runtime/vm/zone_test.cc - sdk.git - Git at Google

 // Copyright (c) 2012, 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 "platform/assert.h"
 #include "vm/dart.h"
 #include "vm/isolate.h"
 #include "vm/unit_test.h"
 #include "vm/zone.h"

 namespace dart {

 DECLARE_DEBUG_FLAG(bool, trace_zones);

 UNIT_TEST_CASE(AllocateZone) {
 #if defined(DEBUG)
   FLAG_trace_zones = true;
 #endif
   Isolate* isolate = Isolate::Init(NULL);
   EXPECT(Isolate::Current() == isolate);
   EXPECT(isolate->current_zone() == NULL);
   {
     StackZone stack_zone(isolate);
     EXPECT(isolate->current_zone() != NULL);
     Zone* zone = stack_zone.GetZone();
     intptr_t allocated_size = 0;

     // The loop is to make sure we overflow one segment and go on
     // to the next segment.
     for (int i = 0; i < 1000; i++) {
       uword first = zone->AllocUnsafe(2 * kWordSize);
       uword second = zone->AllocUnsafe(3 * kWordSize);
       EXPECT(first != second);
       allocated_size = ((2 + 3) * kWordSize);
     }
     EXPECT_LE(allocated_size, zone->SizeInBytes());

     // Test for allocation of large segments.
     const uword kLargeSize = 1 * MB;
     const uword kSegmentSize = 64 * KB;
     ASSERT(kLargeSize > kSegmentSize);
     for (int i = 0; i < 10; i++) {
       EXPECT(zone->AllocUnsafe(kLargeSize) != 0);
       allocated_size += kLargeSize;
     }
     EXPECT_LE(allocated_size, zone->SizeInBytes());

     // Test corner cases of kSegmentSize.
     uint8_t* buffer = NULL;
     buffer = reinterpret_cast<uint8_t*>(
         zone->AllocUnsafe(kSegmentSize - kWordSize));
     EXPECT(buffer != NULL);
     buffer[(kSegmentSize - kWordSize) - 1] = 0;
     allocated_size += (kSegmentSize - kWordSize);
     EXPECT_LE(allocated_size, zone->SizeInBytes());

     buffer = reinterpret_cast<uint8_t*>(
         zone->AllocUnsafe(kSegmentSize - (2 * kWordSize)));
     EXPECT(buffer != NULL);
     buffer[(kSegmentSize - (2 * kWordSize)) - 1] = 0;
     allocated_size += (kSegmentSize - (2 * kWordSize));
     EXPECT_LE(allocated_size, zone->SizeInBytes());

     buffer = reinterpret_cast<uint8_t*>(
         zone->AllocUnsafe(kSegmentSize + kWordSize));
     EXPECT(buffer != NULL);
     buffer[(kSegmentSize + kWordSize) - 1] = 0;
     allocated_size += (kSegmentSize + kWordSize);
     EXPECT_LE(allocated_size, zone->SizeInBytes());
   }
   EXPECT(isolate->current_zone() == NULL);
   isolate->Shutdown();
   delete isolate;
 }


 UNIT_TEST_CASE(AllocGeneric_Success) {
 #if defined(DEBUG)
   FLAG_trace_zones = true;
 #endif
   Isolate* isolate = Isolate::Init(NULL);
   EXPECT(Isolate::Current() == isolate);
   EXPECT(isolate->current_zone() == NULL);
   {
     StackZone zone(isolate);
     EXPECT(isolate->current_zone() != NULL);
     intptr_t allocated_size = 0;

     const intptr_t kNumElements = 1000;
     zone.GetZone()->Alloc<uint32_t>(kNumElements);
     allocated_size += sizeof(uint32_t) * kNumElements;
     EXPECT_LE(allocated_size, zone.SizeInBytes());
   }
   EXPECT(isolate->current_zone() == NULL);
   isolate->Shutdown();
   delete isolate;
 }


 // This test is expected to crash.
 UNIT_TEST_CASE(AllocGeneric_Overflow) {
 #if defined(DEBUG)
   FLAG_trace_zones = true;
 #endif
   Isolate* isolate = Isolate::Init(NULL);
   EXPECT(Isolate::Current() == isolate);
   EXPECT(isolate->current_zone() == NULL);
   {
     StackZone zone(isolate);
     EXPECT(isolate->current_zone() != NULL);

     const intptr_t kNumElements = (kIntptrMax / sizeof(uint32_t)) + 1;
     zone.GetZone()->Alloc<uint32_t>(kNumElements);
   }
   isolate->Shutdown();
   delete isolate;
 }


 UNIT_TEST_CASE(ZoneAllocated) {
 #if defined(DEBUG)
   FLAG_trace_zones = true;
 #endif
   Isolate* isolate = Isolate::Init(NULL);
   EXPECT(Isolate::Current() == isolate);
   EXPECT(isolate->current_zone() == NULL);
   static int marker;

   class SimpleZoneObject : public ZoneAllocated {
    public:
     SimpleZoneObject() : slot(marker++) { }
     virtual int GetSlot() { return slot; }
     int slot;
   };

   // Reset the marker.
   marker = 0;

   // Create a few zone allocated objects.
   {
     StackZone zone(isolate);
     EXPECT_EQ(0, zone.SizeInBytes());
     SimpleZoneObject* first = new SimpleZoneObject();
     EXPECT(first != NULL);
     SimpleZoneObject* second = new SimpleZoneObject();
     EXPECT(second != NULL);
     EXPECT(first != second);
     intptr_t expected_size = (2 * sizeof(SimpleZoneObject));
     EXPECT_LE(expected_size, zone.SizeInBytes());

     // Make sure the constructors were invoked.
     EXPECT_EQ(0, first->slot);
     EXPECT_EQ(1, second->slot);

     // Make sure we can write to the members of the zone objects.
     first->slot = 42;
     second->slot = 87;
     EXPECT_EQ(42, first->slot);
     EXPECT_EQ(87, second->slot);
   }
   EXPECT(isolate->current_zone() == NULL);
   isolate->Shutdown();
   delete isolate;
 }


 TEST_CASE(PrintToString) {
   StackZone zone(Isolate::Current());
   const char* result = zone.GetZone()->PrintToString("Hello %s!", "World");
   EXPECT_STREQ("Hello World!", result);
 }

 }  // namespace dart
	// Copyright (c) 2012, 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 "platform/assert.h"
	#include "vm/dart.h"
	#include "vm/isolate.h"
	#include "vm/unit_test.h"
	#include "vm/zone.h"

	namespace dart {

	DECLARE_DEBUG_FLAG(bool, trace_zones);

	UNIT_TEST_CASE(AllocateZone) {
	#if defined(DEBUG)
	FLAG_trace_zones = true;
	#endif
	Isolate* isolate = Isolate::Init(NULL);
	EXPECT(Isolate::Current() == isolate);
	EXPECT(isolate->current_zone() == NULL);
	{
	StackZone stack_zone(isolate);
	EXPECT(isolate->current_zone() != NULL);
	Zone* zone = stack_zone.GetZone();
	intptr_t allocated_size = 0;

	// The loop is to make sure we overflow one segment and go on
	// to the next segment.
	for (int i = 0; i < 1000; i++) {
	uword first = zone->AllocUnsafe(2 * kWordSize);
	uword second = zone->AllocUnsafe(3 * kWordSize);
	EXPECT(first != second);
	allocated_size = ((2 + 3) * kWordSize);
	}
	EXPECT_LE(allocated_size, zone->SizeInBytes());

	// Test for allocation of large segments.
	const uword kLargeSize = 1 * MB;
	const uword kSegmentSize = 64 * KB;
	ASSERT(kLargeSize > kSegmentSize);
	for (int i = 0; i < 10; i++) {
	EXPECT(zone->AllocUnsafe(kLargeSize) != 0);
	allocated_size += kLargeSize;
	}
	EXPECT_LE(allocated_size, zone->SizeInBytes());

	// Test corner cases of kSegmentSize.
	uint8_t* buffer = NULL;
	buffer = reinterpret_cast<uint8_t*>(
	zone->AllocUnsafe(kSegmentSize - kWordSize));
	EXPECT(buffer != NULL);
	buffer[(kSegmentSize - kWordSize) - 1] = 0;
	allocated_size += (kSegmentSize - kWordSize);
	EXPECT_LE(allocated_size, zone->SizeInBytes());

	buffer = reinterpret_cast<uint8_t*>(
	zone->AllocUnsafe(kSegmentSize - (2 * kWordSize)));
	EXPECT(buffer != NULL);
	buffer[(kSegmentSize - (2 * kWordSize)) - 1] = 0;
	allocated_size += (kSegmentSize - (2 * kWordSize));
	EXPECT_LE(allocated_size, zone->SizeInBytes());

	buffer = reinterpret_cast<uint8_t*>(
	zone->AllocUnsafe(kSegmentSize + kWordSize));
	EXPECT(buffer != NULL);
	buffer[(kSegmentSize + kWordSize) - 1] = 0;
	allocated_size += (kSegmentSize + kWordSize);
	EXPECT_LE(allocated_size, zone->SizeInBytes());
	}
	EXPECT(isolate->current_zone() == NULL);
	isolate->Shutdown();
	delete isolate;
	}


	UNIT_TEST_CASE(AllocGeneric_Success) {
	#if defined(DEBUG)
	FLAG_trace_zones = true;
	#endif
	Isolate* isolate = Isolate::Init(NULL);
	EXPECT(Isolate::Current() == isolate);
	EXPECT(isolate->current_zone() == NULL);
	{
	StackZone zone(isolate);
	EXPECT(isolate->current_zone() != NULL);
	intptr_t allocated_size = 0;

	const intptr_t kNumElements = 1000;
	zone.GetZone()->Alloc<uint32_t>(kNumElements);
	allocated_size += sizeof(uint32_t) * kNumElements;
	EXPECT_LE(allocated_size, zone.SizeInBytes());
	}
	EXPECT(isolate->current_zone() == NULL);
	isolate->Shutdown();
	delete isolate;
	}


	// This test is expected to crash.
	UNIT_TEST_CASE(AllocGeneric_Overflow) {
	#if defined(DEBUG)
	FLAG_trace_zones = true;
	#endif
	Isolate* isolate = Isolate::Init(NULL);
	EXPECT(Isolate::Current() == isolate);
	EXPECT(isolate->current_zone() == NULL);
	{
	StackZone zone(isolate);
	EXPECT(isolate->current_zone() != NULL);

	const intptr_t kNumElements = (kIntptrMax / sizeof(uint32_t)) + 1;
	zone.GetZone()->Alloc<uint32_t>(kNumElements);
	}
	isolate->Shutdown();
	delete isolate;
	}


	UNIT_TEST_CASE(ZoneAllocated) {
	#if defined(DEBUG)
	FLAG_trace_zones = true;
	#endif
	Isolate* isolate = Isolate::Init(NULL);
	EXPECT(Isolate::Current() == isolate);
	EXPECT(isolate->current_zone() == NULL);
	static int marker;

	class SimpleZoneObject : public ZoneAllocated {
	public:
	SimpleZoneObject() : slot(marker++) { }
	virtual int GetSlot() { return slot; }
	int slot;
	};

	// Reset the marker.
	marker = 0;

	// Create a few zone allocated objects.
	{
	StackZone zone(isolate);
	EXPECT_EQ(0, zone.SizeInBytes());
	SimpleZoneObject* first = new SimpleZoneObject();
	EXPECT(first != NULL);
	SimpleZoneObject* second = new SimpleZoneObject();
	EXPECT(second != NULL);
	EXPECT(first != second);
	intptr_t expected_size = (2 * sizeof(SimpleZoneObject));
	EXPECT_LE(expected_size, zone.SizeInBytes());

	// Make sure the constructors were invoked.
	EXPECT_EQ(0, first->slot);
	EXPECT_EQ(1, second->slot);

	// Make sure we can write to the members of the zone objects.
	first->slot = 42;
	second->slot = 87;
	EXPECT_EQ(42, first->slot);
	EXPECT_EQ(87, second->slot);
	}
	EXPECT(isolate->current_zone() == NULL);
	isolate->Shutdown();
	delete isolate;
	}


	TEST_CASE(PrintToString) {
	StackZone zone(Isolate::Current());
	const char* result = zone.GetZone()->PrintToString("Hello %s!", "World");
	EXPECT_STREQ("Hello World!", result);
	}

	} // namespace dart