mem: decrementing refcount of 1000: 4 -> 3
+run: put-index {10: ("array" "bar" "3")}, {1: "literal"}, {2: "bar"}
+mem: decrementing refcount of 1000: 3 -> 2
+run: {20: "foo"} <- merge {10: ("array" "bar" "3")}, {1: ("address" "number")}
+mem: decrementing refcount of 1000: 2 -> 1
+mem: decrementing refcount of 1000: 1 -> 0
:(scenario refcounts_handle_exclusive_containers_with_different_tags)
container foo1 [
x:address:num
y:num
]
container foo2 [
x:num
y:address:num
]
exclusive-container bar [
a:foo1
b:foo2
]
def main [
1:address:num <- copy 12000/unsafe # pretend allocation
*1:address:num <- copy 34
2:bar <- merge 0/foo1, 1:address:num, 97
5:address:num <- copy 13000/unsafe # pretend allocation
*5:address:num <- copy 35
6:bar <- merge 1/foo2, 98, 5:address:num
2:bar <- copy 6:bar
]
+run: {2: "bar"} <- merge {0: "literal", "foo1": ()}, {1: ("address" "number")}, {97: "literal"}
+mem: incrementing refcount of 12000: 1 -> 2
+run: {6: "bar"} <- merge {1: "literal", "foo2": ()}, {98: "literal"}, {5: ("address" "number")}
+mem: incrementing refcount of 13000: 1 -> 2
+run: {2: "bar"} <- copy {6: "bar"}
+mem: incrementing refcount of 13000: 2 -> 3
+mem: decrementing refcount of 12000: 2 -> 1
:(code)
bool is_mu_container(const reagent& r) {
return is_mu_container(r.type);
}
bool is_mu_container(const type_tree* type) {
if (!type) return false;
// End is_mu_container(type) Special-cases
if (type->value == 0) return false;
if (!contains_key(Type, type->value)) return false; // error raised elsewhere
type_info& info = get(Type, type->value);
return info.kind == CONTAINER;
}
bool is_mu_exclusive_container(const reagent& r) {
return is_mu_exclusive_container(r.type);
}
bool is_mu_exclusive_container(const type_tree* type) {
if (!type) return false;
// End is_mu_exclusive_container(type) Special-cases
if (type->value == 0) return false;
if (!contains_key(Type, type->value)) return false; // error raised elsewhere
type_info& info = get(Type, type->value);
return info.kind == EXCLUSIVE_CONTAINER;
}
//:: Counters for trying to understand where Mu programs are spending time
//:: updating refcounts.
:(before "End Globals")
int Total_refcount_updates = 0;
map<recipe_ordinal, map</*step index*/int, /*num refcount updates*/int> > Num_refcount_updates;
:(after "Running One Instruction")
int initial_num_refcount_updates = Total_refcount_updates;
:(before "End Running One Instruction")
if (Run_profiler) {
Num_refcount_updates[current_call().running_recipe][current_call().running_step_index]
+= (Total_refcount_updates - initial_num_refcount_updates);
initial_num_refcount_updates = Total_refcount_updates;
}
:(before "End Non-primitive Call(caller_frame)")
if (Run_profiler) {
Num_refcount_updates[caller_frame.running_recipe][caller_frame.running_step_index]
+= (Total_refcount_updates - initial_num_refcount_updates);
initial_num_refcount_updates = Total_refcount_updates;
}
:(after "Begin Return")
if (Run_profiler) {
Num_refcount_updates[current_call().running_recipe][current_call().running_step_index]
+= (Total_refcount_updates - initial_num_refcount_updates);
initial_num_refcount_updates = Total_refcount_updates;
}
:(before "End dump_profile")
fout.open("profile.refcounts");
if (fout) {
for (map<recipe_ordinal, recipe>::iterator p = Recipe.begin(); p != Recipe.end(); ++p)
dump_recipe_profile(p->first, p->second, fout);
}
fout.close();
:(code)
void dump_recipe_profile(recipe_ordinal ridx, const recipe& r, ostream& out) {
out << "recipe " << r.name << " [\n";
for (int i = 0; i < SIZE(r.steps); ++i) {
out << std::setw(6) << Num_refcount_updates[ridx][i] << ' ' << to_string(r.steps.at(i)) << '\n';
}
out << "]\n\n";
}
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