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dart / sdk / b58e8d73070684d6662bb1d6eecc57255b201fcf / . / runtime / vm / object_reload.cc
blob: c519034141e8cca474303726eeeced1d09743b3d [file] [log] [blame]
// Copyright (c) 2016, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/object.h"
#include "vm/hash_table.h"
#include "vm/isolate_reload.h"
#include "vm/log.h"
#include "vm/resolver.h"
#include "vm/symbols.h"
namespace dart {
#if !defined(PRODUCT) && !defined(DART_PRECOMPILED_RUNTIME)
DECLARE_FLAG(bool, trace_reload);
DECLARE_FLAG(bool, trace_reload_verbose);
DECLARE_FLAG(bool, two_args_smi_icd);
class ObjectReloadUtils : public AllStatic {
static void DumpLibraryDictionary(const Library& lib) {
DictionaryIterator it(lib);
Object& entry = Object::Handle();
String& name = String::Handle();
TIR_Print("Dumping dictionary for %s\n", lib.ToCString());
while (it.HasNext()) {
entry = it.GetNext();
name = entry.DictionaryName();
TIR_Print("%s -> %s\n", name.ToCString(), entry.ToCString());
}
}
};
void Function::Reparent(const Class& new_cls) const {
set_owner(new_cls);
}
void Function::ZeroEdgeCounters() const {
const Array& saved_ic_data = Array::Handle(ic_data_array());
if (saved_ic_data.IsNull()) {
return;
}
const intptr_t saved_ic_datalength = saved_ic_data.Length();
ASSERT(saved_ic_datalength > 0);
const Array& edge_counters_array =
Array::Handle(Array::RawCast(saved_ic_data.At(0)));
ASSERT(!edge_counters_array.IsNull());
// Fill edge counters array with zeros.
const Smi& zero = Smi::Handle(Smi::New(0));
for (intptr_t i = 0; i < edge_counters_array.Length(); i++) {
edge_counters_array.SetAt(i, zero);
}
}
void Code::ResetICDatas(Zone* zone) const {
// Iterate over the Code's object pool and reset all ICDatas.
#ifdef TARGET_ARCH_IA32
// IA32 does not have an object pool, but, we can iterate over all
// embedded objects by using the variable length data section.
if (!is_alive()) {
return;
}
const Instructions& instrs = Instructions::Handle(zone, instructions());
ASSERT(!instrs.IsNull());
uword base_address = instrs.PayloadStart();
Object& object = Object::Handle(zone);
intptr_t offsets_length = pointer_offsets_length();
const int32_t* offsets = raw_ptr()->data();
for (intptr_t i = 0; i < offsets_length; i++) {
int32_t offset = offsets[i];
RawObject** object_ptr =
reinterpret_cast<RawObject**>(base_address + offset);
RawObject* raw_object = *object_ptr;
if (!raw_object->IsHeapObject()) {
continue;
}
object = raw_object;
if (object.IsICData()) {
ICData::Cast(object).Reset(zone);
}
}
#else
const ObjectPool& pool = ObjectPool::Handle(zone, object_pool());
ASSERT(!pool.IsNull());
pool.ResetICDatas(zone);
#endif
}
void Bytecode::ResetICDatas(Zone* zone) const {
// Iterate over the Bytecode's object pool and reset all ICDatas.
const ObjectPool& pool = ObjectPool::Handle(zone, object_pool());
ASSERT(!pool.IsNull());
pool.ResetICDatas(zone);
}
void ObjectPool::ResetICDatas(Zone* zone) const {
#ifdef TARGET_ARCH_IA32
UNREACHABLE();
#else
Object& object = Object::Handle(zone);
for (intptr_t i = 0; i < Length(); i++) {
ObjectPool::EntryType entry_type = TypeAt(i);
if (entry_type != ObjectPool::kTaggedObject) {
continue;
}
object = ObjectAt(i);
if (object.IsICData()) {
ICData::Cast(object).Reset(zone);
}
}
#endif
}
void Class::CopyStaticFieldValues(const Class& old_cls) const {
// We only update values for non-enum classes.
const bool update_values = !is_enum_class();
IsolateReloadContext* reload_context = Isolate::Current()->reload_context();
ASSERT(reload_context != NULL);
const Array& old_field_list = Array::Handle(old_cls.fields());
Field& old_field = Field::Handle();
String& old_name = String::Handle();
const Array& field_list = Array::Handle(fields());
Field& field = Field::Handle();
String& name = String::Handle();
Instance& value = Instance::Handle();
for (intptr_t i = 0; i < field_list.Length(); i++) {
field = Field::RawCast(field_list.At(i));
name = field.name();
if (field.is_static()) {
// Find the corresponding old field, if it exists, and migrate
// over the field value.
for (intptr_t j = 0; j < old_field_list.Length(); j++) {
old_field = Field::RawCast(old_field_list.At(j));
old_name = old_field.name();
if (name.Equals(old_name)) {
// We only copy values if requested and if the field is not a const
// field. We let const fields be updated with a reload.
if (update_values && !field.is_const()) {
value = old_field.StaticValue();
field.SetStaticValue(value);
}
reload_context->AddStaticFieldMapping(old_field, field);
}
}
}
}
}
void Class::CopyCanonicalConstants(const Class& old_cls) const {
if (is_enum_class()) {
// We do not copy enum classes's canonical constants because we explicitly
// become the old enum values to the new enum values.
return;
}
#if defined(DEBUG)
{
// Class has no canonical constants allocated.
const Array& my_constants = Array::Handle(constants());
ASSERT(my_constants.Length() == 0);
}
#endif // defined(DEBUG).
// Copy old constants into new class.
const Array& old_constants = Array::Handle(old_cls.constants());
if (old_constants.IsNull() || old_constants.Length() == 0) {
return;
}
TIR_Print("Copied %" Pd " canonical constants for class `%s`\n",
old_constants.Length(), ToCString());
set_constants(old_constants);
}
void Class::CopyDeclarationType(const Class& old_cls) const {
const Type& old_declaration_type = Type::Handle(old_cls.declaration_type());
if (old_declaration_type.IsNull()) {
return;
}
set_declaration_type(old_declaration_type);
}
class EnumMapTraits {
public:
static bool ReportStats() { return false; }
static const char* Name() { return "EnumMapTraits"; }
static bool IsMatch(const Object& a, const Object& b) {
return a.raw() == b.raw();
}
static uword Hash(const Object& obj) {
ASSERT(obj.IsString());
return String::Cast(obj).Hash();
}
};
// Given an old enum class, add become mappings from old values to new values.
// Some notes about how we reload enums below:
//
// When an enum is reloaded the following three things can happen, possibly
// simultaneously.
//
// 1) A new enum value is added.
// This case is handled automatically.
// 2) Enum values are reordered.
// We pair old and new enums and the old enums 'become' the new ones so
// the ordering is always correct (i.e. enum indices match slots in values
// array)
// 3) An existing enum value is removed.
// Each enum class has a canonical 'deleted' enum sentinel instance.
// When an enum value is deleted, we 'become' all references to the 'deleted'
// sentinel value. The index value is -1.
//
void Class::ReplaceEnum(const Class& old_enum) const {
// We only do this for finalized enum classes.
ASSERT(is_enum_class());
ASSERT(old_enum.is_enum_class());
ASSERT(is_finalized());
ASSERT(old_enum.is_finalized());
Thread* thread = Thread::Current();
Zone* zone = thread->zone();
IsolateReloadContext* reload_context = Isolate::Current()->reload_context();
ASSERT(reload_context != NULL);
Array& enum_fields = Array::Handle(zone);
Field& field = Field::Handle(zone);
String& enum_ident = String::Handle();
Instance& old_enum_value = Instance::Handle(zone);
Instance& enum_value = Instance::Handle(zone);
// The E.values array.
Instance& old_enum_values = Instance::Handle(zone);
// The E.values array.
Instance& enum_values = Instance::Handle(zone);
// The E._deleted_enum_sentinel instance.
Instance& old_deleted_enum_sentinel = Instance::Handle(zone);
// The E._deleted_enum_sentinel instance.
Instance& deleted_enum_sentinel = Instance::Handle(zone);
Array& enum_map_storage =
Array::Handle(zone, HashTables::New<UnorderedHashMap<EnumMapTraits> >(4));
ASSERT(!enum_map_storage.IsNull());
TIR_Print("Replacing enum `%s`\n", String::Handle(Name()).ToCString());
{
UnorderedHashMap<EnumMapTraits> enum_map(enum_map_storage.raw());
// Build a map of all enum name -> old enum instance.
enum_fields = old_enum.fields();
for (intptr_t i = 0; i < enum_fields.Length(); i++) {
field = Field::RawCast(enum_fields.At(i));
enum_ident = field.name();
if (!field.is_static()) {
// Enum instances are only held in static fields.
continue;
}
if (enum_ident.Equals(Symbols::Values())) {
old_enum_values = field.StaticValue();
// Non-enum instance.
continue;
}
if (enum_ident.Equals(Symbols::_DeletedEnumSentinel())) {
old_deleted_enum_sentinel = field.StaticValue();
// Non-enum instance.
continue;
}
old_enum_value = field.StaticValue();
ASSERT(!old_enum_value.IsNull());
VTIR_Print("Element %s being added to mapping\n", enum_ident.ToCString());
bool update = enum_map.UpdateOrInsert(enum_ident, old_enum_value);
VTIR_Print("Element %s added to mapping\n", enum_ident.ToCString());
ASSERT(!update);
}
// The storage given to the map may have been reallocated, remember the new
// address.
enum_map_storage = enum_map.Release().raw();
}
bool enums_deleted = false;
{
UnorderedHashMap<EnumMapTraits> enum_map(enum_map_storage.raw());
// Add a become mapping from the old instances to the new instances.
enum_fields = fields();
for (intptr_t i = 0; i < enum_fields.Length(); i++) {
field = Field::RawCast(enum_fields.At(i));
enum_ident = field.name();
if (!field.is_static()) {
// Enum instances are only held in static fields.
continue;
}
if (enum_ident.Equals(Symbols::Values())) {
enum_values = field.StaticValue();
// Non-enum instance.
continue;
}
if (enum_ident.Equals(Symbols::_DeletedEnumSentinel())) {
deleted_enum_sentinel = field.StaticValue();
// Non-enum instance.
continue;
}
enum_value = field.StaticValue();
ASSERT(!enum_value.IsNull());
old_enum_value ^= enum_map.GetOrNull(enum_ident);
if (old_enum_value.IsNull()) {
VTIR_Print("New element %s was not found in mapping\n",
enum_ident.ToCString());
} else {
VTIR_Print("Adding element `%s` to become mapping\n",
enum_ident.ToCString());
bool removed = enum_map.Remove(enum_ident);
ASSERT(removed);
reload_context->AddEnumBecomeMapping(old_enum_value, enum_value);
}
}
enums_deleted = enum_map.NumOccupied() > 0;
// The storage given to the map may have been reallocated, remember the new
// address.
enum_map_storage = enum_map.Release().raw();
}
// Map the old E.values array to the new E.values array.
ASSERT(!old_enum_values.IsNull());
ASSERT(!enum_values.IsNull());
reload_context->AddEnumBecomeMapping(old_enum_values, enum_values);
// Map the old E._deleted_enum_sentinel to the new E._deleted_enum_sentinel.
ASSERT(!old_deleted_enum_sentinel.IsNull());
ASSERT(!deleted_enum_sentinel.IsNull());
reload_context->AddEnumBecomeMapping(old_deleted_enum_sentinel,
deleted_enum_sentinel);
if (enums_deleted) {
// Map all deleted enums to the deleted enum sentinel value.
// TODO(johnmccutchan): Add this to the reload 'notices' list.
VTIR_Print(
"The following enum values were deleted from %s and will become the "
"deleted enum sentinel:\n",
old_enum.ToCString());
UnorderedHashMap<EnumMapTraits> enum_map(enum_map_storage.raw());
UnorderedHashMap<EnumMapTraits>::Iterator it(&enum_map);
while (it.MoveNext()) {
const intptr_t entry = it.Current();
enum_ident = String::RawCast(enum_map.GetKey(entry));
ASSERT(!enum_ident.IsNull());
old_enum_value ^= enum_map.GetOrNull(enum_ident);
VTIR_Print("Element `%s` was deleted\n", enum_ident.ToCString());
reload_context->AddEnumBecomeMapping(old_enum_value,
deleted_enum_sentinel);
}
enum_map.Release();
}
}
void Class::PatchFieldsAndFunctions() const {
// Move all old functions and fields to a patch class so that they
// still refer to their original script.
const PatchClass& patch =
PatchClass::Handle(PatchClass::New(*this, Script::Handle(script())));
ASSERT(!patch.IsNull());
const Library& lib = Library::Handle(library());
patch.set_library_kernel_data(ExternalTypedData::Handle(lib.kernel_data()));
patch.set_library_kernel_offset(lib.kernel_offset());
const Array& funcs = Array::Handle(functions());
Function& func = Function::Handle();
Object& owner = Object::Handle();
for (intptr_t i = 0; i < funcs.Length(); i++) {
func = Function::RawCast(funcs.At(i));
if ((func.token_pos() == TokenPosition::kMinSource) ||
func.IsClosureFunction()) {
// Eval functions do not need to have their script updated.
//
// Closure functions refer to the parent's script which we can
// rely on being updated for us, if necessary.
continue;
}
// If the source for this function is already patched, leave it alone.
owner = func.RawOwner();
ASSERT(!owner.IsNull());
if (!owner.IsPatchClass()) {
ASSERT(owner.raw() == this->raw());
func.set_owner(patch);
}
}
const Array& field_list = Array::Handle(fields());
Field& field = Field::Handle();
for (intptr_t i = 0; i < field_list.Length(); i++) {
field = Field::RawCast(field_list.At(i));
owner = field.RawOwner();
ASSERT(!owner.IsNull());
if (!owner.IsPatchClass()) {
ASSERT(owner.raw() == this->raw());
field.set_owner(patch);
}
field.ForceDynamicGuardedCidAndLength();
}
}
void Class::MigrateImplicitStaticClosures(IsolateReloadContext* irc,
const Class& new_cls) const {
const Array& funcs = Array::Handle(functions());
Function& old_func = Function::Handle();
String& selector = String::Handle();
Function& new_func = Function::Handle();
Instance& old_closure = Instance::Handle();
Instance& new_closure = Instance::Handle();
for (intptr_t i = 0; i < funcs.Length(); i++) {
old_func ^= funcs.At(i);
if (old_func.is_static() && old_func.HasImplicitClosureFunction()) {
selector = old_func.name();
new_func = new_cls.LookupFunction(selector);
if (!new_func.IsNull() && new_func.is_static()) {
old_func = old_func.ImplicitClosureFunction();
old_closure = old_func.ImplicitStaticClosure();
new_func = new_func.ImplicitClosureFunction();
new_closure = new_func.ImplicitStaticClosure();
if (old_closure.IsCanonical()) {
new_closure.SetCanonical();
}
irc->AddBecomeMapping(old_closure, new_closure);
}
}
}
}
class EnumClassConflict : public ClassReasonForCancelling {
public:
EnumClassConflict(Zone* zone, const Class& from, const Class& to)
: ClassReasonForCancelling(zone, from, to) {}
RawString* ToString() {
return String::NewFormatted(
from_.is_enum_class()
? "Enum class cannot be redefined to be a non-enum class: %s"
: "Class cannot be redefined to be a enum class: %s",
from_.ToCString());
}
};
class TypedefClassConflict : public ClassReasonForCancelling {
public:
TypedefClassConflict(Zone* zone, const Class& from, const Class& to)
: ClassReasonForCancelling(zone, from, to) {}
RawString* ToString() {
return String::NewFormatted(
from_.IsTypedefClass()
? "Typedef class cannot be redefined to be a non-typedef class: %s"
: "Class cannot be redefined to be a typedef class: %s",
from_.ToCString());
}
};
class EnsureFinalizedError : public ClassReasonForCancelling {
public:
EnsureFinalizedError(Zone* zone,
const Class& from,
const Class& to,
const Error& error)
: ClassReasonForCancelling(zone, from, to), error_(error) {}
private:
const Error& error_;
RawError* ToError() { return error_.raw(); }
RawString* ToString() { return String::New(error_.ToErrorCString()); }
};
class NativeFieldsConflict : public ClassReasonForCancelling {
public:
NativeFieldsConflict(Zone* zone, const Class& from, const Class& to)
: ClassReasonForCancelling(zone, from, to) {}
private:
RawString* ToString() {
return String::NewFormatted("Number of native fields changed in %s",
from_.ToCString());
}
};
class TypeParametersChanged : public ClassReasonForCancelling {
public:
TypeParametersChanged(Zone* zone, const Class& from, const Class& to)
: ClassReasonForCancelling(zone, from, to) {}
RawString* ToString() {
return String::NewFormatted(
"Limitation: type parameters have changed for %s", from_.ToCString());
}
void AppendTo(JSONArray* array) {
JSONObject jsobj(array);
jsobj.AddProperty("type", "ReasonForCancellingReload");
jsobj.AddProperty("kind", "TypeParametersChanged");
jsobj.AddProperty("class", to_);
jsobj.AddProperty("message",
"Limitation: changing type parameters "
"does not work with hot reload.");
}
};
class PreFinalizedConflict : public ClassReasonForCancelling {
public:
PreFinalizedConflict(Zone* zone, const Class& from, const Class& to)
: ClassReasonForCancelling(zone, from, to) {}
private:
RawString* ToString() {
return String::NewFormatted(
"Original class ('%s') is prefinalized and replacement class "
"('%s') is not ",
from_.ToCString(), to_.ToCString());
}
};
class InstanceSizeConflict : public ClassReasonForCancelling {
public:
InstanceSizeConflict(Zone* zone, const Class& from, const Class& to)
: ClassReasonForCancelling(zone, from, to) {}
private:
RawString* ToString() {
return String::NewFormatted("Instance size mismatch between '%s' (%" Pd
") and replacement "
"'%s' ( %" Pd ")",
from_.ToCString(), from_.instance_size(),
to_.ToCString(), to_.instance_size());
}
};
class UnimplementedDeferredLibrary : public ReasonForCancelling {
public:
UnimplementedDeferredLibrary(Zone* zone,
const Library& from,
const Library& to,
const String& name)
: ReasonForCancelling(zone), from_(from), to_(to), name_(name) {}
private:
const Library& from_;
const Library& to_;
const String& name_;
RawString* ToString() {
const String& lib_url = String::Handle(to_.url());
from_.ToCString();
return String::NewFormatted(
"Reloading support for deferred loading has not yet been implemented:"
" library '%s' has deferred import '%s'",
lib_url.ToCString(), name_.ToCString());
}
};
// This is executed before iterating over the instances.
void Class::CheckReload(const Class& replacement,
IsolateReloadContext* context) const {
ASSERT(IsolateReloadContext::IsSameClass(*this, replacement));
// Class cannot change enum property.
if (is_enum_class() != replacement.is_enum_class()) {
context->AddReasonForCancelling(new (context->zone()) EnumClassConflict(
context->zone(), *this, replacement));
return;
}
// Class cannot change typedef property.
if (IsTypedefClass() != replacement.IsTypedefClass()) {
context->AddReasonForCancelling(new (context->zone()) TypedefClassConflict(
context->zone(), *this, replacement));
return;
}
if (is_finalized()) {
// Ensure the replacement class is also finalized.
const Error& error =
Error::Handle(replacement.EnsureIsFinalized(Thread::Current()));
if (!error.IsNull()) {
context->AddReasonForCancelling(
new (context->zone())
EnsureFinalizedError(context->zone(), *this, replacement, error));
return; // No reason to check other properties.
}
ASSERT(replacement.is_finalized());
TIR_Print("Finalized replacement class for %s\n", ToCString());
}
// Native field count cannot change.
if (num_native_fields() != replacement.num_native_fields()) {
context->AddReasonForCancelling(new (context->zone()) NativeFieldsConflict(
context->zone(), *this, replacement));
return;
}
// Just checking.
ASSERT(is_enum_class() == replacement.is_enum_class());
ASSERT(num_native_fields() == replacement.num_native_fields());
if (is_finalized()) {
if (!CanReloadFinalized(replacement, context)) return;
}
if (is_prefinalized()) {
if (!CanReloadPreFinalized(replacement, context)) return;
}
TIR_Print("Class `%s` can be reloaded (%" Pd " and %" Pd ")\n", ToCString(),
id(), replacement.id());
}
bool Class::RequiresInstanceMorphing(const Class& replacement) const {
// Get the field maps for both classes. These field maps walk the class
// hierarchy.
const Array& fields =
Array::Handle(OffsetToFieldMap(true /* original classes */));
const Array& replacement_fields =
Array::Handle(replacement.OffsetToFieldMap());
// Check that the size of the instance is the same.
if (fields.Length() != replacement_fields.Length()) return true;
// Check that we have the same next field offset. This check is not
// redundant with the one above because the instance OffsetToFieldMap
// array length is based on the instance size (which may be aligned up).
if (next_field_offset() != replacement.next_field_offset()) return true;
// Verify that field names / offsets match across the entire hierarchy.
Field& field = Field::Handle();
String& field_name = String::Handle();
Field& replacement_field = Field::Handle();
String& replacement_field_name = String::Handle();
for (intptr_t i = 0; i < fields.Length(); i++) {
if (fields.At(i) == Field::null()) {
ASSERT(replacement_fields.At(i) == Field::null());
continue;
}
field = Field::RawCast(fields.At(i));
replacement_field = Field::RawCast(replacement_fields.At(i));
field_name = field.name();
replacement_field_name = replacement_field.name();
if (!field_name.Equals(replacement_field_name)) return true;
}
return false;
}
bool Class::CanReloadFinalized(const Class& replacement,
IsolateReloadContext* context) const {
// Make sure the declaration types argument count matches for the two classes.
// ex. class A<int,B> {} cannot be replace with class A<B> {}.
if (NumTypeArguments() != replacement.NumTypeArguments()) {
context->AddReasonForCancelling(new (context->zone()) TypeParametersChanged(
context->zone(), *this, replacement));
return false;
}
if (RequiresInstanceMorphing(replacement)) {
context->AddInstanceMorpher(new (context->zone()) InstanceMorpher(
context->zone(), *this, replacement));
}
return true;
}
bool Class::CanReloadPreFinalized(const Class& replacement,
IsolateReloadContext* context) const {
// The replacement class must also prefinalized.
if (!replacement.is_prefinalized()) {
context->AddReasonForCancelling(new (context->zone()) PreFinalizedConflict(
context->zone(), *this, replacement));
return false;
}
// Check the instance sizes are equal.
if (instance_size() != replacement.instance_size()) {
context->AddReasonForCancelling(new (context->zone()) InstanceSizeConflict(
context->zone(), *this, replacement));
return false;
}
return true;
}
void Library::CheckReload(const Library& replacement,
IsolateReloadContext* context) const {
// TODO(26878): If the replacement library uses deferred loading,
// reject it. We do not yet support reloading deferred libraries.
LibraryPrefix& prefix = LibraryPrefix::Handle();
LibraryPrefixIterator it(replacement);
while (it.HasNext()) {
prefix = it.GetNext();
if (prefix.is_deferred_load()) {
const String& prefix_name = String::Handle(prefix.name());
context->AddReasonForCancelling(
new (context->zone()) UnimplementedDeferredLibrary(
context->zone(), *this, replacement, prefix_name));
return;
}
}
}
static const Function* static_call_target = NULL;
void ICData::Reset(Zone* zone) const {
RebindRule rule = rebind_rule();
if (rule == kInstance) {
const intptr_t num_args = NumArgsTested();
const bool tracking_exactness = IsTrackingExactness();
const intptr_t len = Length();
// We need at least one non-sentinel entry to require a check
// for the smi fast path case.
if (num_args == 2 && len >= 2) {
if (IsImmutable()) {
return;
}
Zone* zone = Thread::Current()->zone();
const String& name = String::Handle(target_name());
const Class& smi_class = Class::Handle(Smi::Class());
const Function& smi_op_target = Function::Handle(
Resolver::ResolveDynamicAnyArgs(zone, smi_class, name));
GrowableArray<intptr_t> class_ids(2);
Function& target = Function::Handle();
GetCheckAt(0, &class_ids, &target);
if ((target.raw() == smi_op_target.raw()) && (class_ids[0] == kSmiCid) &&
(class_ids[1] == kSmiCid)) {
// The smi fast path case, preserve the initial entry but reset the
// count.
ClearCountAt(0);
WriteSentinelAt(1);
const Array& array = Array::Handle(ic_data());
array.Truncate(2 * TestEntryLength());
return;
}
// Fall back to the normal behavior with cached empty ICData arrays.
}
const Array& data_array = Array::Handle(
zone, CachedEmptyICDataArray(num_args, tracking_exactness));
set_ic_data_array(data_array);
return;
} else if (rule == kNoRebind || rule == kNSMDispatch) {
// TODO(30877) we should account for addition/removal of NSM.
// Don't rebind dispatchers.
return;
} else if (rule == kStatic || rule == kSuper) {
const Function& old_target = Function::Handle(zone, GetTargetAt(0));
if (old_target.IsNull()) {
FATAL("old_target is NULL.\n");
}
static_call_target = &old_target;
const String& selector = String::Handle(zone, old_target.name());
Function& new_target = Function::Handle(zone);
if (rule == kStatic) {
ASSERT(old_target.is_static() ||
old_target.kind() == RawFunction::kConstructor);
// This can be incorrect if the call site was an unqualified invocation.
const Class& cls = Class::Handle(zone, old_target.Owner());
new_target = cls.LookupFunction(selector);
if (new_target.kind() != old_target.kind()) {
new_target = Function::null();
}
} else {
// Super call.
Function& caller = Function::Handle(zone);
caller ^= Owner();
ASSERT(!caller.is_static());
Class& cls = Class::Handle(zone, caller.Owner());
cls = cls.SuperClass();
while (!cls.IsNull()) {
// TODO(rmacnak): Should use Resolver::ResolveDynamicAnyArgs to handle
// method-extractors and call-through-getters, but we're in a no
// safepoint scope here.
new_target = cls.LookupDynamicFunction(selector);
if (!new_target.IsNull()) {
break;
}
cls = cls.SuperClass();
}
}
const Array& args_desc_array = Array::Handle(zone, arguments_descriptor());
ArgumentsDescriptor args_desc(args_desc_array);
if (new_target.IsNull() || !new_target.AreValidArguments(args_desc, NULL)) {
// TODO(rmacnak): Patch to a NSME stub.
VTIR_Print("Cannot rebind static call to %s from %s\n",
old_target.ToCString(),
Object::Handle(zone, Owner()).ToCString());
return;
}
ClearAndSetStaticTarget(new_target);
} else {
FATAL("Unexpected rebind rule.");
}
}
#endif // !defined(PRODUCT) && !defined(DART_PRECOMPILED_RUNTIME)
} // namespace dart.