third_party/v8/src/strings/string-stream.cc - cobalt - Git at Google

 // Copyright 2014 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/strings/string-stream.h"

 #include <memory>

 #include "src/handles/handles-inl.h"
 #include "src/logging/log.h"
 #include "src/objects/js-array-inl.h"
 #include "src/objects/objects-inl.h"
 #include "src/objects/prototype.h"
 #include "src/utils/vector.h"

 namespace v8 {
 namespace internal {

 static const int kMentionedObjectCacheMaxSize = 256;

 char* HeapStringAllocator::allocate(unsigned bytes) {
   space_ = NewArray<char>(bytes);
   return space_;
 }

 char* FixedStringAllocator::allocate(unsigned bytes) {
   CHECK_LE(bytes, length_);
   return buffer_;
 }

 char* FixedStringAllocator::grow(unsigned* old) {
   *old = length_;
   return buffer_;
 }

 bool StringStream::Put(char c) {
   if (full()) return false;
   DCHECK(length_ < capacity_);
   // Since the trailing '\0' is not accounted for in length_ fullness is
   // indicated by a difference of 1 between length_ and capacity_. Thus when
   // reaching a difference of 2 we need to grow the buffer.
   if (length_ == capacity_ - 2) {
     unsigned new_capacity = capacity_;
     char* new_buffer = allocator_->grow(&new_capacity);
     if (new_capacity > capacity_) {
       capacity_ = new_capacity;
       buffer_ = new_buffer;
     } else {
       // Reached the end of the available buffer.
       DCHECK_GE(capacity_, 5);
       length_ = capacity_ - 1;  // Indicate fullness of the stream.
       buffer_[length_ - 4] = '.';
       buffer_[length_ - 3] = '.';
       buffer_[length_ - 2] = '.';
       buffer_[length_ - 1] = '\n';
       buffer_[length_] = '\0';
       return false;
     }
   }
   buffer_[length_] = c;
   buffer_[length_ + 1] = '\0';
   length_++;
   return true;
 }

 // A control character is one that configures a format element.  For
 // instance, in %.5s, .5 are control characters.
 static bool IsControlChar(char c) {
   switch (c) {
     case '0':
     case '1':
     case '2':
     case '3':
     case '4':
     case '5':
     case '6':
     case '7':
     case '8':
     case '9':
     case '.':
     case '-':
       return true;
     default:
       return false;
   }
 }

 void StringStream::Add(Vector<const char> format, Vector<FmtElm> elms) {
   // If we already ran out of space then return immediately.
   if (full()) return;
   int offset = 0;
   int elm = 0;
   while (offset < format.length()) {
     if (format[offset] != '%' || elm == elms.length()) {
       Put(format[offset]);
       offset++;
       continue;
     }
     // Read this formatting directive into a temporary buffer
     EmbeddedVector<char, 24> temp;
     int format_length = 0;
     // Skip over the whole control character sequence until the
     // format element type
     temp[format_length++] = format[offset++];
     while (offset < format.length() && IsControlChar(format[offset]))
       temp[format_length++] = format[offset++];
     if (offset >= format.length()) return;
     char type = format[offset];
     temp[format_length++] = type;
     temp[format_length] = '\0';
     offset++;
     FmtElm current = elms[elm++];
     switch (type) {
       case 's': {
         DCHECK_EQ(FmtElm::C_STR, current.type_);
         const char* value = current.data_.u_c_str_;
         Add(value);
         break;
       }
       case 'w': {
         DCHECK_EQ(FmtElm::LC_STR, current.type_);
         Vector<const uc16> value = *current.data_.u_lc_str_;
         for (int i = 0; i < value.length(); i++)
           Put(static_cast<char>(value[i]));
         break;
       }
       case 'o': {
         DCHECK_EQ(FmtElm::OBJ, current.type_);
         Object obj(current.data_.u_obj_);
         PrintObject(obj);
         break;
       }
       case 'k': {
         DCHECK_EQ(FmtElm::INT, current.type_);
         int value = current.data_.u_int_;
         if (0x20 <= value && value <= 0x7F) {
           Put(value);
         } else if (value <= 0xFF) {
           Add("\\x%02x", value);
         } else {
           Add("\\u%04x", value);
         }
         break;
       }
       case 'i':
       case 'd':
       case 'u':
       case 'x':
       case 'c':
       case 'X': {
         int value = current.data_.u_int_;
         EmbeddedVector<char, 24> formatted;
         int length = SNPrintF(formatted, temp.begin(), value);
         Add(Vector<const char>(formatted.begin(), length));
         break;
       }
       case 'f':
       case 'g':
       case 'G':
       case 'e':
       case 'E': {
         double value = current.data_.u_double_;
         int inf = std::isinf(value);
         if (inf == -1) {
           Add("-inf");
         } else if (inf == 1) {
           Add("inf");
         } else if (std::isnan(value)) {
           Add("nan");
         } else {
           EmbeddedVector<char, 28> formatted;
           SNPrintF(formatted, temp.begin(), value);
           Add(formatted.begin());
         }
         break;
       }
       case 'p': {
         void* value = current.data_.u_pointer_;
         EmbeddedVector<char, 20> formatted;
         SNPrintF(formatted, temp.begin(), value);
         Add(formatted.begin());
         break;
       }
       default:
         UNREACHABLE();
     }
   }

   // Verify that the buffer is 0-terminated
   DCHECK_EQ(buffer_[length_], '\0');
 }

 void StringStream::PrintObject(Object o) {
   o.ShortPrint(this);
   if (o.IsString()) {
     if (String::cast(o).length() <= String::kMaxShortPrintLength) {
       return;
     }
   } else if (o.IsNumber() || o.IsOddball()) {
     return;
   }
   if (o.IsHeapObject() && object_print_mode_ == kPrintObjectVerbose) {
     // TODO(delphick): Consider whether we can get the isolate without using
     // TLS.
     Isolate* isolate = Isolate::Current();
     DebugObjectCache* debug_object_cache =
         isolate->string_stream_debug_object_cache();
     for (size_t i = 0; i < debug_object_cache->size(); i++) {
       if (*(*debug_object_cache)[i] == o) {
         Add("#%d#", static_cast<int>(i));
         return;
       }
     }
     if (debug_object_cache->size() < kMentionedObjectCacheMaxSize) {
       Add("#%d#", static_cast<int>(debug_object_cache->size()));
       debug_object_cache->push_back(handle(HeapObject::cast(o), isolate));
     } else {
       Add("@%p", o);
     }
   }
 }

 std::unique_ptr<char[]> StringStream::ToCString() const {
   char* str = NewArray<char>(length_ + 1);
   MemCopy(str, buffer_, length_);
   str[length_] = '\0';
   return std::unique_ptr<char[]>(str);
 }

 void StringStream::Log(Isolate* isolate) {
   LOG(isolate, StringEvent("StackDump", buffer_));
 }

 void StringStream::OutputToFile(FILE* out) {
   // Dump the output to stdout, but make sure to break it up into
   // manageable chunks to avoid losing parts of the output in the OS
   // printing code. This is a problem on Windows in particular; see
   // the VPrint() function implementations in platform-win32.cc.
   unsigned position = 0;
   for (unsigned next; (next = position + 2048) < length_; position = next) {
     char save = buffer_[next];
     buffer_[next] = '\0';
     internal::PrintF(out, "%s", &buffer_[position]);
     buffer_[next] = save;
   }
   internal::PrintF(out, "%s", &buffer_[position]);
 }

 Handle<String> StringStream::ToString(Isolate* isolate) {
   return isolate->factory()
       ->NewStringFromUtf8(Vector<const char>(buffer_, length_))
       .ToHandleChecked();
 }

 void StringStream::ClearMentionedObjectCache(Isolate* isolate) {
   isolate->set_string_stream_current_security_token(Object());
   if (isolate->string_stream_debug_object_cache() == nullptr) {
     isolate->set_string_stream_debug_object_cache(new DebugObjectCache());
   }
   isolate->string_stream_debug_object_cache()->clear();
 }

 #ifdef DEBUG
 bool StringStream::IsMentionedObjectCacheClear(Isolate* isolate) {
   return object_print_mode_ == kPrintObjectConcise ||
          isolate->string_stream_debug_object_cache()->size() == 0;
 }
 #endif

 bool StringStream::Put(String str) { return Put(str, 0, str.length()); }

 bool StringStream::Put(String str, int start, int end) {
   StringCharacterStream stream(str, start);
   for (int i = start; i < end && stream.HasMore(); i++) {
     uint16_t c = stream.GetNext();
     if (c >= 127 || c < 32) {
       c = '?';
     }
     if (!Put(static_cast<char>(c))) {
       return false;  // Output was truncated.
     }
   }
   return true;
 }

 void StringStream::PrintName(Object name) {
   if (name.IsString()) {
     String str = String::cast(name);
     if (str.length() > 0) {
       Put(str);
     } else {
       Add("/* anonymous */");
     }
   } else {
     Add("%o", name);
   }
 }

 void StringStream::PrintUsingMap(JSObject js_object) {
   Map map = js_object.map();
   DescriptorArray descs = map.instance_descriptors(kRelaxedLoad);
   for (InternalIndex i : map.IterateOwnDescriptors()) {
     PropertyDetails details = descs.GetDetails(i);
     if (details.location() == kField) {
       DCHECK_EQ(kData, details.kind());
       Object key = descs.GetKey(i);
       if (key.IsString() || key.IsNumber()) {
         int len = 3;
         if (key.IsString()) {
           len = String::cast(key).length();
         }
         for (; len < 18; len++) Put(' ');
         if (key.IsString()) {
           Put(String::cast(key));
         } else {
           key.ShortPrint();
         }
         Add(": ");
         FieldIndex index = FieldIndex::ForDescriptor(map, i);
         if (js_object.IsUnboxedDoubleField(index)) {
           double value = js_object.RawFastDoublePropertyAt(index);
           Add("<unboxed double> %.16g\n", FmtElm(value));
         } else {
           Object value = js_object.RawFastPropertyAt(index);
           Add("%o\n", value);
         }
       }
     }
   }
 }

 void StringStream::PrintFixedArray(FixedArray array, unsigned int limit) {
   ReadOnlyRoots roots = array.GetReadOnlyRoots();
   for (unsigned int i = 0; i < 10 && i < limit; i++) {
     Object element = array.get(i);
     if (element.IsTheHole(roots)) continue;
     for (int len = 1; len < 18; len++) {
       Put(' ');
     }
     Add("%d: %o\n", i, array.get(i));
   }
   if (limit >= 10) {
     Add("                  ...\n");
   }
 }

 void StringStream::PrintByteArray(ByteArray byte_array) {
   unsigned int limit = byte_array.length();
   for (unsigned int i = 0; i < 10 && i < limit; i++) {
     byte b = byte_array.get(i);
     Add("             %d: %3d 0x%02x", i, b, b);
     if (b >= ' ' && b <= '~') {
       Add(" '%c'", b);
     } else if (b == '\n') {
       Add(" '\n'");
     } else if (b == '\r') {
       Add(" '\r'");
     } else if (b >= 1 && b <= 26) {
       Add(" ^%c", b + 'A' - 1);
     }
     Add("\n");
   }
   if (limit >= 10) {
     Add("                  ...\n");
   }
 }

 void StringStream::PrintMentionedObjectCache(Isolate* isolate) {
   if (object_print_mode_ == kPrintObjectConcise) return;
   DebugObjectCache* debug_object_cache =
       isolate->string_stream_debug_object_cache();
   Add("==== Key         ============================================\n\n");
   for (size_t i = 0; i < debug_object_cache->size(); i++) {
     HeapObject printee = *(*debug_object_cache)[i];
     Add(" #%d# %p: ", static_cast<int>(i),
         reinterpret_cast<void*>(printee.ptr()));
     printee.ShortPrint(this);
     Add("\n");
     if (printee.IsJSObject()) {
       if (printee.IsJSPrimitiveWrapper()) {
         Add("           value(): %o\n",
             JSPrimitiveWrapper::cast(printee).value());
       }
       PrintUsingMap(JSObject::cast(printee));
       if (printee.IsJSArray()) {
         JSArray array = JSArray::cast(printee);
         if (array.HasObjectElements()) {
           unsigned int limit = FixedArray::cast(array.elements()).length();
           unsigned int length =
               static_cast<uint32_t>(JSArray::cast(array).length().Number());
           if (length < limit) limit = length;
           PrintFixedArray(FixedArray::cast(array.elements()), limit);
         }
       }
     } else if (printee.IsByteArray()) {
       PrintByteArray(ByteArray::cast(printee));
     } else if (printee.IsFixedArray()) {
       unsigned int limit = FixedArray::cast(printee).length();
       PrintFixedArray(FixedArray::cast(printee), limit);
     }
   }
 }

 void StringStream::PrintSecurityTokenIfChanged(JSFunction fun) {
   Object token = fun.native_context().security_token();
   Isolate* isolate = fun.GetIsolate();
   if (token != isolate->string_stream_current_security_token()) {
     Add("Security context: %o\n", token);
     isolate->set_string_stream_current_security_token(token);
   }
 }

 void StringStream::PrintFunction(JSFunction fun, Object receiver, Code* code) {
   PrintPrototype(fun, receiver);
   *code = fun.code();
 }

 void StringStream::PrintPrototype(JSFunction fun, Object receiver) {
   Object name = fun.shared().Name();
   bool print_name = false;
   Isolate* isolate = fun.GetIsolate();
   if (receiver.IsNullOrUndefined(isolate) || receiver.IsTheHole(isolate) ||
       receiver.IsJSProxy()) {
     print_name = true;
   } else if (!isolate->context().is_null()) {
     if (!receiver.IsJSObject()) {
       receiver = receiver.GetPrototypeChainRootMap(isolate).prototype();
     }

     for (PrototypeIterator iter(isolate, JSObject::cast(receiver),
                                 kStartAtReceiver);
          !iter.IsAtEnd(); iter.Advance()) {
       if (iter.GetCurrent().IsJSProxy()) break;
       Object key = iter.GetCurrent<JSObject>().SlowReverseLookup(fun);
       if (!key.IsUndefined(isolate)) {
         if (!name.IsString() || !key.IsString() ||
             !String::cast(name).Equals(String::cast(key))) {
           print_name = true;
         }
         if (name.IsString() && String::cast(name).length() == 0) {
           print_name = false;
         }
         name = key;
         break;
       }
     }
   }
   PrintName(name);
   // Also known as - if the name in the function doesn't match the name under
   // which it was looked up.
   if (print_name) {
     Add("(aka ");
     PrintName(fun.shared().Name());
     Put(')');
   }
 }

 char* HeapStringAllocator::grow(unsigned* bytes) {
   unsigned new_bytes = *bytes * 2;
   // Check for overflow.
   if (new_bytes <= *bytes) {
     return space_;
   }
   char* new_space = NewArray<char>(new_bytes);
   if (new_space == nullptr) {
     return space_;
   }
   MemCopy(new_space, space_, *bytes);
   *bytes = new_bytes;
   DeleteArray(space_);
   space_ = new_space;
   return new_space;
 }

 }  // namespace internal
 }  // namespace v8
	// Copyright 2014 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/strings/string-stream.h"

	#include <memory>

	#include "src/handles/handles-inl.h"
	#include "src/logging/log.h"
	#include "src/objects/js-array-inl.h"
	#include "src/objects/objects-inl.h"
	#include "src/objects/prototype.h"
	#include "src/utils/vector.h"

	namespace v8 {
	namespace internal {

	static const int kMentionedObjectCacheMaxSize = 256;

	char* HeapStringAllocator::allocate(unsigned bytes) {
	space_ = NewArray<char>(bytes);
	return space_;
	}

	char* FixedStringAllocator::allocate(unsigned bytes) {
	CHECK_LE(bytes, length_);
	return buffer_;
	}

	char* FixedStringAllocator::grow(unsigned* old) {
	*old = length_;
	return buffer_;
	}

	bool StringStream::Put(char c) {
	if (full()) return false;
	DCHECK(length_ < capacity_);
	// Since the trailing '\0' is not accounted for in length_ fullness is
	// indicated by a difference of 1 between length_ and capacity_. Thus when
	// reaching a difference of 2 we need to grow the buffer.
	if (length_ == capacity_ - 2) {
	unsigned new_capacity = capacity_;
	char* new_buffer = allocator_->grow(&new_capacity);
	if (new_capacity > capacity_) {
	capacity_ = new_capacity;
	buffer_ = new_buffer;
	} else {
	// Reached the end of the available buffer.
	DCHECK_GE(capacity_, 5);
	length_ = capacity_ - 1; // Indicate fullness of the stream.
	buffer_[length_ - 4] = '.';
	buffer_[length_ - 3] = '.';
	buffer_[length_ - 2] = '.';
	buffer_[length_ - 1] = '\n';
	buffer_[length_] = '\0';
	return false;
	}
	}
	buffer_[length_] = c;
	buffer_[length_ + 1] = '\0';
	length_++;
	return true;
	}

	// A control character is one that configures a format element. For
	// instance, in %.5s, .5 are control characters.
	static bool IsControlChar(char c) {
	switch (c) {
	case '0':
	case '1':
	case '2':
	case '3':
	case '4':
	case '5':
	case '6':
	case '7':
	case '8':
	case '9':
	case '.':
	case '-':
	return true;
	default:
	return false;
	}
	}

	void StringStream::Add(Vector<const char> format, Vector<FmtElm> elms) {
	// If we already ran out of space then return immediately.
	if (full()) return;
	int offset = 0;
	int elm = 0;
	while (offset < format.length()) {
	if (format[offset] != '%' \|\| elm == elms.length()) {
	Put(format[offset]);
	offset++;
	continue;
	}
	// Read this formatting directive into a temporary buffer
	EmbeddedVector<char, 24> temp;
	int format_length = 0;
	// Skip over the whole control character sequence until the
	// format element type
	temp[format_length++] = format[offset++];
	while (offset < format.length() && IsControlChar(format[offset]))
	temp[format_length++] = format[offset++];
	if (offset >= format.length()) return;
	char type = format[offset];
	temp[format_length++] = type;
	temp[format_length] = '\0';
	offset++;
	FmtElm current = elms[elm++];
	switch (type) {
	case 's': {
	DCHECK_EQ(FmtElm::C_STR, current.type_);
	const char* value = current.data_.u_c_str_;
	Add(value);
	break;
	}
	case 'w': {
	DCHECK_EQ(FmtElm::LC_STR, current.type_);
	Vector<const uc16> value = *current.data_.u_lc_str_;
	for (int i = 0; i < value.length(); i++)
	Put(static_cast<char>(value[i]));
	break;
	}
	case 'o': {
	DCHECK_EQ(FmtElm::OBJ, current.type_);
	Object obj(current.data_.u_obj_);
	PrintObject(obj);
	break;
	}
	case 'k': {
	DCHECK_EQ(FmtElm::INT, current.type_);
	int value = current.data_.u_int_;
	if (0x20 <= value && value <= 0x7F) {
	Put(value);
	} else if (value <= 0xFF) {
	Add("\\x%02x", value);
	} else {
	Add("\\u%04x", value);
	}
	break;
	}
	case 'i':
	case 'd':
	case 'u':
	case 'x':
	case 'c':
	case 'X': {
	int value = current.data_.u_int_;
	EmbeddedVector<char, 24> formatted;
	int length = SNPrintF(formatted, temp.begin(), value);
	Add(Vector<const char>(formatted.begin(), length));
	break;
	}
	case 'f':
	case 'g':
	case 'G':
	case 'e':
	case 'E': {
	double value = current.data_.u_double_;
	int inf = std::isinf(value);
	if (inf == -1) {
	Add("-inf");
	} else if (inf == 1) {
	Add("inf");
	} else if (std::isnan(value)) {
	Add("nan");
	} else {
	EmbeddedVector<char, 28> formatted;
	SNPrintF(formatted, temp.begin(), value);
	Add(formatted.begin());
	}
	break;
	}
	case 'p': {
	void* value = current.data_.u_pointer_;
	EmbeddedVector<char, 20> formatted;
	SNPrintF(formatted, temp.begin(), value);
	Add(formatted.begin());
	break;
	}
	default:
	UNREACHABLE();
	}
	}

	// Verify that the buffer is 0-terminated
	DCHECK_EQ(buffer_[length_], '\0');
	}

	void StringStream::PrintObject(Object o) {
	o.ShortPrint(this);
	if (o.IsString()) {
	if (String::cast(o).length() <= String::kMaxShortPrintLength) {
	return;
	}
	} else if (o.IsNumber() \|\| o.IsOddball()) {
	return;
	}
	if (o.IsHeapObject() && object_print_mode_ == kPrintObjectVerbose) {
	// TODO(delphick): Consider whether we can get the isolate without using
	// TLS.
	Isolate* isolate = Isolate::Current();
	DebugObjectCache* debug_object_cache =
	isolate->string_stream_debug_object_cache();
	for (size_t i = 0; i < debug_object_cache->size(); i++) {
	if ((debug_object_cache)[i] == o) {
	Add("#%d#", static_cast<int>(i));
	return;
	}
	}
	if (debug_object_cache->size() < kMentionedObjectCacheMaxSize) {
	Add("#%d#", static_cast<int>(debug_object_cache->size()));
	debug_object_cache->push_back(handle(HeapObject::cast(o), isolate));
	} else {
	Add("@%p", o);
	}
	}
	}

	std::unique_ptr<char[]> StringStream::ToCString() const {
	char* str = NewArray<char>(length_ + 1);
	MemCopy(str, buffer_, length_);
	str[length_] = '\0';
	return std::unique_ptr<char[]>(str);
	}

	void StringStream::Log(Isolate* isolate) {
	LOG(isolate, StringEvent("StackDump", buffer_));
	}

	void StringStream::OutputToFile(FILE* out) {
	// Dump the output to stdout, but make sure to break it up into
	// manageable chunks to avoid losing parts of the output in the OS
	// printing code. This is a problem on Windows in particular; see
	// the VPrint() function implementations in platform-win32.cc.
	unsigned position = 0;
	for (unsigned next; (next = position + 2048) < length_; position = next) {
	char save = buffer_[next];
	buffer_[next] = '\0';
	internal::PrintF(out, "%s", &buffer_[position]);
	buffer_[next] = save;
	}
	internal::PrintF(out, "%s", &buffer_[position]);
	}

	Handle<String> StringStream::ToString(Isolate* isolate) {
	return isolate->factory()
	->NewStringFromUtf8(Vector<const char>(buffer_, length_))
	.ToHandleChecked();
	}

	void StringStream::ClearMentionedObjectCache(Isolate* isolate) {
	isolate->set_string_stream_current_security_token(Object());
	if (isolate->string_stream_debug_object_cache() == nullptr) {
	isolate->set_string_stream_debug_object_cache(new DebugObjectCache());
	}
	isolate->string_stream_debug_object_cache()->clear();
	}

	#ifdef DEBUG
	bool StringStream::IsMentionedObjectCacheClear(Isolate* isolate) {
	return object_print_mode_ == kPrintObjectConcise \|\|
	isolate->string_stream_debug_object_cache()->size() == 0;
	}
	#endif

	bool StringStream::Put(String str) { return Put(str, 0, str.length()); }

	bool StringStream::Put(String str, int start, int end) {
	StringCharacterStream stream(str, start);
	for (int i = start; i < end && stream.HasMore(); i++) {
	uint16_t c = stream.GetNext();
	if (c >= 127 \|\| c < 32) {
	c = '?';
	}
	if (!Put(static_cast<char>(c))) {
	return false; // Output was truncated.
	}
	}
	return true;
	}

	void StringStream::PrintName(Object name) {
	if (name.IsString()) {
	String str = String::cast(name);
	if (str.length() > 0) {
	Put(str);
	} else {
	Add("/* anonymous */");
	}
	} else {
	Add("%o", name);
	}
	}

	void StringStream::PrintUsingMap(JSObject js_object) {
	Map map = js_object.map();
	DescriptorArray descs = map.instance_descriptors(kRelaxedLoad);
	for (InternalIndex i : map.IterateOwnDescriptors()) {
	PropertyDetails details = descs.GetDetails(i);
	if (details.location() == kField) {
	DCHECK_EQ(kData, details.kind());
	Object key = descs.GetKey(i);
	if (key.IsString() \|\| key.IsNumber()) {
	int len = 3;
	if (key.IsString()) {
	len = String::cast(key).length();
	}
	for (; len < 18; len++) Put(' ');
	if (key.IsString()) {
	Put(String::cast(key));
	} else {
	key.ShortPrint();
	}
	Add(": ");
	FieldIndex index = FieldIndex::ForDescriptor(map, i);
	if (js_object.IsUnboxedDoubleField(index)) {
	double value = js_object.RawFastDoublePropertyAt(index);
	Add("<unboxed double> %.16g\n", FmtElm(value));
	} else {
	Object value = js_object.RawFastPropertyAt(index);
	Add("%o\n", value);
	}
	}
	}
	}
	}

	void StringStream::PrintFixedArray(FixedArray array, unsigned int limit) {
	ReadOnlyRoots roots = array.GetReadOnlyRoots();
	for (unsigned int i = 0; i < 10 && i < limit; i++) {
	Object element = array.get(i);
	if (element.IsTheHole(roots)) continue;
	for (int len = 1; len < 18; len++) {
	Put(' ');
	}
	Add("%d: %o\n", i, array.get(i));
	}
	if (limit >= 10) {
	Add(" ...\n");
	}
	}

	void StringStream::PrintByteArray(ByteArray byte_array) {
	unsigned int limit = byte_array.length();
	for (unsigned int i = 0; i < 10 && i < limit; i++) {
	byte b = byte_array.get(i);
	Add(" %d: %3d 0x%02x", i, b, b);
	if (b >= ' ' && b <= '~') {
	Add(" '%c'", b);
	} else if (b == '\n') {
	Add(" '\n'");
	} else if (b == '\r') {
	Add(" '\r'");
	} else if (b >= 1 && b <= 26) {
	Add(" ^%c", b + 'A' - 1);
	}
	Add("\n");
	}
	if (limit >= 10) {
	Add(" ...\n");
	}
	}

	void StringStream::PrintMentionedObjectCache(Isolate* isolate) {
	if (object_print_mode_ == kPrintObjectConcise) return;
	DebugObjectCache* debug_object_cache =
	isolate->string_stream_debug_object_cache();
	Add("==== Key ============================================\n\n");
	for (size_t i = 0; i < debug_object_cache->size(); i++) {
	HeapObject printee = (debug_object_cache)[i];
	Add(" #%d# %p: ", static_cast<int>(i),
	reinterpret_cast<void*>(printee.ptr()));
	printee.ShortPrint(this);
	Add("\n");
	if (printee.IsJSObject()) {
	if (printee.IsJSPrimitiveWrapper()) {
	Add(" value(): %o\n",
	JSPrimitiveWrapper::cast(printee).value());
	}
	PrintUsingMap(JSObject::cast(printee));
	if (printee.IsJSArray()) {
	JSArray array = JSArray::cast(printee);
	if (array.HasObjectElements()) {
	unsigned int limit = FixedArray::cast(array.elements()).length();
	unsigned int length =
	static_cast<uint32_t>(JSArray::cast(array).length().Number());
	if (length < limit) limit = length;
	PrintFixedArray(FixedArray::cast(array.elements()), limit);
	}
	}
	} else if (printee.IsByteArray()) {
	PrintByteArray(ByteArray::cast(printee));
	} else if (printee.IsFixedArray()) {
	unsigned int limit = FixedArray::cast(printee).length();
	PrintFixedArray(FixedArray::cast(printee), limit);
	}
	}
	}

	void StringStream::PrintSecurityTokenIfChanged(JSFunction fun) {
	Object token = fun.native_context().security_token();
	Isolate* isolate = fun.GetIsolate();
	if (token != isolate->string_stream_current_security_token()) {
	Add("Security context: %o\n", token);
	isolate->set_string_stream_current_security_token(token);
	}
	}

	void StringStream::PrintFunction(JSFunction fun, Object receiver, Code* code) {
	PrintPrototype(fun, receiver);
	*code = fun.code();
	}

	void StringStream::PrintPrototype(JSFunction fun, Object receiver) {
	Object name = fun.shared().Name();
	bool print_name = false;
	Isolate* isolate = fun.GetIsolate();
	if (receiver.IsNullOrUndefined(isolate) \|\| receiver.IsTheHole(isolate) \|\|
	receiver.IsJSProxy()) {
	print_name = true;
	} else if (!isolate->context().is_null()) {
	if (!receiver.IsJSObject()) {
	receiver = receiver.GetPrototypeChainRootMap(isolate).prototype();
	}

	for (PrototypeIterator iter(isolate, JSObject::cast(receiver),
	kStartAtReceiver);
	!iter.IsAtEnd(); iter.Advance()) {
	if (iter.GetCurrent().IsJSProxy()) break;
	Object key = iter.GetCurrent<JSObject>().SlowReverseLookup(fun);
	if (!key.IsUndefined(isolate)) {
	if (!name.IsString() \|\| !key.IsString() \|\|
	!String::cast(name).Equals(String::cast(key))) {
	print_name = true;
	}
	if (name.IsString() && String::cast(name).length() == 0) {
	print_name = false;
	}
	name = key;
	break;
	}
	}
	}
	PrintName(name);
	// Also known as - if the name in the function doesn't match the name under
	// which it was looked up.
	if (print_name) {
	Add("(aka ");
	PrintName(fun.shared().Name());
	Put(')');
	}
	}

	char* HeapStringAllocator::grow(unsigned* bytes) {
	unsigned new_bytes = bytes 2;
	// Check for overflow.
	if (new_bytes <= *bytes) {
	return space_;
	}
	char* new_space = NewArray<char>(new_bytes);
	if (new_space == nullptr) {
	return space_;
	}
	MemCopy(new_space, space_, *bytes);
	*bytes = new_bytes;
	DeleteArray(space_);
	space_ = new_space;
	return new_space;
	}

	} // namespace internal
	} // namespace v8