/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "mozilla/double-conversion.h" #include "mozilla/MemoryReporting.h" using double_conversion::DoubleToStringConverter; #ifdef XPCOM_STRING_CONSTRUCTOR_OUT_OF_LINE nsTSubstring_CharT::nsTSubstring_CharT(char_type* aData, size_type aLength, uint32_t aFlags) : mData(aData), mLength(aLength), mFlags(aFlags) { if (aFlags & F_OWNED) { STRING_STAT_INCREMENT(Adopt); MOZ_LOG_CTOR(mData, "StringAdopt", 1); } } #endif /* XPCOM_STRING_CONSTRUCTOR_OUT_OF_LINE */ /** * helper function for down-casting a nsTSubstring to a nsTFixedString. */ inline const nsTFixedString_CharT* AsFixedString(const nsTSubstring_CharT* aStr) { return static_cast(aStr); } /** * this function is called to prepare mData for writing. the given capacity * indicates the required minimum storage size for mData, in sizeof(char_type) * increments. this function returns true if the operation succeeds. it also * returns the old data and old flags members if mData is newly allocated. * the old data must be released by the caller. */ bool nsTSubstring_CharT::MutatePrep(size_type aCapacity, char_type** aOldData, uint32_t* aOldFlags) { // initialize to no old data *aOldData = nullptr; *aOldFlags = 0; size_type curCapacity = Capacity(); // If |aCapacity > kMaxCapacity|, then our doubling algorithm may not be // able to allocate it. Just bail out in cases like that. We don't want // to be allocating 2GB+ strings anyway. static_assert((sizeof(nsStringBuffer) & 0x1) == 0, "bad size for nsStringBuffer"); const size_type kMaxCapacity = (size_type(-1) / 2 - sizeof(nsStringBuffer)) / sizeof(char_type) - 2; if (aCapacity > kMaxCapacity) { // Also assert for |aCapacity| equal to |size_type(-1)|, since we used to // use that value to flag immutability. NS_ASSERTION(aCapacity != size_type(-1), "Bogus capacity"); return false; } // |curCapacity == 0| means that the buffer is immutable or 0-sized, so we // need to allocate a new buffer. We cannot use the existing buffer even // though it might be large enough. if (curCapacity != 0) { if (aCapacity <= curCapacity) { mFlags &= ~F_VOIDED; // mutation clears voided flag return true; } // Use doubling algorithm when forced to increase available capacity. size_type temp = curCapacity; while (temp < aCapacity) { temp <<= 1; } NS_ASSERTION(XPCOM_MIN(temp, kMaxCapacity) >= aCapacity, "should have hit the early return at the top"); aCapacity = XPCOM_MIN(temp, kMaxCapacity); } // // several cases: // // (1) we have a shared buffer (mFlags & F_SHARED) // (2) we have an owned buffer (mFlags & F_OWNED) // (3) we have a fixed buffer (mFlags & F_FIXED) // (4) we have a readonly buffer // // requiring that we in some cases preserve the data before creating // a new buffer complicates things just a bit ;-) // size_type storageSize = (aCapacity + 1) * sizeof(char_type); // case #1 if (mFlags & F_SHARED) { nsStringBuffer* hdr = nsStringBuffer::FromData(mData); if (!hdr->IsReadonly()) { nsStringBuffer* newHdr = nsStringBuffer::Realloc(hdr, storageSize); if (!newHdr) { return false; // out-of-memory (original header left intact) } hdr = newHdr; mData = (char_type*)hdr->Data(); mFlags &= ~F_VOIDED; // mutation clears voided flag return true; } } char_type* newData; uint32_t newDataFlags; // if we have a fixed buffer of sufficient size, then use it. this helps // avoid heap allocations. if ((mFlags & F_CLASS_FIXED) && (aCapacity < AsFixedString(this)->mFixedCapacity)) { newData = AsFixedString(this)->mFixedBuf; newDataFlags = F_TERMINATED | F_FIXED; } else { // if we reach here then, we must allocate a new buffer. we cannot // make use of our F_OWNED or F_FIXED buffers because they are not // large enough. nsStringBuffer* newHdr = nsStringBuffer::Alloc(storageSize).take(); if (!newHdr) { return false; // we are still in a consistent state } newData = (char_type*)newHdr->Data(); newDataFlags = F_TERMINATED | F_SHARED; } // save old data and flags *aOldData = mData; *aOldFlags = mFlags; mData = newData; SetDataFlags(newDataFlags); // mLength does not change // though we are not necessarily terminated at the moment, now is probably // still the best time to set F_TERMINATED. return true; } void nsTSubstring_CharT::Finalize() { ::ReleaseData(mData, mFlags); // mData, mLength, and mFlags are purposefully left dangling } bool nsTSubstring_CharT::ReplacePrepInternal(index_type aCutStart, size_type aCutLen, size_type aFragLen, size_type aNewLen) { char_type* oldData; uint32_t oldFlags; if (!MutatePrep(aNewLen, &oldData, &oldFlags)) { return false; // out-of-memory } if (oldData) { // determine whether or not we need to copy part of the old string // over to the new string. if (aCutStart > 0) { // copy prefix from old string char_traits::copy(mData, oldData, aCutStart); } if (aCutStart + aCutLen < mLength) { // copy suffix from old string to new offset size_type from = aCutStart + aCutLen; size_type fromLen = mLength - from; uint32_t to = aCutStart + aFragLen; char_traits::copy(mData + to, oldData + from, fromLen); } ::ReleaseData(oldData, oldFlags); } else { // original data remains intact // determine whether or not we need to move part of the existing string // to make room for the requested hole. if (aFragLen != aCutLen && aCutStart + aCutLen < mLength) { uint32_t from = aCutStart + aCutLen; uint32_t fromLen = mLength - from; uint32_t to = aCutStart + aFragLen; char_traits::move(mData + to, mData + from, fromLen); } } // add null terminator (mutable mData always has room for the null- // terminator). mData[aNewLen] = char_type(0); mLength = aNewLen; return true; } nsTSubstring_CharT::size_type nsTSubstring_CharT::Capacity() const { // return 0 to indicate an immutable or 0-sized buffer size_type capacity; if (mFlags & F_SHARED) { // if the string is readonly, then we pretend that it has no capacity. nsStringBuffer* hdr = nsStringBuffer::FromData(mData); if (hdr->IsReadonly()) { capacity = 0; } else { capacity = (hdr->StorageSize() / sizeof(char_type)) - 1; } } else if (mFlags & F_FIXED) { capacity = AsFixedString(this)->mFixedCapacity; } else if (mFlags & F_OWNED) { // we don't store the capacity of an adopted buffer because that would // require an additional member field. the best we can do is base the // capacity on our length. remains to be seen if this is the right // trade-off. capacity = mLength; } else { capacity = 0; } return capacity; } bool nsTSubstring_CharT::EnsureMutable(size_type aNewLen) { if (aNewLen == size_type(-1) || aNewLen == mLength) { if (mFlags & (F_FIXED | F_OWNED)) { return true; } if ((mFlags & F_SHARED) && !nsStringBuffer::FromData(mData)->IsReadonly()) { return true; } aNewLen = mLength; } return SetLength(aNewLen, mozilla::fallible); } // --------------------------------------------------------------------------- // This version of Assign is optimized for single-character assignment. void nsTSubstring_CharT::Assign(char_type aChar) { if (!ReplacePrep(0, mLength, 1)) { AllocFailed(mLength); } *mData = aChar; } bool nsTSubstring_CharT::Assign(char_type aChar, const fallible_t&) { if (!ReplacePrep(0, mLength, 1)) { return false; } *mData = aChar; return true; } void nsTSubstring_CharT::Assign(const char_type* aData) { if (!Assign(aData, size_type(-1), mozilla::fallible)) { AllocFailed(char_traits::length(aData)); } } void nsTSubstring_CharT::Assign(const char_type* aData, size_type aLength) { if (!Assign(aData, aLength, mozilla::fallible)) { AllocFailed(aLength == size_type(-1) ? char_traits::length(aData) : aLength); } } bool nsTSubstring_CharT::Assign(const char_type* aData, size_type aLength, const fallible_t& aFallible) { if (!aData || aLength == 0) { Truncate(); return true; } if (aLength == size_type(-1)) { aLength = char_traits::length(aData); } if (IsDependentOn(aData, aData + aLength)) { return Assign(string_type(aData, aLength), aFallible); } if (!ReplacePrep(0, mLength, aLength)) { return false; } char_traits::copy(mData, aData, aLength); return true; } void nsTSubstring_CharT::AssignASCII(const char* aData, size_type aLength) { if (!AssignASCII(aData, aLength, mozilla::fallible)) { AllocFailed(aLength); } } bool nsTSubstring_CharT::AssignASCII(const char* aData, size_type aLength, const fallible_t& aFallible) { // A Unicode string can't depend on an ASCII string buffer, // so this dependence check only applies to CStrings. #ifdef CharT_is_char if (IsDependentOn(aData, aData + aLength)) { return Assign(string_type(aData, aLength), aFallible); } #endif if (!ReplacePrep(0, mLength, aLength)) { return false; } char_traits::copyASCII(mData, aData, aLength); return true; } void nsTSubstring_CharT::AssignLiteral(const char_type* aData, size_type aLength) { ::ReleaseData(mData, mFlags); mData = const_cast(aData); mLength = aLength; SetDataFlags(F_TERMINATED | F_LITERAL); } void nsTSubstring_CharT::Assign(const self_type& aStr) { if (!Assign(aStr, mozilla::fallible)) { AllocFailed(aStr.Length()); } } bool nsTSubstring_CharT::Assign(const self_type& aStr, const fallible_t& aFallible) { // |aStr| could be sharable. We need to check its flags to know how to // deal with it. if (&aStr == this) { return true; } if (!aStr.mLength) { Truncate(); mFlags |= aStr.mFlags & F_VOIDED; return true; } if (aStr.mFlags & F_SHARED) { // nice! we can avoid a string copy :-) // |aStr| should be null-terminated NS_ASSERTION(aStr.mFlags & F_TERMINATED, "shared, but not terminated"); ::ReleaseData(mData, mFlags); mData = aStr.mData; mLength = aStr.mLength; SetDataFlags(F_TERMINATED | F_SHARED); // get an owning reference to the mData nsStringBuffer::FromData(mData)->AddRef(); return true; } else if (aStr.mFlags & F_LITERAL) { MOZ_ASSERT(aStr.mFlags & F_TERMINATED, "Unterminated literal"); AssignLiteral(aStr.mData, aStr.mLength); return true; } // else, treat this like an ordinary assignment. return Assign(aStr.Data(), aStr.Length(), aFallible); } void nsTSubstring_CharT::Assign(const substring_tuple_type& aTuple) { if (!Assign(aTuple, mozilla::fallible)) { AllocFailed(aTuple.Length()); } } bool nsTSubstring_CharT::Assign(const substring_tuple_type& aTuple, const fallible_t& aFallible) { if (aTuple.IsDependentOn(mData, mData + mLength)) { // take advantage of sharing here... return Assign(string_type(aTuple), aFallible); } size_type length = aTuple.Length(); // don't use ReplacePrep here because it changes the length char_type* oldData; uint32_t oldFlags; if (!MutatePrep(length, &oldData, &oldFlags)) { return false; } if (oldData) { ::ReleaseData(oldData, oldFlags); } aTuple.WriteTo(mData, length); mData[length] = 0; mLength = length; return true; } void nsTSubstring_CharT::Adopt(char_type* aData, size_type aLength) { if (aData) { ::ReleaseData(mData, mFlags); if (aLength == size_type(-1)) { aLength = char_traits::length(aData); } mData = aData; mLength = aLength; SetDataFlags(F_TERMINATED | F_OWNED); STRING_STAT_INCREMENT(Adopt); // Treat this as construction of a "StringAdopt" object for leak // tracking purposes. MOZ_LOG_CTOR(mData, "StringAdopt", 1); } else { SetIsVoid(true); } } // This version of Replace is optimized for single-character replacement. void nsTSubstring_CharT::Replace(index_type aCutStart, size_type aCutLength, char_type aChar) { aCutStart = XPCOM_MIN(aCutStart, Length()); if (ReplacePrep(aCutStart, aCutLength, 1)) { mData[aCutStart] = aChar; } } bool nsTSubstring_CharT::Replace(index_type aCutStart, size_type aCutLength, char_type aChar, const fallible_t&) { aCutStart = XPCOM_MIN(aCutStart, Length()); if (!ReplacePrep(aCutStart, aCutLength, 1)) { return false; } mData[aCutStart] = aChar; return true; } void nsTSubstring_CharT::Replace(index_type aCutStart, size_type aCutLength, const char_type* aData, size_type aLength) { if (!Replace(aCutStart, aCutLength, aData, aLength, mozilla::fallible)) { AllocFailed(Length() - aCutLength + 1); } } bool nsTSubstring_CharT::Replace(index_type aCutStart, size_type aCutLength, const char_type* aData, size_type aLength, const fallible_t& aFallible) { // unfortunately, some callers pass null :-( if (!aData) { aLength = 0; } else { if (aLength == size_type(-1)) { aLength = char_traits::length(aData); } if (IsDependentOn(aData, aData + aLength)) { nsTAutoString_CharT temp(aData, aLength); return Replace(aCutStart, aCutLength, temp, aFallible); } } aCutStart = XPCOM_MIN(aCutStart, Length()); bool ok = ReplacePrep(aCutStart, aCutLength, aLength); if (!ok) { return false; } if (aLength > 0) { char_traits::copy(mData + aCutStart, aData, aLength); } return true; } void nsTSubstring_CharT::ReplaceASCII(index_type aCutStart, size_type aCutLength, const char* aData, size_type aLength) { if (!ReplaceASCII(aCutStart, aCutLength, aData, aLength, mozilla::fallible)) { AllocFailed(Length() - aCutLength + 1); } } bool nsTSubstring_CharT::ReplaceASCII(index_type aCutStart, size_type aCutLength, const char* aData, size_type aLength, const fallible_t& aFallible) { if (aLength == size_type(-1)) { aLength = strlen(aData); } // A Unicode string can't depend on an ASCII string buffer, // so this dependence check only applies to CStrings. #ifdef CharT_is_char if (IsDependentOn(aData, aData + aLength)) { nsTAutoString_CharT temp(aData, aLength); return Replace(aCutStart, aCutLength, temp, aFallible); } #endif aCutStart = XPCOM_MIN(aCutStart, Length()); bool ok = ReplacePrep(aCutStart, aCutLength, aLength); if (!ok) { return false; } if (aLength > 0) { char_traits::copyASCII(mData + aCutStart, aData, aLength); } return true; } void nsTSubstring_CharT::Replace(index_type aCutStart, size_type aCutLength, const substring_tuple_type& aTuple) { if (aTuple.IsDependentOn(mData, mData + mLength)) { nsTAutoString_CharT temp(aTuple); Replace(aCutStart, aCutLength, temp); return; } size_type length = aTuple.Length(); aCutStart = XPCOM_MIN(aCutStart, Length()); if (ReplacePrep(aCutStart, aCutLength, length) && length > 0) { aTuple.WriteTo(mData + aCutStart, length); } } void nsTSubstring_CharT::ReplaceLiteral(index_type aCutStart, size_type aCutLength, const char_type* aData, size_type aLength) { aCutStart = XPCOM_MIN(aCutStart, Length()); if (!aCutStart && aCutLength == Length()) { AssignLiteral(aData, aLength); } else if (ReplacePrep(aCutStart, aCutLength, aLength) && aLength > 0) { char_traits::copy(mData + aCutStart, aData, aLength); } } void nsTSubstring_CharT::SetCapacity(size_type aCapacity) { if (!SetCapacity(aCapacity, mozilla::fallible)) { AllocFailed(aCapacity); } } bool nsTSubstring_CharT::SetCapacity(size_type aCapacity, const fallible_t&) { // capacity does not include room for the terminating null char // if our capacity is reduced to zero, then free our buffer. if (aCapacity == 0) { ::ReleaseData(mData, mFlags); mData = char_traits::sEmptyBuffer; mLength = 0; SetDataFlags(F_TERMINATED); return true; } char_type* oldData; uint32_t oldFlags; if (!MutatePrep(aCapacity, &oldData, &oldFlags)) { return false; // out-of-memory } // compute new string length size_type newLen = XPCOM_MIN(mLength, aCapacity); if (oldData) { // preserve old data if (mLength > 0) { char_traits::copy(mData, oldData, newLen); } ::ReleaseData(oldData, oldFlags); } // adjust mLength if our buffer shrunk down in size if (newLen < mLength) { mLength = newLen; } // always null-terminate here, even if the buffer got longer. this is // for backwards compat with the old string implementation. mData[aCapacity] = char_type(0); return true; } void nsTSubstring_CharT::SetLength(size_type aLength) { SetCapacity(aLength); mLength = aLength; } bool nsTSubstring_CharT::SetLength(size_type aLength, const fallible_t& aFallible) { if (!SetCapacity(aLength, aFallible)) { return false; } mLength = aLength; return true; } void nsTSubstring_CharT::SetIsVoid(bool aVal) { if (aVal) { Truncate(); mFlags |= F_VOIDED; } else { mFlags &= ~F_VOIDED; } } bool nsTSubstring_CharT::Equals(const self_type& aStr) const { return mLength == aStr.mLength && char_traits::compare(mData, aStr.mData, mLength) == 0; } bool nsTSubstring_CharT::Equals(const self_type& aStr, const comparator_type& aComp) const { return mLength == aStr.mLength && aComp(mData, aStr.mData, mLength, aStr.mLength) == 0; } bool nsTSubstring_CharT::Equals(const char_type* aData) const { // unfortunately, some callers pass null :-( if (!aData) { NS_NOTREACHED("null data pointer"); return mLength == 0; } // XXX avoid length calculation? size_type length = char_traits::length(aData); return mLength == length && char_traits::compare(mData, aData, mLength) == 0; } bool nsTSubstring_CharT::Equals(const char_type* aData, const comparator_type& aComp) const { // unfortunately, some callers pass null :-( if (!aData) { NS_NOTREACHED("null data pointer"); return mLength == 0; } // XXX avoid length calculation? size_type length = char_traits::length(aData); return mLength == length && aComp(mData, aData, mLength, length) == 0; } bool nsTSubstring_CharT::EqualsASCII(const char* aData, size_type aLen) const { return mLength == aLen && char_traits::compareASCII(mData, aData, aLen) == 0; } bool nsTSubstring_CharT::EqualsASCII(const char* aData) const { return char_traits::compareASCIINullTerminated(mData, mLength, aData) == 0; } bool nsTSubstring_CharT::LowerCaseEqualsASCII(const char* aData, size_type aLen) const { return mLength == aLen && char_traits::compareLowerCaseToASCII(mData, aData, aLen) == 0; } bool nsTSubstring_CharT::LowerCaseEqualsASCII(const char* aData) const { return char_traits::compareLowerCaseToASCIINullTerminated(mData, mLength, aData) == 0; } nsTSubstring_CharT::size_type nsTSubstring_CharT::CountChar(char_type aChar) const { const char_type* start = mData; const char_type* end = mData + mLength; return NS_COUNT(start, end, aChar); } int32_t nsTSubstring_CharT::FindChar(char_type aChar, index_type aOffset) const { if (aOffset < mLength) { const char_type* result = char_traits::find(mData + aOffset, mLength - aOffset, aChar); if (result) { return result - mData; } } return -1; } void nsTSubstring_CharT::StripChar(char_type aChar, int32_t aOffset) { if (mLength == 0 || aOffset >= int32_t(mLength)) { return; } if (!EnsureMutable()) { // XXX do this lazily? AllocFailed(mLength); } // XXX(darin): this code should defer writing until necessary. char_type* to = mData + aOffset; char_type* from = mData + aOffset; char_type* end = mData + mLength; while (from < end) { char_type theChar = *from++; if (aChar != theChar) { *to++ = theChar; } } *to = char_type(0); // add the null mLength = to - mData; } void nsTSubstring_CharT::StripChars(const char_type* aChars, uint32_t aOffset) { if (aOffset >= uint32_t(mLength)) { return; } if (!EnsureMutable()) { // XXX do this lazily? AllocFailed(mLength); } // XXX(darin): this code should defer writing until necessary. char_type* to = mData + aOffset; char_type* from = mData + aOffset; char_type* end = mData + mLength; while (from < end) { char_type theChar = *from++; const char_type* test = aChars; for (; *test && *test != theChar; ++test); if (!*test) { // Not stripped, copy this char. *to++ = theChar; } } *to = char_type(0); // add the null mLength = to - mData; } int nsTSubstring_CharT::AppendFunc(void* aArg, const char* aStr, uint32_t aLen) { self_type* self = static_cast(aArg); // NSPR sends us the final null terminator even though we don't want it if (aLen && aStr[aLen - 1] == '\0') { --aLen; } self->AppendASCII(aStr, aLen); return aLen; } void nsTSubstring_CharT::AppendPrintf(const char* aFormat, ...) { va_list ap; va_start(ap, aFormat); uint32_t r = PR_vsxprintf(AppendFunc, this, aFormat, ap); if (r == (uint32_t)-1) { NS_RUNTIMEABORT("Allocation or other failure in PR_vsxprintf"); } va_end(ap); } void nsTSubstring_CharT::AppendPrintf(const char* aFormat, va_list aAp) { uint32_t r = PR_vsxprintf(AppendFunc, this, aFormat, aAp); if (r == (uint32_t)-1) { NS_RUNTIMEABORT("Allocation or other failure in PR_vsxprintf"); } } /* hack to make sure we define FormatWithoutTrailingZeros only once */ #ifdef CharT_is_PRUnichar // Returns the length of the formatted aDouble in aBuf. static int FormatWithoutTrailingZeros(char (&aBuf)[40], double aDouble, int aPrecision) { static const DoubleToStringConverter converter(DoubleToStringConverter::UNIQUE_ZERO | DoubleToStringConverter::EMIT_POSITIVE_EXPONENT_SIGN, "Infinity", "NaN", 'e', -6, 21, 6, 1); double_conversion::StringBuilder builder(aBuf, sizeof(aBuf)); bool exponential_notation = false; converter.ToPrecision(aDouble, aPrecision, &exponential_notation, &builder); int length = builder.position(); char* formattedDouble = builder.Finalize(); // If we have a shorter string than aPrecision, it means we have a special // value (NaN or Infinity). All other numbers will be formatted with at // least aPrecision digits. if (length <= aPrecision) { return length; } char* end = formattedDouble + length; char* decimalPoint = strchr(aBuf, '.'); // No trailing zeros to remove. if (!decimalPoint) { return length; } if (MOZ_UNLIKELY(exponential_notation)) { // We need to check for cases like 1.00000e-10 (yes, this is // disgusting). char* exponent = end - 1; for (; ; --exponent) { if (*exponent == 'e') { break; } } char* zerosBeforeExponent = exponent - 1; for (; zerosBeforeExponent != decimalPoint; --zerosBeforeExponent) { if (*zerosBeforeExponent != '0') { break; } } if (zerosBeforeExponent == decimalPoint) { --zerosBeforeExponent; } // Slide the exponent to the left over the trailing zeros. Don't // worry about copying the trailing NUL character. size_t exponentSize = end - exponent; memmove(zerosBeforeExponent + 1, exponent, exponentSize); length -= exponent - (zerosBeforeExponent + 1); } else { char* trailingZeros = end - 1; for (; trailingZeros != decimalPoint; --trailingZeros) { if (*trailingZeros != '0') { break; } } if (trailingZeros == decimalPoint) { --trailingZeros; } length -= end - (trailingZeros + 1); } return length; } #endif /* CharT_is_PRUnichar */ void nsTSubstring_CharT::AppendFloat(float aFloat) { char buf[40]; int length = FormatWithoutTrailingZeros(buf, aFloat, 6); AppendASCII(buf, length); } void nsTSubstring_CharT::AppendFloat(double aFloat) { char buf[40]; int length = FormatWithoutTrailingZeros(buf, aFloat, 15); AppendASCII(buf, length); } size_t nsTSubstring_CharT::SizeOfExcludingThisMustBeUnshared( mozilla::MallocSizeOf aMallocSizeOf) const { if (mFlags & F_SHARED) { return nsStringBuffer::FromData(mData)-> SizeOfIncludingThisMustBeUnshared(aMallocSizeOf); } if (mFlags & F_OWNED) { return aMallocSizeOf(mData); } // If we reach here, exactly one of the following must be true: // - F_VOIDED is set, and mData points to sEmptyBuffer; // - F_FIXED is set, and mData points to a buffer within a string // object (e.g. nsAutoString); // - None of F_SHARED, F_OWNED, F_FIXED is set, and mData points to a buffer // owned by something else. // // In all three cases, we don't measure it. return 0; } size_t nsTSubstring_CharT::SizeOfExcludingThisIfUnshared( mozilla::MallocSizeOf aMallocSizeOf) const { // This is identical to SizeOfExcludingThisMustBeUnshared except for the // F_SHARED case. if (mFlags & F_SHARED) { return nsStringBuffer::FromData(mData)-> SizeOfIncludingThisIfUnshared(aMallocSizeOf); } if (mFlags & F_OWNED) { return aMallocSizeOf(mData); } return 0; } size_t nsTSubstring_CharT::SizeOfExcludingThisEvenIfShared( mozilla::MallocSizeOf aMallocSizeOf) const { // This is identical to SizeOfExcludingThisMustBeUnshared except for the // F_SHARED case. if (mFlags & F_SHARED) { return nsStringBuffer::FromData(mData)-> SizeOfIncludingThisEvenIfShared(aMallocSizeOf); } if (mFlags & F_OWNED) { return aMallocSizeOf(mData); } return 0; } size_t nsTSubstring_CharT::SizeOfIncludingThisMustBeUnshared( mozilla::MallocSizeOf aMallocSizeOf) const { return aMallocSizeOf(this) + SizeOfExcludingThisMustBeUnshared(aMallocSizeOf); } size_t nsTSubstring_CharT::SizeOfIncludingThisIfUnshared( mozilla::MallocSizeOf aMallocSizeOf) const { return aMallocSizeOf(this) + SizeOfExcludingThisIfUnshared(aMallocSizeOf); } size_t nsTSubstring_CharT::SizeOfIncludingThisEvenIfShared( mozilla::MallocSizeOf aMallocSizeOf) const { return aMallocSizeOf(this) + SizeOfExcludingThisEvenIfShared(aMallocSizeOf); }