test/cctest/test-strings.cc - fp2-dev/platform/external/v8 - Gitiles

 // Copyright 2006-2008 the V8 project authors. All rights reserved.

 // Check that we can traverse very deep stacks of ConsStrings using
 // StringInputBuffer.  Check that Get(int) works on very deep stacks
 // of ConsStrings.  These operations may not be very fast, but they
 // should be possible without getting errors due to too deep recursion.

 #include <stdlib.h>

 #include "v8.h"

 #include "api.h"
 #include "factory.h"
 #include "cctest.h"
 #include "zone-inl.h"

 unsigned int seed = 123;

 static uint32_t gen() {
         uint64_t z;
         z = seed;
         z *= 279470273;
         z %= 4294967291U;
         seed = static_cast<unsigned int>(z);
         return static_cast<uint32_t>(seed >> 16);
 }


 using namespace v8::internal;

 static v8::Persistent<v8::Context> env;


 static void InitializeVM() {
   if (env.IsEmpty()) {
     v8::HandleScope scope;
     const char* extensions[] = { "v8/print" };
     v8::ExtensionConfiguration config(1, extensions);
     env = v8::Context::New(&config);
   }
   v8::HandleScope scope;
   env->Enter();
 }


 static const int NUMBER_OF_BUILDING_BLOCKS = 128;
 static const int DEEP_DEPTH = 8 * 1024;
 static const int SUPER_DEEP_DEPTH = 80 * 1024;


 class Resource: public v8::String::ExternalStringResource,
                 public ZoneObject {
  public:
   explicit Resource(Vector<const uc16> string): data_(string.start()) {
     length_ = string.length();
   }
   virtual const uint16_t* data() const { return data_; }
   virtual size_t length() const { return length_; }

  private:
   const uc16* data_;
   size_t length_;
 };


 static void InitializeBuildingBlocks(
     Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS]) {
   // A list of pointers that we don't have any interest in cleaning up.
   // If they are reachable from a root then leak detection won't complain.
   for (int i = 0; i < NUMBER_OF_BUILDING_BLOCKS; i++) {
     int len = gen() % 16;
     if (len > 14) {
       len += 1234;
     }
     switch (gen() % 4) {
       case 0: {
         uc16 buf[2000];
         for (int j = 0; j < len; j++) {
           buf[j] = gen() % 65536;
         }
         building_blocks[i] =
             Factory::NewStringFromTwoByte(Vector<const uc16>(buf, len));
         for (int j = 0; j < len; j++) {
           CHECK_EQ(buf[j], building_blocks[i]->Get(j));
         }
         break;
       }
       case 1: {
         char buf[2000];
         for (int j = 0; j < len; j++) {
           buf[j] = gen() % 128;
         }
         building_blocks[i] =
             Factory::NewStringFromAscii(Vector<const char>(buf, len));
         for (int j = 0; j < len; j++) {
           CHECK_EQ(buf[j], building_blocks[i]->Get(j));
         }
         break;
       }
       case 2: {
         uc16* buf = Zone::NewArray<uc16>(len);
         for (int j = 0; j < len; j++) {
           buf[j] = gen() % 65536;
         }
         Resource* resource = new Resource(Vector<const uc16>(buf, len));
         building_blocks[i] = Factory::NewExternalStringFromTwoByte(resource);
         for (int j = 0; j < len; j++) {
           CHECK_EQ(buf[j], building_blocks[i]->Get(j));
         }
         break;
       }
       case 3: {
         char* buf = NewArray<char>(len);
         for (int j = 0; j < len; j++) {
           buf[j] = gen() % 128;
         }
         building_blocks[i] =
             Factory::NewStringFromAscii(Vector<const char>(buf, len));
         for (int j = 0; j < len; j++) {
           CHECK_EQ(buf[j], building_blocks[i]->Get(j));
         }
         DeleteArray<char>(buf);
         break;
       }
     }
   }
 }


 static Handle<String> ConstructLeft(
     Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
     int depth) {
   Handle<String> answer = Factory::NewStringFromAscii(CStrVector(""));
   for (int i = 0; i < depth; i++) {
     answer = Factory::NewConsString(
         answer,
         building_blocks[i % NUMBER_OF_BUILDING_BLOCKS]);
   }
   return answer;
 }


 static Handle<String> ConstructRight(
     Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
     int depth) {
   Handle<String> answer = Factory::NewStringFromAscii(CStrVector(""));
   for (int i = depth - 1; i >= 0; i--) {
     answer = Factory::NewConsString(
         building_blocks[i % NUMBER_OF_BUILDING_BLOCKS],
         answer);
   }
   return answer;
 }


 static Handle<String> ConstructBalancedHelper(
     Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
     int from,
     int to) {
   CHECK(to > from);
   if (to - from == 1) {
     return building_blocks[from % NUMBER_OF_BUILDING_BLOCKS];
   }
   if (to - from == 2) {
     return Factory::NewConsString(
         building_blocks[from % NUMBER_OF_BUILDING_BLOCKS],
         building_blocks[(from+1) % NUMBER_OF_BUILDING_BLOCKS]);
   }
   Handle<String> part1 =
     ConstructBalancedHelper(building_blocks, from, from + ((to - from) / 2));
   Handle<String> part2 =
     ConstructBalancedHelper(building_blocks, from + ((to - from) / 2), to);
   return Factory::NewConsString(part1, part2);
 }


 static Handle<String> ConstructBalanced(
     Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS]) {
   return ConstructBalancedHelper(building_blocks, 0, DEEP_DEPTH);
 }


 static StringInputBuffer buffer;


 static void Traverse(Handle<String> s1, Handle<String> s2) {
   int i = 0;
   buffer.Reset(*s1);
   StringInputBuffer buffer2(*s2);
   while (buffer.has_more()) {
     CHECK(buffer2.has_more());
     uint16_t c = buffer.GetNext();
     CHECK_EQ(c, buffer2.GetNext());
     i++;
   }
   CHECK_EQ(s1->length(), i);
   CHECK_EQ(s2->length(), i);
 }


 static void TraverseFirst(Handle<String> s1, Handle<String> s2, int chars) {
   int i = 0;
   buffer.Reset(*s1);
   StringInputBuffer buffer2(*s2);
   while (buffer.has_more() && i < chars) {
     CHECK(buffer2.has_more());
     uint16_t c = buffer.GetNext();
     CHECK_EQ(c, buffer2.GetNext());
     i++;
   }
   s1->Get(s1->length() - 1);
   s2->Get(s2->length() - 1);
 }


 TEST(Traverse) {
   printf("TestTraverse\n");
   InitializeVM();
   v8::HandleScope scope;
   Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS];
   ZoneScope zone(DELETE_ON_EXIT);
   InitializeBuildingBlocks(building_blocks);
   Handle<String> flat = ConstructBalanced(building_blocks);
   FlattenString(flat);
   Handle<String> left_asymmetric = ConstructLeft(building_blocks, DEEP_DEPTH);
   Handle<String> right_asymmetric = ConstructRight(building_blocks, DEEP_DEPTH);
   Handle<String> symmetric = ConstructBalanced(building_blocks);
   printf("1\n");
   Traverse(flat, symmetric);
   printf("2\n");
   Traverse(flat, left_asymmetric);
   printf("3\n");
   Traverse(flat, right_asymmetric);
   printf("4\n");
   Handle<String> left_deep_asymmetric =
       ConstructLeft(building_blocks, SUPER_DEEP_DEPTH);
   Handle<String> right_deep_asymmetric =
       ConstructRight(building_blocks, SUPER_DEEP_DEPTH);
   printf("5\n");
   TraverseFirst(left_asymmetric, left_deep_asymmetric, 1050);
   printf("6\n");
   TraverseFirst(left_asymmetric, right_deep_asymmetric, 65536);
   printf("7\n");
   Handle<String> right_deep_slice =
       Factory::NewStringSlice(left_deep_asymmetric,
                               left_deep_asymmetric->length() - 1050,
                               left_deep_asymmetric->length() - 50);
   Handle<String> left_deep_slice =
       Factory::NewStringSlice(right_deep_asymmetric,
                               right_deep_asymmetric->length() - 1050,
                               right_deep_asymmetric->length() - 50);
   printf("8\n");
   Traverse(right_deep_slice, left_deep_slice);
   printf("9\n");
   FlattenString(left_asymmetric);
   printf("10\n");
   Traverse(flat, left_asymmetric);
   printf("11\n");
   FlattenString(right_asymmetric);
   printf("12\n");
   Traverse(flat, right_asymmetric);
   printf("14\n");
   FlattenString(symmetric);
   printf("15\n");
   Traverse(flat, symmetric);
   printf("16\n");
   FlattenString(left_deep_asymmetric);
   printf("18\n");
 }


 static Handle<String> SliceOf(Handle<String> underlying) {
   int start = gen() % underlying->length();
   int end = start + gen() % (underlying->length() - start);
   return Factory::NewStringSlice(underlying,
                                  start,
                                  end);
 }


 static Handle<String> ConstructSliceTree(
     Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
     int from,
     int to) {
   CHECK(to > from);
   if (to - from <= 1)
     return SliceOf(building_blocks[from % NUMBER_OF_BUILDING_BLOCKS]);
   if (to - from == 2) {
     Handle<String> lhs = building_blocks[from % NUMBER_OF_BUILDING_BLOCKS];
     if (gen() % 2 == 0)
       lhs = SliceOf(lhs);
     Handle<String> rhs = building_blocks[(from+1) % NUMBER_OF_BUILDING_BLOCKS];
     if (gen() % 2 == 0)
       rhs = SliceOf(rhs);
     return Factory::NewConsString(lhs, rhs);
   }
   Handle<String> part1 =
     ConstructBalancedHelper(building_blocks, from, from + ((to - from) / 2));
   Handle<String> part2 =
     ConstructBalancedHelper(building_blocks, from + ((to - from) / 2), to);
   Handle<String> branch = Factory::NewConsString(part1, part2);
   if (gen() % 2 == 0)
     return branch;
   return(SliceOf(branch));
 }


 TEST(Slice) {
   printf("TestSlice\n");
   InitializeVM();
   v8::HandleScope scope;
   Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS];
   ZoneScope zone(DELETE_ON_EXIT);
   InitializeBuildingBlocks(building_blocks);

   seed = 42;
   Handle<String> slice_tree =
       ConstructSliceTree(building_blocks, 0, DEEP_DEPTH);
   seed = 42;
   Handle<String> flat_slice_tree =
       ConstructSliceTree(building_blocks, 0, DEEP_DEPTH);
   FlattenString(flat_slice_tree);
   Traverse(flat_slice_tree, slice_tree);
 }

 static const int DEEP_ASCII_DEPTH = 100000;


 TEST(DeepAscii) {
   printf("TestDeepAscii\n");
   InitializeVM();
   v8::HandleScope scope;

   char* foo = NewArray<char>(DEEP_ASCII_DEPTH);
   for (int i = 0; i < DEEP_ASCII_DEPTH; i++) {
     foo[i] = "foo "[i % 4];
   }
   Handle<String> string =
       Factory::NewStringFromAscii(Vector<const char>(foo, DEEP_ASCII_DEPTH));
   Handle<String> foo_string = Factory::NewStringFromAscii(CStrVector("foo"));
   for (int i = 0; i < DEEP_ASCII_DEPTH; i += 10) {
     string = Factory::NewConsString(string, foo_string);
   }
   Handle<String> flat_string = Factory::NewConsString(string, foo_string);
   FlattenString(flat_string);

   for (int i = 0; i < 500; i++) {
     TraverseFirst(flat_string, string, DEEP_ASCII_DEPTH);
   }
   DeleteArray<char>(foo);
 }


 TEST(Utf8Conversion) {
   // Smoke test for converting strings to utf-8.
   InitializeVM();
   v8::HandleScope handle_scope;
   // A simple ascii string
   const char* ascii_string = "abcdef12345";
   int len = v8::String::New(ascii_string, strlen(ascii_string))->Utf8Length();
   CHECK_EQ(strlen(ascii_string), len);
   // A mixed ascii and non-ascii string
   // U+02E4 -> CB A4
   // U+0064 -> 64
   // U+12E4 -> E1 8B A4
   // U+0030 -> 30
   // U+3045 -> E3 81 85
   const uint16_t mixed_string[] = {0x02E4, 0x0064, 0x12E4, 0x0030, 0x3045};
   // The characters we expect to be output
   const unsigned char as_utf8[11] = {0xCB, 0xA4, 0x64, 0xE1, 0x8B, 0xA4, 0x30,
       0xE3, 0x81, 0x85, 0x00};
   // The number of bytes expected to be written for each length
   const int lengths[12] = {0, 0, 2, 3, 3, 3, 6, 7, 7, 7, 10, 11};
   v8::Handle<v8::String> mixed = v8::String::New(mixed_string, 5);
   CHECK_EQ(10, mixed->Utf8Length());
   // Try encoding the string with all capacities
   char buffer[11];
   const char kNoChar = static_cast<char>(-1);
   for (int i = 0; i <= 11; i++) {
     // Clear the buffer before reusing it
     for (int j = 0; j < 11; j++)
       buffer[j] = kNoChar;
     int written = mixed->WriteUtf8(buffer, i);
     CHECK_EQ(lengths[i], written);
     // Check that the contents are correct
     for (int j = 0; j < lengths[i]; j++)
       CHECK_EQ(as_utf8[j], static_cast<unsigned char>(buffer[j]));
     // Check that the rest of the buffer hasn't been touched
     for (int j = lengths[i]; j < 11; j++)
       CHECK_EQ(kNoChar, buffer[j]);
   }
 }


 class TwoByteResource: public v8::String::ExternalStringResource {
  public:
   TwoByteResource(const uint16_t* data, size_t length, bool* destructed)
       : data_(data), length_(length), destructed_(destructed) {
     CHECK_NE(destructed, NULL);
     *destructed_ = false;
   }

   virtual ~TwoByteResource() {
     CHECK_NE(destructed_, NULL);
     CHECK(!*destructed_);
     *destructed_ = true;
   }

   const uint16_t* data() const { return data_; }
   size_t length() const { return length_; }

  private:
   const uint16_t* data_;
   size_t length_;
   bool* destructed_;
 };


 // Regression test case for http://crbug.com/9746. The problem was
 // that when we marked objects reachable only through weak pointers,
 // we ended up keeping a sliced symbol alive, even though we already
 // invoked the weak callback on the underlying external string thus
 // deleting its resource.
 TEST(Regress9746) {
   InitializeVM();

   // Setup lengths that guarantee we'll get slices instead of simple
   // flat strings.
   static const int kFullStringLength = String::kMinNonFlatLength * 2;
   static const int kSliceStringLength = String::kMinNonFlatLength + 1;

   uint16_t* source = new uint16_t[kFullStringLength];
   for (int i = 0; i < kFullStringLength; i++) source[i] = '1';
   char* key = new char[kSliceStringLength];
   for (int i = 0; i < kSliceStringLength; i++) key[i] = '1';
   Vector<const char> key_vector(key, kSliceStringLength);

   // Allocate an external string resource that keeps track of when it
   // is destructed.
   bool resource_destructed = false;
   TwoByteResource* resource =
       new TwoByteResource(source, kFullStringLength, &resource_destructed);

   {
     v8::HandleScope scope;

     // Allocate an external string resource and external string. We
     // have to go through the API to get the weak handle and the
     // automatic destruction going.
     Handle<String> string =
         v8::Utils::OpenHandle(*v8::String::NewExternal(resource));

     // Create a slice of the external string.
     Handle<String> slice =
         Factory::NewStringSlice(string, 0, kSliceStringLength);
     CHECK_EQ(kSliceStringLength, slice->length());
     CHECK(StringShape(*slice).IsSliced());

     // Make sure the slice ends up in old space so we can morph it
     // into a symbol.
     while (Heap::InNewSpace(*slice)) {
       Heap::PerformScavenge();
     }

     // Force the slice into the symbol table.
     slice = Factory::SymbolFromString(slice);
     CHECK(slice->IsSymbol());
     CHECK(StringShape(*slice).IsSliced());

     Handle<String> buffer(Handle<SlicedString>::cast(slice)->buffer());
     CHECK(StringShape(*buffer).IsExternal());
     CHECK(buffer->IsTwoByteRepresentation());

     // Finally, base a script on the slice of the external string and
     // get its wrapper. This allocates yet another weak handle that
     // indirectly refers to the external string.
     Handle<Script> script = Factory::NewScript(slice);
     Handle<JSObject> wrapper = GetScriptWrapper(script);
   }

   // When we collect all garbage, we cannot get rid of the sliced
   // symbol entry in the symbol table because it is used by the script
   // kept alive by the weak wrapper. Make sure we don't destruct the
   // external string.
   Heap::CollectAllGarbage(false);
   CHECK(!resource_destructed);

   {
     v8::HandleScope scope;

     // Make sure the sliced symbol is still in the table.
     Handle<String> symbol = Factory::LookupSymbol(key_vector);
     CHECK(StringShape(*symbol).IsSliced());

     // Make sure the buffer is still a two-byte external string.
     Handle<String> buffer(Handle<SlicedString>::cast(symbol)->buffer());
     CHECK(StringShape(*buffer).IsExternal());
     CHECK(buffer->IsTwoByteRepresentation());
   }

   // Forcing another garbage collection should let us get rid of the
   // slice from the symbol table. The external string remains in the
   // heap until the next GC.
   Heap::CollectAllGarbage(false);
   CHECK(!resource_destructed);
   v8::HandleScope scope;
   Handle<String> key_string = Factory::NewStringFromAscii(key_vector);
   String* out;
   CHECK(!Heap::LookupSymbolIfExists(*key_string, &out));

   // Forcing yet another garbage collection must allow us to finally
   // get rid of the external string.
   Heap::CollectAllGarbage(false);
   CHECK(resource_destructed);

   delete[] source;
   delete[] key;
 }
	// Copyright 2006-2008 the V8 project authors. All rights reserved.

	// Check that we can traverse very deep stacks of ConsStrings using
	// StringInputBuffer. Check that Get(int) works on very deep stacks
	// of ConsStrings. These operations may not be very fast, but they
	// should be possible without getting errors due to too deep recursion.

	#include <stdlib.h>

	#include "v8.h"

	#include "api.h"
	#include "factory.h"
	#include "cctest.h"
	#include "zone-inl.h"

	unsigned int seed = 123;

	static uint32_t gen() {
	uint64_t z;
	z = seed;
	z *= 279470273;
	z %= 4294967291U;
	seed = static_cast<unsigned int>(z);
	return static_cast<uint32_t>(seed >> 16);
	}


	using namespace v8::internal;

	static v8::Persistent<v8::Context> env;


	static void InitializeVM() {
	if (env.IsEmpty()) {
	v8::HandleScope scope;
	const char* extensions[] = { "v8/print" };
	v8::ExtensionConfiguration config(1, extensions);
	env = v8::Context::New(&config);
	}
	v8::HandleScope scope;
	env->Enter();
	}


	static const int NUMBER_OF_BUILDING_BLOCKS = 128;
	static const int DEEP_DEPTH = 8 * 1024;
	static const int SUPER_DEEP_DEPTH = 80 * 1024;


	class Resource: public v8::String::ExternalStringResource,
	public ZoneObject {
	public:
	explicit Resource(Vector<const uc16> string): data_(string.start()) {
	length_ = string.length();
	}
	virtual const uint16_t* data() const { return data_; }
	virtual size_t length() const { return length_; }

	private:
	const uc16* data_;
	size_t length_;
	};


	static void InitializeBuildingBlocks(
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS]) {
	// A list of pointers that we don't have any interest in cleaning up.
	// If they are reachable from a root then leak detection won't complain.
	for (int i = 0; i < NUMBER_OF_BUILDING_BLOCKS; i++) {
	int len = gen() % 16;
	if (len > 14) {
	len += 1234;
	}
	switch (gen() % 4) {
	case 0: {
	uc16 buf[2000];
	for (int j = 0; j < len; j++) {
	buf[j] = gen() % 65536;
	}
	building_blocks[i] =
	Factory::NewStringFromTwoByte(Vector<const uc16>(buf, len));
	for (int j = 0; j < len; j++) {
	CHECK_EQ(buf[j], building_blocks[i]->Get(j));
	}
	break;
	}
	case 1: {
	char buf[2000];
	for (int j = 0; j < len; j++) {
	buf[j] = gen() % 128;
	}
	building_blocks[i] =
	Factory::NewStringFromAscii(Vector<const char>(buf, len));
	for (int j = 0; j < len; j++) {
	CHECK_EQ(buf[j], building_blocks[i]->Get(j));
	}
	break;
	}
	case 2: {
	uc16* buf = Zone::NewArray<uc16>(len);
	for (int j = 0; j < len; j++) {
	buf[j] = gen() % 65536;
	}
	Resource* resource = new Resource(Vector<const uc16>(buf, len));
	building_blocks[i] = Factory::NewExternalStringFromTwoByte(resource);
	for (int j = 0; j < len; j++) {
	CHECK_EQ(buf[j], building_blocks[i]->Get(j));
	}
	break;
	}
	case 3: {
	char* buf = NewArray<char>(len);
	for (int j = 0; j < len; j++) {
	buf[j] = gen() % 128;
	}
	building_blocks[i] =
	Factory::NewStringFromAscii(Vector<const char>(buf, len));
	for (int j = 0; j < len; j++) {
	CHECK_EQ(buf[j], building_blocks[i]->Get(j));
	}
	DeleteArray<char>(buf);
	break;
	}
	}
	}
	}


	static Handle<String> ConstructLeft(
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
	int depth) {
	Handle<String> answer = Factory::NewStringFromAscii(CStrVector(""));
	for (int i = 0; i < depth; i++) {
	answer = Factory::NewConsString(
	answer,
	building_blocks[i % NUMBER_OF_BUILDING_BLOCKS]);
	}
	return answer;
	}


	static Handle<String> ConstructRight(
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
	int depth) {
	Handle<String> answer = Factory::NewStringFromAscii(CStrVector(""));
	for (int i = depth - 1; i >= 0; i--) {
	answer = Factory::NewConsString(
	building_blocks[i % NUMBER_OF_BUILDING_BLOCKS],
	answer);
	}
	return answer;
	}


	static Handle<String> ConstructBalancedHelper(
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
	int from,
	int to) {
	CHECK(to > from);
	if (to - from == 1) {
	return building_blocks[from % NUMBER_OF_BUILDING_BLOCKS];
	}
	if (to - from == 2) {
	return Factory::NewConsString(
	building_blocks[from % NUMBER_OF_BUILDING_BLOCKS],
	building_blocks[(from+1) % NUMBER_OF_BUILDING_BLOCKS]);
	}
	Handle<String> part1 =
	ConstructBalancedHelper(building_blocks, from, from + ((to - from) / 2));
	Handle<String> part2 =
	ConstructBalancedHelper(building_blocks, from + ((to - from) / 2), to);
	return Factory::NewConsString(part1, part2);
	}


	static Handle<String> ConstructBalanced(
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS]) {
	return ConstructBalancedHelper(building_blocks, 0, DEEP_DEPTH);
	}


	static StringInputBuffer buffer;


	static void Traverse(Handle<String> s1, Handle<String> s2) {
	int i = 0;
	buffer.Reset(*s1);
	StringInputBuffer buffer2(*s2);
	while (buffer.has_more()) {
	CHECK(buffer2.has_more());
	uint16_t c = buffer.GetNext();
	CHECK_EQ(c, buffer2.GetNext());
	i++;
	}
	CHECK_EQ(s1->length(), i);
	CHECK_EQ(s2->length(), i);
	}


	static void TraverseFirst(Handle<String> s1, Handle<String> s2, int chars) {
	int i = 0;
	buffer.Reset(*s1);
	StringInputBuffer buffer2(*s2);
	while (buffer.has_more() && i < chars) {
	CHECK(buffer2.has_more());
	uint16_t c = buffer.GetNext();
	CHECK_EQ(c, buffer2.GetNext());
	i++;
	}
	s1->Get(s1->length() - 1);
	s2->Get(s2->length() - 1);
	}


	TEST(Traverse) {
	printf("TestTraverse\n");
	InitializeVM();
	v8::HandleScope scope;
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS];
	ZoneScope zone(DELETE_ON_EXIT);
	InitializeBuildingBlocks(building_blocks);
	Handle<String> flat = ConstructBalanced(building_blocks);
	FlattenString(flat);
	Handle<String> left_asymmetric = ConstructLeft(building_blocks, DEEP_DEPTH);
	Handle<String> right_asymmetric = ConstructRight(building_blocks, DEEP_DEPTH);
	Handle<String> symmetric = ConstructBalanced(building_blocks);
	printf("1\n");
	Traverse(flat, symmetric);
	printf("2\n");
	Traverse(flat, left_asymmetric);
	printf("3\n");
	Traverse(flat, right_asymmetric);
	printf("4\n");
	Handle<String> left_deep_asymmetric =
	ConstructLeft(building_blocks, SUPER_DEEP_DEPTH);
	Handle<String> right_deep_asymmetric =
	ConstructRight(building_blocks, SUPER_DEEP_DEPTH);
	printf("5\n");
	TraverseFirst(left_asymmetric, left_deep_asymmetric, 1050);
	printf("6\n");
	TraverseFirst(left_asymmetric, right_deep_asymmetric, 65536);
	printf("7\n");
	Handle<String> right_deep_slice =
	Factory::NewStringSlice(left_deep_asymmetric,
	left_deep_asymmetric->length() - 1050,
	left_deep_asymmetric->length() - 50);
	Handle<String> left_deep_slice =
	Factory::NewStringSlice(right_deep_asymmetric,
	right_deep_asymmetric->length() - 1050,
	right_deep_asymmetric->length() - 50);
	printf("8\n");
	Traverse(right_deep_slice, left_deep_slice);
	printf("9\n");
	FlattenString(left_asymmetric);
	printf("10\n");
	Traverse(flat, left_asymmetric);
	printf("11\n");
	FlattenString(right_asymmetric);
	printf("12\n");
	Traverse(flat, right_asymmetric);
	printf("14\n");
	FlattenString(symmetric);
	printf("15\n");
	Traverse(flat, symmetric);
	printf("16\n");
	FlattenString(left_deep_asymmetric);
	printf("18\n");
	}


	static Handle<String> SliceOf(Handle<String> underlying) {
	int start = gen() % underlying->length();
	int end = start + gen() % (underlying->length() - start);
	return Factory::NewStringSlice(underlying,
	start,
	end);
	}


	static Handle<String> ConstructSliceTree(
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS],
	int from,
	int to) {
	CHECK(to > from);
	if (to - from <= 1)
	return SliceOf(building_blocks[from % NUMBER_OF_BUILDING_BLOCKS]);
	if (to - from == 2) {
	Handle<String> lhs = building_blocks[from % NUMBER_OF_BUILDING_BLOCKS];
	if (gen() % 2 == 0)
	lhs = SliceOf(lhs);
	Handle<String> rhs = building_blocks[(from+1) % NUMBER_OF_BUILDING_BLOCKS];
	if (gen() % 2 == 0)
	rhs = SliceOf(rhs);
	return Factory::NewConsString(lhs, rhs);
	}
	Handle<String> part1 =
	ConstructBalancedHelper(building_blocks, from, from + ((to - from) / 2));
	Handle<String> part2 =
	ConstructBalancedHelper(building_blocks, from + ((to - from) / 2), to);
	Handle<String> branch = Factory::NewConsString(part1, part2);
	if (gen() % 2 == 0)
	return branch;
	return(SliceOf(branch));
	}


	TEST(Slice) {
	printf("TestSlice\n");
	InitializeVM();
	v8::HandleScope scope;
	Handle<String> building_blocks[NUMBER_OF_BUILDING_BLOCKS];
	ZoneScope zone(DELETE_ON_EXIT);
	InitializeBuildingBlocks(building_blocks);

	seed = 42;
	Handle<String> slice_tree =
	ConstructSliceTree(building_blocks, 0, DEEP_DEPTH);
	seed = 42;
	Handle<String> flat_slice_tree =
	ConstructSliceTree(building_blocks, 0, DEEP_DEPTH);
	FlattenString(flat_slice_tree);
	Traverse(flat_slice_tree, slice_tree);
	}

	static const int DEEP_ASCII_DEPTH = 100000;


	TEST(DeepAscii) {
	printf("TestDeepAscii\n");
	InitializeVM();
	v8::HandleScope scope;

	char* foo = NewArray<char>(DEEP_ASCII_DEPTH);
	for (int i = 0; i < DEEP_ASCII_DEPTH; i++) {
	foo[i] = "foo "[i % 4];
	}
	Handle<String> string =
	Factory::NewStringFromAscii(Vector<const char>(foo, DEEP_ASCII_DEPTH));
	Handle<String> foo_string = Factory::NewStringFromAscii(CStrVector("foo"));
	for (int i = 0; i < DEEP_ASCII_DEPTH; i += 10) {
	string = Factory::NewConsString(string, foo_string);
	}
	Handle<String> flat_string = Factory::NewConsString(string, foo_string);
	FlattenString(flat_string);

	for (int i = 0; i < 500; i++) {
	TraverseFirst(flat_string, string, DEEP_ASCII_DEPTH);
	}
	DeleteArray<char>(foo);
	}


	TEST(Utf8Conversion) {
	// Smoke test for converting strings to utf-8.
	InitializeVM();
	v8::HandleScope handle_scope;
	// A simple ascii string
	const char* ascii_string = "abcdef12345";
	int len = v8::String::New(ascii_string, strlen(ascii_string))->Utf8Length();
	CHECK_EQ(strlen(ascii_string), len);
	// A mixed ascii and non-ascii string
	// U+02E4 -> CB A4
	// U+0064 -> 64
	// U+12E4 -> E1 8B A4
	// U+0030 -> 30
	// U+3045 -> E3 81 85
	const uint16_t mixed_string[] = {0x02E4, 0x0064, 0x12E4, 0x0030, 0x3045};
	// The characters we expect to be output
	const unsigned char as_utf8[11] = {0xCB, 0xA4, 0x64, 0xE1, 0x8B, 0xA4, 0x30,
	0xE3, 0x81, 0x85, 0x00};
	// The number of bytes expected to be written for each length
	const int lengths[12] = {0, 0, 2, 3, 3, 3, 6, 7, 7, 7, 10, 11};
	v8::Handle<v8::String> mixed = v8::String::New(mixed_string, 5);
	CHECK_EQ(10, mixed->Utf8Length());
	// Try encoding the string with all capacities
	char buffer[11];
	const char kNoChar = static_cast<char>(-1);
	for (int i = 0; i <= 11; i++) {
	// Clear the buffer before reusing it
	for (int j = 0; j < 11; j++)
	buffer[j] = kNoChar;
	int written = mixed->WriteUtf8(buffer, i);
	CHECK_EQ(lengths[i], written);
	// Check that the contents are correct
	for (int j = 0; j < lengths[i]; j++)
	CHECK_EQ(as_utf8[j], static_cast<unsigned char>(buffer[j]));
	// Check that the rest of the buffer hasn't been touched
	for (int j = lengths[i]; j < 11; j++)
	CHECK_EQ(kNoChar, buffer[j]);
	}
	}


	class TwoByteResource: public v8::String::ExternalStringResource {
	public:
	TwoByteResource(const uint16_t* data, size_t length, bool* destructed)
	: data_(data), length_(length), destructed_(destructed) {
	CHECK_NE(destructed, NULL);
	*destructed_ = false;
	}

	virtual ~TwoByteResource() {
	CHECK_NE(destructed_, NULL);
	CHECK(!*destructed_);
	*destructed_ = true;
	}

	const uint16_t* data() const { return data_; }
	size_t length() const { return length_; }

	private:
	const uint16_t* data_;
	size_t length_;
	bool* destructed_;
	};


	// Regression test case for http://crbug.com/9746. The problem was
	// that when we marked objects reachable only through weak pointers,
	// we ended up keeping a sliced symbol alive, even though we already
	// invoked the weak callback on the underlying external string thus
	// deleting its resource.
	TEST(Regress9746) {
	InitializeVM();

	// Setup lengths that guarantee we'll get slices instead of simple
	// flat strings.
	static const int kFullStringLength = String::kMinNonFlatLength * 2;
	static const int kSliceStringLength = String::kMinNonFlatLength + 1;

	uint16_t* source = new uint16_t[kFullStringLength];
	for (int i = 0; i < kFullStringLength; i++) source[i] = '1';
	char* key = new char[kSliceStringLength];
	for (int i = 0; i < kSliceStringLength; i++) key[i] = '1';
	Vector<const char> key_vector(key, kSliceStringLength);

	// Allocate an external string resource that keeps track of when it
	// is destructed.
	bool resource_destructed = false;
	TwoByteResource* resource =
	new TwoByteResource(source, kFullStringLength, &resource_destructed);

	{
	v8::HandleScope scope;

	// Allocate an external string resource and external string. We
	// have to go through the API to get the weak handle and the
	// automatic destruction going.
	Handle<String> string =
	v8::Utils::OpenHandle(*v8::String::NewExternal(resource));

	// Create a slice of the external string.
	Handle<String> slice =
	Factory::NewStringSlice(string, 0, kSliceStringLength);
	CHECK_EQ(kSliceStringLength, slice->length());
	CHECK(StringShape(*slice).IsSliced());

	// Make sure the slice ends up in old space so we can morph it
	// into a symbol.
	while (Heap::InNewSpace(*slice)) {
	Heap::PerformScavenge();
	}

	// Force the slice into the symbol table.
	slice = Factory::SymbolFromString(slice);
	CHECK(slice->IsSymbol());
	CHECK(StringShape(*slice).IsSliced());

	Handle<String> buffer(Handle<SlicedString>::cast(slice)->buffer());
	CHECK(StringShape(*buffer).IsExternal());
	CHECK(buffer->IsTwoByteRepresentation());

	// Finally, base a script on the slice of the external string and
	// get its wrapper. This allocates yet another weak handle that
	// indirectly refers to the external string.
	Handle<Script> script = Factory::NewScript(slice);
	Handle<JSObject> wrapper = GetScriptWrapper(script);
	}

	// When we collect all garbage, we cannot get rid of the sliced
	// symbol entry in the symbol table because it is used by the script
	// kept alive by the weak wrapper. Make sure we don't destruct the
	// external string.
	Heap::CollectAllGarbage(false);
	CHECK(!resource_destructed);

	{
	v8::HandleScope scope;

	// Make sure the sliced symbol is still in the table.
	Handle<String> symbol = Factory::LookupSymbol(key_vector);
	CHECK(StringShape(*symbol).IsSliced());

	// Make sure the buffer is still a two-byte external string.
	Handle<String> buffer(Handle<SlicedString>::cast(symbol)->buffer());
	CHECK(StringShape(*buffer).IsExternal());
	CHECK(buffer->IsTwoByteRepresentation());
	}

	// Forcing another garbage collection should let us get rid of the
	// slice from the symbol table. The external string remains in the
	// heap until the next GC.
	Heap::CollectAllGarbage(false);
	CHECK(!resource_destructed);
	v8::HandleScope scope;
	Handle<String> key_string = Factory::NewStringFromAscii(key_vector);
	String* out;
	CHECK(!Heap::LookupSymbolIfExists(*key_string, &out));

	// Forcing yet another garbage collection must allow us to finally
	// get rid of the external string.
	Heap::CollectAllGarbage(false);
	CHECK(resource_destructed);

	delete[] source;
	delete[] key;
	}