gecko/dom/base/nsXMLContentSerializer.cpp
Ehsan Akhgari 5ae69b5469 Bug 1113238 - Part 2: Only maintain the pre level status which can be potentially expensive if we may end up using it; r=bzbarsky
This patch ensures that we check ShouldMaintainPreLevel() before attempting
to modify or read mPreLevel in order to avoid wasting time to compute
mPreLevel for elements without frames needlessly.  Computing this value for
such elements can incur expensive style calculations.
2015-01-16 15:56:46 -05:00

1723 lines
51 KiB
C++

/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* 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/. */
/*
* nsIContentSerializer implementation that can be used with an
* nsIDocumentEncoder to convert an XML DOM to an XML string that
* could be parsed into more or less the original DOM.
*/
#include "nsXMLContentSerializer.h"
#include "nsGkAtoms.h"
#include "nsIDOMProcessingInstruction.h"
#include "nsIDOMComment.h"
#include "nsIDOMDocumentType.h"
#include "nsIContent.h"
#include "nsIDocument.h"
#include "nsIDocumentEncoder.h"
#include "nsNameSpaceManager.h"
#include "nsTextFragment.h"
#include "nsString.h"
#include "prprf.h"
#include "nsUnicharUtils.h"
#include "nsCRT.h"
#include "nsContentUtils.h"
#include "nsAttrName.h"
#include "nsILineBreaker.h"
#include "mozilla/dom/Element.h"
#include "nsParserConstants.h"
using namespace mozilla::dom;
#define kXMLNS "xmlns"
// to be readable, we assume that an indented line contains
// at least this number of characters (arbitrary value here).
// This is a limit for the indentation.
#define MIN_INDENTED_LINE_LENGTH 15
// the string used to indent.
#define INDENT_STRING " "
#define INDENT_STRING_LENGTH 2
nsresult NS_NewXMLContentSerializer(nsIContentSerializer** aSerializer)
{
nsXMLContentSerializer* it = new nsXMLContentSerializer();
if (!it) {
return NS_ERROR_OUT_OF_MEMORY;
}
return CallQueryInterface(it, aSerializer);
}
nsXMLContentSerializer::nsXMLContentSerializer()
: mPrefixIndex(0),
mColPos(0),
mIndentOverflow(0),
mIsIndentationAddedOnCurrentLine(false),
mInAttribute(false),
mAddNewlineForRootNode(false),
mAddSpace(false),
mMayIgnoreLineBreakSequence(false),
mBodyOnly(false),
mInBody(0)
{
}
nsXMLContentSerializer::~nsXMLContentSerializer()
{
}
NS_IMPL_ISUPPORTS(nsXMLContentSerializer, nsIContentSerializer)
NS_IMETHODIMP
nsXMLContentSerializer::Init(uint32_t aFlags, uint32_t aWrapColumn,
const char* aCharSet, bool aIsCopying,
bool aRewriteEncodingDeclaration)
{
mPrefixIndex = 0;
mColPos = 0;
mIndentOverflow = 0;
mIsIndentationAddedOnCurrentLine = false;
mInAttribute = false;
mAddNewlineForRootNode = false;
mAddSpace = false;
mMayIgnoreLineBreakSequence = false;
mBodyOnly = false;
mInBody = 0;
mCharset = aCharSet;
mFlags = aFlags;
// Set the line break character:
if ((mFlags & nsIDocumentEncoder::OutputCRLineBreak)
&& (mFlags & nsIDocumentEncoder::OutputLFLineBreak)) { // Windows
mLineBreak.AssignLiteral("\r\n");
}
else if (mFlags & nsIDocumentEncoder::OutputCRLineBreak) { // Mac
mLineBreak.Assign('\r');
}
else if (mFlags & nsIDocumentEncoder::OutputLFLineBreak) { // Unix/DOM
mLineBreak.Assign('\n');
}
else {
mLineBreak.AssignLiteral(NS_LINEBREAK); // Platform/default
}
mDoRaw = !!(mFlags & nsIDocumentEncoder::OutputRaw);
mDoFormat = (mFlags & nsIDocumentEncoder::OutputFormatted && !mDoRaw);
mDoWrap = (mFlags & nsIDocumentEncoder::OutputWrap && !mDoRaw);
if (!aWrapColumn) {
mMaxColumn = 72;
}
else {
mMaxColumn = aWrapColumn;
}
mPreLevel = 0;
mIsIndentationAddedOnCurrentLine = false;
return NS_OK;
}
nsresult
nsXMLContentSerializer::AppendTextData(nsIContent* aNode,
int32_t aStartOffset,
int32_t aEndOffset,
nsAString& aStr,
bool aTranslateEntities)
{
nsIContent* content = aNode;
const nsTextFragment* frag;
if (!content || !(frag = content->GetText())) {
return NS_ERROR_FAILURE;
}
int32_t fragLength = frag->GetLength();
int32_t endoffset = (aEndOffset == -1) ? fragLength : std::min(aEndOffset, fragLength);
int32_t length = endoffset - aStartOffset;
NS_ASSERTION(aStartOffset >= 0, "Negative start offset for text fragment!");
NS_ASSERTION(aStartOffset <= endoffset, "A start offset is beyond the end of the text fragment!");
if (length <= 0) {
// XXX Zero is a legal value, maybe non-zero values should be an
// error.
return NS_OK;
}
if (frag->Is2b()) {
const char16_t *strStart = frag->Get2b() + aStartOffset;
if (aTranslateEntities) {
AppendAndTranslateEntities(Substring(strStart, strStart + length), aStr);
}
else {
aStr.Append(Substring(strStart, strStart + length));
}
}
else {
if (aTranslateEntities) {
AppendAndTranslateEntities(NS_ConvertASCIItoUTF16(frag->Get1b()+aStartOffset, length), aStr);
}
else {
aStr.Append(NS_ConvertASCIItoUTF16(frag->Get1b()+aStartOffset, length));
}
}
return NS_OK;
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendText(nsIContent* aText,
int32_t aStartOffset,
int32_t aEndOffset,
nsAString& aStr)
{
NS_ENSURE_ARG(aText);
nsAutoString data;
nsresult rv;
rv = AppendTextData(aText, aStartOffset, aEndOffset, data, true);
if (NS_FAILED(rv))
return NS_ERROR_FAILURE;
if (mDoRaw || PreLevel() > 0) {
AppendToStringConvertLF(data, aStr);
}
else if (mDoFormat) {
AppendToStringFormatedWrapped(data, aStr);
}
else if (mDoWrap) {
AppendToStringWrapped(data, aStr);
}
else {
AppendToStringConvertLF(data, aStr);
}
return NS_OK;
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendCDATASection(nsIContent* aCDATASection,
int32_t aStartOffset,
int32_t aEndOffset,
nsAString& aStr)
{
NS_ENSURE_ARG(aCDATASection);
nsresult rv;
NS_NAMED_LITERAL_STRING(cdata , "<![CDATA[");
if (mDoRaw || PreLevel() > 0) {
AppendToString(cdata, aStr);
}
else if (mDoFormat) {
AppendToStringFormatedWrapped(cdata, aStr);
}
else if (mDoWrap) {
AppendToStringWrapped(cdata, aStr);
}
else {
AppendToString(cdata, aStr);
}
nsAutoString data;
rv = AppendTextData(aCDATASection, aStartOffset, aEndOffset, data, false);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
AppendToStringConvertLF(data, aStr);
AppendToString(NS_LITERAL_STRING("]]>"), aStr);
return NS_OK;
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendProcessingInstruction(nsIContent* aPI,
int32_t aStartOffset,
int32_t aEndOffset,
nsAString& aStr)
{
nsCOMPtr<nsIDOMProcessingInstruction> pi = do_QueryInterface(aPI);
NS_ENSURE_ARG(pi);
nsresult rv;
nsAutoString target, data, start;
MaybeAddNewlineForRootNode(aStr);
rv = pi->GetTarget(target);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
rv = pi->GetData(data);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
start.AppendLiteral("<?");
start.Append(target);
if (mDoRaw || PreLevel() > 0) {
AppendToString(start, aStr);
}
else if (mDoFormat) {
if (mAddSpace) {
AppendNewLineToString(aStr);
}
AppendToStringFormatedWrapped(start, aStr);
}
else if (mDoWrap) {
AppendToStringWrapped(start, aStr);
}
else {
AppendToString(start, aStr);
}
if (!data.IsEmpty()) {
AppendToString(char16_t(' '), aStr);
AppendToStringConvertLF(data, aStr);
}
AppendToString(NS_LITERAL_STRING("?>"), aStr);
MaybeFlagNewlineForRootNode(aPI);
return NS_OK;
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendComment(nsIContent* aComment,
int32_t aStartOffset,
int32_t aEndOffset,
nsAString& aStr)
{
nsCOMPtr<nsIDOMComment> comment = do_QueryInterface(aComment);
NS_ENSURE_ARG(comment);
nsresult rv;
nsAutoString data;
rv = comment->GetData(data);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
int32_t dataLength = data.Length();
if (aStartOffset || (aEndOffset != -1 && aEndOffset < dataLength)) {
int32_t length =
(aEndOffset == -1) ? dataLength : std::min(aEndOffset, dataLength);
length -= aStartOffset;
nsAutoString frag;
if (length > 0) {
data.Mid(frag, aStartOffset, length);
}
data.Assign(frag);
}
MaybeAddNewlineForRootNode(aStr);
NS_NAMED_LITERAL_STRING(startComment, "<!--");
if (mDoRaw || PreLevel() > 0) {
AppendToString(startComment, aStr);
}
else if (mDoFormat) {
if (mAddSpace) {
AppendNewLineToString(aStr);
}
AppendToStringFormatedWrapped(startComment, aStr);
}
else if (mDoWrap) {
AppendToStringWrapped(startComment, aStr);
}
else {
AppendToString(startComment, aStr);
}
// Even if mDoformat, we don't format the content because it
// could have been preformated by the author
AppendToStringConvertLF(data, aStr);
AppendToString(NS_LITERAL_STRING("-->"), aStr);
MaybeFlagNewlineForRootNode(aComment);
return NS_OK;
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendDoctype(nsIContent* aDocType,
nsAString& aStr)
{
nsCOMPtr<nsIDOMDocumentType> docType = do_QueryInterface(aDocType);
NS_ENSURE_ARG(docType);
nsresult rv;
nsAutoString name, publicId, systemId, internalSubset;
rv = docType->GetName(name);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
rv = docType->GetPublicId(publicId);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
rv = docType->GetSystemId(systemId);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
rv = docType->GetInternalSubset(internalSubset);
if (NS_FAILED(rv)) return NS_ERROR_FAILURE;
MaybeAddNewlineForRootNode(aStr);
AppendToString(NS_LITERAL_STRING("<!DOCTYPE "), aStr);
AppendToString(name, aStr);
char16_t quote;
if (!publicId.IsEmpty()) {
AppendToString(NS_LITERAL_STRING(" PUBLIC "), aStr);
if (publicId.FindChar(char16_t('"')) == -1) {
quote = char16_t('"');
}
else {
quote = char16_t('\'');
}
AppendToString(quote, aStr);
AppendToString(publicId, aStr);
AppendToString(quote, aStr);
if (!systemId.IsEmpty()) {
AppendToString(char16_t(' '), aStr);
if (systemId.FindChar(char16_t('"')) == -1) {
quote = char16_t('"');
}
else {
quote = char16_t('\'');
}
AppendToString(quote, aStr);
AppendToString(systemId, aStr);
AppendToString(quote, aStr);
}
}
else if (!systemId.IsEmpty()) {
if (systemId.FindChar(char16_t('"')) == -1) {
quote = char16_t('"');
}
else {
quote = char16_t('\'');
}
AppendToString(NS_LITERAL_STRING(" SYSTEM "), aStr);
AppendToString(quote, aStr);
AppendToString(systemId, aStr);
AppendToString(quote, aStr);
}
if (!internalSubset.IsEmpty()) {
AppendToString(NS_LITERAL_STRING(" ["), aStr);
AppendToString(internalSubset, aStr);
AppendToString(char16_t(']'), aStr);
}
AppendToString(kGreaterThan, aStr);
MaybeFlagNewlineForRootNode(aDocType);
return NS_OK;
}
nsresult
nsXMLContentSerializer::PushNameSpaceDecl(const nsAString& aPrefix,
const nsAString& aURI,
nsIContent* aOwner)
{
NameSpaceDecl* decl = mNameSpaceStack.AppendElement();
if (!decl) return NS_ERROR_OUT_OF_MEMORY;
decl->mPrefix.Assign(aPrefix);
decl->mURI.Assign(aURI);
// Don't addref - this weak reference will be removed when
// we pop the stack
decl->mOwner = aOwner;
return NS_OK;
}
void
nsXMLContentSerializer::PopNameSpaceDeclsFor(nsIContent* aOwner)
{
int32_t index, count;
count = mNameSpaceStack.Length();
for (index = count - 1; index >= 0; index--) {
if (mNameSpaceStack[index].mOwner != aOwner) {
break;
}
mNameSpaceStack.RemoveElementAt(index);
}
}
bool
nsXMLContentSerializer::ConfirmPrefix(nsAString& aPrefix,
const nsAString& aURI,
nsIContent* aElement,
bool aIsAttribute)
{
if (aPrefix.EqualsLiteral(kXMLNS)) {
return false;
}
if (aURI.EqualsLiteral("http://www.w3.org/XML/1998/namespace")) {
// The prefix must be xml for this namespace. We don't need to declare it,
// so always just set the prefix to xml.
aPrefix.AssignLiteral("xml");
return false;
}
bool mustHavePrefix;
if (aIsAttribute) {
if (aURI.IsEmpty()) {
// Attribute in the null namespace. This just shouldn't have a prefix.
// And there's no need to push any namespace decls
aPrefix.Truncate();
return false;
}
// Attribute not in the null namespace -- must have a prefix
mustHavePrefix = true;
} else {
// Not an attribute, so doesn't _have_ to have a prefix
mustHavePrefix = false;
}
// Keep track of the closest prefix that's bound to aURI and whether we've
// found such a thing. closestURIMatch holds the prefix, and uriMatch
// indicates whether we actually have one.
nsAutoString closestURIMatch;
bool uriMatch = false;
// Also keep track of whether we've seen aPrefix already. If we have, that
// means that it's already bound to a URI different from aURI, so even if we
// later (so in a more outer scope) see it bound to aURI we can't reuse it.
bool haveSeenOurPrefix = false;
int32_t count = mNameSpaceStack.Length();
int32_t index = count - 1;
while (index >= 0) {
NameSpaceDecl& decl = mNameSpaceStack.ElementAt(index);
// Check if we've found a prefix match
if (aPrefix.Equals(decl.mPrefix)) {
// If the URIs match and aPrefix is not bound to any other URI, we can
// use aPrefix
if (!haveSeenOurPrefix && aURI.Equals(decl.mURI)) {
// Just use our uriMatch stuff. That will deal with an empty aPrefix
// the right way. We can break out of the loop now, though.
uriMatch = true;
closestURIMatch = aPrefix;
break;
}
haveSeenOurPrefix = true;
// If they don't, and either:
// 1) We have a prefix (so we'd be redeclaring this prefix to point to a
// different namespace) or
// 2) We're looking at an existing default namespace decl on aElement (so
// we can't create a new default namespace decl for this URI)
// then generate a new prefix. Note that we do NOT generate new prefixes
// if we happen to have aPrefix == decl->mPrefix == "" and mismatching
// URIs when |decl| doesn't have aElement as its owner. In that case we
// can simply push the new namespace URI as the default namespace for
// aElement.
if (!aPrefix.IsEmpty() || decl.mOwner == aElement) {
NS_ASSERTION(!aURI.IsEmpty(),
"Not allowed to add a xmlns attribute with an empty "
"namespace name unless it declares the default "
"namespace.");
GenerateNewPrefix(aPrefix);
// Now we need to validate our new prefix/uri combination; check it
// against the full namespace stack again. Note that just restarting
// the while loop is ok, since we haven't changed aURI, so the
// closestURIMatch and uriMatch state is not affected.
index = count - 1;
haveSeenOurPrefix = false;
continue;
}
}
// If we've found a URI match, then record the first one
if (!uriMatch && aURI.Equals(decl.mURI)) {
// Need to check that decl->mPrefix is not declared anywhere closer to
// us. If it is, we can't use it.
bool prefixOK = true;
int32_t index2;
for (index2 = count-1; index2 > index && prefixOK; --index2) {
prefixOK = (mNameSpaceStack[index2].mPrefix != decl.mPrefix);
}
if (prefixOK) {
uriMatch = true;
closestURIMatch.Assign(decl.mPrefix);
}
}
--index;
}
// At this point the following invariants hold:
// 1) The prefix in closestURIMatch is mapped to aURI in our scope if
// uriMatch is set.
// 2) There is nothing on the namespace stack that has aPrefix as the prefix
// and a _different_ URI, except for the case aPrefix.IsEmpty (and
// possible default namespaces on ancestors)
// So if uriMatch is set it's OK to use the closestURIMatch prefix. The one
// exception is when closestURIMatch is actually empty (default namespace
// decl) and we must have a prefix.
if (uriMatch && (!mustHavePrefix || !closestURIMatch.IsEmpty())) {
aPrefix.Assign(closestURIMatch);
return false;
}
if (aPrefix.IsEmpty()) {
// At this point, aPrefix is empty (which means we never had a prefix to
// start with). If we must have a prefix, just generate a new prefix and
// then send it back through the namespace stack checks to make sure it's
// OK.
if (mustHavePrefix) {
GenerateNewPrefix(aPrefix);
return ConfirmPrefix(aPrefix, aURI, aElement, aIsAttribute);
}
// One final special case. If aPrefix is empty and we never saw an empty
// prefix (default namespace decl) on the namespace stack and we're in the
// null namespace there is no reason to output an |xmlns=""| here. It just
// makes the output less readable.
if (!haveSeenOurPrefix && aURI.IsEmpty()) {
return false;
}
}
// Now just set aURI as the new default namespace URI. Indicate that we need
// to create a namespace decl for the final prefix
return true;
}
void
nsXMLContentSerializer::GenerateNewPrefix(nsAString& aPrefix)
{
aPrefix.Assign('a');
char buf[128];
PR_snprintf(buf, sizeof(buf), "%d", mPrefixIndex++);
AppendASCIItoUTF16(buf, aPrefix);
}
void
nsXMLContentSerializer::SerializeAttr(const nsAString& aPrefix,
const nsAString& aName,
const nsAString& aValue,
nsAString& aStr,
bool aDoEscapeEntities)
{
nsAutoString attrString_;
// For innerHTML we can do faster appending without
// temporary strings.
bool rawAppend = mDoRaw && aDoEscapeEntities;
nsAString& attrString = (rawAppend) ? aStr : attrString_;
attrString.Append(char16_t(' '));
if (!aPrefix.IsEmpty()) {
attrString.Append(aPrefix);
attrString.Append(char16_t(':'));
}
attrString.Append(aName);
if (aDoEscapeEntities) {
// if problem characters are turned into character entity references
// then there will be no problem with the value delimiter characters
attrString.AppendLiteral("=\"");
mInAttribute = true;
AppendAndTranslateEntities(aValue, attrString);
mInAttribute = false;
attrString.Append(char16_t('"'));
if (rawAppend) {
return;
}
}
else {
// Depending on whether the attribute value contains quotes or apostrophes we
// need to select the delimiter character and escape characters using
// character entity references, ignoring the value of aDoEscapeEntities.
// See http://www.w3.org/TR/REC-html40/appendix/notes.html#h-B.3.2.2 for
// the standard on character entity references in values. We also have to
// make sure to escape any '&' characters.
bool bIncludesSingle = false;
bool bIncludesDouble = false;
nsAString::const_iterator iCurr, iEnd;
uint32_t uiSize, i;
aValue.BeginReading(iCurr);
aValue.EndReading(iEnd);
for ( ; iCurr != iEnd; iCurr.advance(uiSize) ) {
const char16_t * buf = iCurr.get();
uiSize = iCurr.size_forward();
for ( i = 0; i < uiSize; i++, buf++ ) {
if ( *buf == char16_t('\'') )
{
bIncludesSingle = true;
if ( bIncludesDouble ) break;
}
else if ( *buf == char16_t('"') )
{
bIncludesDouble = true;
if ( bIncludesSingle ) break;
}
}
// if both have been found we don't need to search further
if ( bIncludesDouble && bIncludesSingle ) break;
}
// Delimiter and escaping is according to the following table
// bIncludesDouble bIncludesSingle Delimiter Escape Double Quote
// FALSE FALSE " FALSE
// FALSE TRUE " FALSE
// TRUE FALSE ' FALSE
// TRUE TRUE " TRUE
char16_t cDelimiter =
(bIncludesDouble && !bIncludesSingle) ? char16_t('\'') : char16_t('"');
attrString.Append(char16_t('='));
attrString.Append(cDelimiter);
nsAutoString sValue(aValue);
sValue.ReplaceSubstring(NS_LITERAL_STRING("&"),
NS_LITERAL_STRING("&amp;"));
if (bIncludesDouble && bIncludesSingle) {
sValue.ReplaceSubstring(NS_LITERAL_STRING("\""),
NS_LITERAL_STRING("&quot;"));
}
attrString.Append(sValue);
attrString.Append(cDelimiter);
}
if (mDoRaw || PreLevel() > 0) {
AppendToStringConvertLF(attrString, aStr);
}
else if (mDoFormat) {
AppendToStringFormatedWrapped(attrString, aStr);
}
else if (mDoWrap) {
AppendToStringWrapped(attrString, aStr);
}
else {
AppendToStringConvertLF(attrString, aStr);
}
}
uint32_t
nsXMLContentSerializer::ScanNamespaceDeclarations(nsIContent* aContent,
nsIContent *aOriginalElement,
const nsAString& aTagNamespaceURI)
{
uint32_t index, count;
nsAutoString uriStr, valueStr;
count = aContent->GetAttrCount();
// First scan for namespace declarations, pushing each on the stack
uint32_t skipAttr = count;
for (index = 0; index < count; index++) {
const nsAttrName* name = aContent->GetAttrNameAt(index);
int32_t namespaceID = name->NamespaceID();
nsIAtom *attrName = name->LocalName();
if (namespaceID == kNameSpaceID_XMLNS ||
// Also push on the stack attrs named "xmlns" in the null
// namespace... because once we serialize those out they'll look like
// namespace decls. :(
// XXXbz what if we have both "xmlns" in the null namespace and "xmlns"
// in the xmlns namespace?
(namespaceID == kNameSpaceID_None &&
attrName == nsGkAtoms::xmlns)) {
aContent->GetAttr(namespaceID, attrName, uriStr);
if (!name->GetPrefix()) {
if (aTagNamespaceURI.IsEmpty() && !uriStr.IsEmpty()) {
// If the element is in no namespace we need to add a xmlns
// attribute to declare that. That xmlns attribute must not have a
// prefix (see http://www.w3.org/TR/REC-xml-names/#dt-prefix), ie it
// must declare the default namespace. We just found an xmlns
// attribute that declares the default namespace to something
// non-empty. We're going to ignore this attribute, for children we
// will detect that we need to add it again and attributes aren't
// affected by the default namespace.
skipAttr = index;
}
else {
// Default NS attribute does not have prefix (and the name is "xmlns")
PushNameSpaceDecl(EmptyString(), uriStr, aOriginalElement);
}
}
else {
PushNameSpaceDecl(nsDependentAtomString(attrName), uriStr,
aOriginalElement);
}
}
}
return skipAttr;
}
bool
nsXMLContentSerializer::IsJavaScript(nsIContent * aContent, nsIAtom* aAttrNameAtom,
int32_t aAttrNamespaceID, const nsAString& aValueString)
{
bool isHtml = aContent->IsHTML();
bool isXul = aContent->IsXUL();
bool isSvg = aContent->IsSVG();
if (aAttrNamespaceID == kNameSpaceID_None &&
(isHtml || isXul || isSvg) &&
(aAttrNameAtom == nsGkAtoms::href ||
aAttrNameAtom == nsGkAtoms::src)) {
static const char kJavaScript[] = "javascript";
int32_t pos = aValueString.FindChar(':');
if (pos < (int32_t)(sizeof kJavaScript - 1))
return false;
nsAutoString scheme(Substring(aValueString, 0, pos));
scheme.StripWhitespace();
if ((scheme.Length() == (sizeof kJavaScript - 1)) &&
scheme.EqualsIgnoreCase(kJavaScript))
return true;
else
return false;
}
return aContent->IsEventAttributeName(aAttrNameAtom);
}
void
nsXMLContentSerializer::SerializeAttributes(nsIContent* aContent,
nsIContent *aOriginalElement,
nsAString& aTagPrefix,
const nsAString& aTagNamespaceURI,
nsIAtom* aTagName,
nsAString& aStr,
uint32_t aSkipAttr,
bool aAddNSAttr)
{
nsAutoString prefixStr, uriStr, valueStr;
nsAutoString xmlnsStr;
xmlnsStr.AssignLiteral(kXMLNS);
uint32_t index, count;
// If we had to add a new namespace declaration, serialize
// and push it on the namespace stack
if (aAddNSAttr) {
if (aTagPrefix.IsEmpty()) {
// Serialize default namespace decl
SerializeAttr(EmptyString(), xmlnsStr, aTagNamespaceURI, aStr, true);
}
else {
// Serialize namespace decl
SerializeAttr(xmlnsStr, aTagPrefix, aTagNamespaceURI, aStr, true);
}
PushNameSpaceDecl(aTagPrefix, aTagNamespaceURI, aOriginalElement);
}
count = aContent->GetAttrCount();
// Now serialize each of the attributes
// XXX Unfortunately we need a namespace manager to get
// attribute URIs.
for (index = 0; index < count; index++) {
if (aSkipAttr == index) {
continue;
}
const nsAttrName* name = aContent->GetAttrNameAt(index);
int32_t namespaceID = name->NamespaceID();
nsIAtom* attrName = name->LocalName();
nsIAtom* attrPrefix = name->GetPrefix();
// Filter out any attribute starting with [-|_]moz
nsDependentAtomString attrNameStr(attrName);
if (StringBeginsWith(attrNameStr, NS_LITERAL_STRING("_moz")) ||
StringBeginsWith(attrNameStr, NS_LITERAL_STRING("-moz"))) {
continue;
}
if (attrPrefix) {
attrPrefix->ToString(prefixStr);
}
else {
prefixStr.Truncate();
}
bool addNSAttr = false;
if (kNameSpaceID_XMLNS != namespaceID) {
nsContentUtils::NameSpaceManager()->GetNameSpaceURI(namespaceID, uriStr);
addNSAttr = ConfirmPrefix(prefixStr, uriStr, aOriginalElement, true);
}
aContent->GetAttr(namespaceID, attrName, valueStr);
nsDependentAtomString nameStr(attrName);
bool isJS = IsJavaScript(aContent, attrName, namespaceID, valueStr);
SerializeAttr(prefixStr, nameStr, valueStr, aStr, !isJS);
if (addNSAttr) {
NS_ASSERTION(!prefixStr.IsEmpty(),
"Namespaced attributes must have a prefix");
SerializeAttr(xmlnsStr, prefixStr, uriStr, aStr, true);
PushNameSpaceDecl(prefixStr, uriStr, aOriginalElement);
}
}
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendElementStart(Element* aElement,
Element* aOriginalElement,
nsAString& aStr)
{
NS_ENSURE_ARG(aElement);
nsIContent* content = aElement;
bool forceFormat = false;
if (!CheckElementStart(content, forceFormat, aStr)) {
return NS_OK;
}
nsAutoString tagPrefix, tagLocalName, tagNamespaceURI;
aElement->NodeInfo()->GetPrefix(tagPrefix);
aElement->NodeInfo()->GetName(tagLocalName);
aElement->NodeInfo()->GetNamespaceURI(tagNamespaceURI);
uint32_t skipAttr = ScanNamespaceDeclarations(content,
aOriginalElement, tagNamespaceURI);
nsIAtom *name = content->Tag();
bool lineBreakBeforeOpen = LineBreakBeforeOpen(content->GetNameSpaceID(), name);
if ((mDoFormat || forceFormat) && !mDoRaw && !PreLevel()) {
if (mColPos && lineBreakBeforeOpen) {
AppendNewLineToString(aStr);
}
else {
MaybeAddNewlineForRootNode(aStr);
}
if (!mColPos) {
AppendIndentation(aStr);
}
else if (mAddSpace) {
AppendToString(char16_t(' '), aStr);
mAddSpace = false;
}
}
else if (mAddSpace) {
AppendToString(char16_t(' '), aStr);
mAddSpace = false;
}
else {
MaybeAddNewlineForRootNode(aStr);
}
// Always reset to avoid false newlines in case MaybeAddNewlineForRootNode wasn't
// called
mAddNewlineForRootNode = false;
bool addNSAttr;
addNSAttr = ConfirmPrefix(tagPrefix, tagNamespaceURI, aOriginalElement,
false);
// Serialize the qualified name of the element
AppendToString(kLessThan, aStr);
if (!tagPrefix.IsEmpty()) {
AppendToString(tagPrefix, aStr);
AppendToString(NS_LITERAL_STRING(":"), aStr);
}
AppendToString(tagLocalName, aStr);
MaybeEnterInPreContent(content);
if ((mDoFormat || forceFormat) && !mDoRaw && !PreLevel()) {
IncrIndentation(name);
}
SerializeAttributes(content, aOriginalElement, tagPrefix, tagNamespaceURI,
name, aStr, skipAttr, addNSAttr);
AppendEndOfElementStart(aOriginalElement, name, content->GetNameSpaceID(),
aStr);
if ((mDoFormat || forceFormat) && !mDoRaw && !PreLevel()
&& LineBreakAfterOpen(content->GetNameSpaceID(), name)) {
AppendNewLineToString(aStr);
}
AfterElementStart(content, aOriginalElement, aStr);
return NS_OK;
}
void
nsXMLContentSerializer::AppendEndOfElementStart(nsIContent *aOriginalElement,
nsIAtom * aName,
int32_t aNamespaceID,
nsAString& aStr)
{
// We don't output a separate end tag for empty elements
if (!aOriginalElement->GetChildCount()) {
AppendToString(NS_LITERAL_STRING("/>"), aStr);
}
else {
AppendToString(kGreaterThan, aStr);
}
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendElementEnd(Element* aElement,
nsAString& aStr)
{
NS_ENSURE_ARG(aElement);
nsIContent* content = aElement;
bool forceFormat = false, outputElementEnd;
outputElementEnd = CheckElementEnd(content, forceFormat, aStr);
nsIAtom *name = content->Tag();
if ((mDoFormat || forceFormat) && !mDoRaw && !PreLevel()) {
DecrIndentation(name);
}
if (!outputElementEnd) {
PopNameSpaceDeclsFor(aElement);
MaybeFlagNewlineForRootNode(aElement);
return NS_OK;
}
nsAutoString tagPrefix, tagLocalName, tagNamespaceURI;
aElement->NodeInfo()->GetPrefix(tagPrefix);
aElement->NodeInfo()->GetName(tagLocalName);
aElement->NodeInfo()->GetNamespaceURI(tagNamespaceURI);
#ifdef DEBUG
bool debugNeedToPushNamespace =
#endif
ConfirmPrefix(tagPrefix, tagNamespaceURI, aElement, false);
NS_ASSERTION(!debugNeedToPushNamespace, "Can't push namespaces in closing tag!");
if ((mDoFormat || forceFormat) && !mDoRaw && !PreLevel()) {
bool lineBreakBeforeClose = LineBreakBeforeClose(content->GetNameSpaceID(), name);
if (mColPos && lineBreakBeforeClose) {
AppendNewLineToString(aStr);
}
if (!mColPos) {
AppendIndentation(aStr);
}
else if (mAddSpace) {
AppendToString(char16_t(' '), aStr);
mAddSpace = false;
}
}
else if (mAddSpace) {
AppendToString(char16_t(' '), aStr);
mAddSpace = false;
}
AppendToString(kEndTag, aStr);
if (!tagPrefix.IsEmpty()) {
AppendToString(tagPrefix, aStr);
AppendToString(NS_LITERAL_STRING(":"), aStr);
}
AppendToString(tagLocalName, aStr);
AppendToString(kGreaterThan, aStr);
PopNameSpaceDeclsFor(aElement);
MaybeLeaveFromPreContent(content);
if ((mDoFormat || forceFormat) && !mDoRaw && !PreLevel()
&& LineBreakAfterClose(content->GetNameSpaceID(), name)) {
AppendNewLineToString(aStr);
}
else {
MaybeFlagNewlineForRootNode(aElement);
}
AfterElementEnd(content, aStr);
return NS_OK;
}
NS_IMETHODIMP
nsXMLContentSerializer::AppendDocumentStart(nsIDocument *aDocument,
nsAString& aStr)
{
NS_ENSURE_ARG_POINTER(aDocument);
nsAutoString version, encoding, standalone;
aDocument->GetXMLDeclaration(version, encoding, standalone);
if (version.IsEmpty())
return NS_OK; // A declaration must have version, or there is no decl
NS_NAMED_LITERAL_STRING(endQuote, "\"");
aStr += NS_LITERAL_STRING("<?xml version=\"") + version + endQuote;
if (!mCharset.IsEmpty()) {
aStr += NS_LITERAL_STRING(" encoding=\"") +
NS_ConvertASCIItoUTF16(mCharset) + endQuote;
}
// Otherwise just don't output an encoding attr. Not that we expect
// mCharset to ever be empty.
#ifdef DEBUG
else {
NS_WARNING("Empty mCharset? How come?");
}
#endif
if (!standalone.IsEmpty()) {
aStr += NS_LITERAL_STRING(" standalone=\"") + standalone + endQuote;
}
aStr.AppendLiteral("?>");
mAddNewlineForRootNode = true;
return NS_OK;
}
bool
nsXMLContentSerializer::CheckElementStart(nsIContent * aContent,
bool & aForceFormat,
nsAString& aStr)
{
aForceFormat = false;
return true;
}
bool
nsXMLContentSerializer::CheckElementEnd(nsIContent * aContent,
bool & aForceFormat,
nsAString& aStr)
{
// We don't output a separate end tag for empty element
aForceFormat = false;
return aContent->GetChildCount() > 0;
}
void
nsXMLContentSerializer::AppendToString(const char16_t aChar,
nsAString& aOutputStr)
{
if (mBodyOnly && !mInBody) {
return;
}
mColPos += 1;
aOutputStr.Append(aChar);
}
void
nsXMLContentSerializer::AppendToString(const nsAString& aStr,
nsAString& aOutputStr)
{
if (mBodyOnly && !mInBody) {
return;
}
mColPos += aStr.Length();
aOutputStr.Append(aStr);
}
static const uint16_t kGTVal = 62;
static const char* kEntities[] = {
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "&amp;", "",
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "", "",
"&lt;", "", "&gt;"
};
static const char* kAttrEntities[] = {
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "&quot;", "", "", "", "&amp;", "",
"", "", "", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "", "", "",
"&lt;", "", "&gt;"
};
void
nsXMLContentSerializer::AppendAndTranslateEntities(const nsAString& aStr,
nsAString& aOutputStr)
{
nsReadingIterator<char16_t> done_reading;
aStr.EndReading(done_reading);
// for each chunk of |aString|...
uint32_t advanceLength = 0;
nsReadingIterator<char16_t> iter;
const char **entityTable = mInAttribute ? kAttrEntities : kEntities;
for (aStr.BeginReading(iter);
iter != done_reading;
iter.advance(int32_t(advanceLength))) {
uint32_t fragmentLength = iter.size_forward();
const char16_t* c = iter.get();
const char16_t* fragmentStart = c;
const char16_t* fragmentEnd = c + fragmentLength;
const char* entityText = nullptr;
advanceLength = 0;
// for each character in this chunk, check if it
// needs to be replaced
for (; c < fragmentEnd; c++, advanceLength++) {
char16_t val = *c;
if ((val <= kGTVal) && (entityTable[val][0] != 0)) {
entityText = entityTable[val];
break;
}
}
aOutputStr.Append(fragmentStart, advanceLength);
if (entityText) {
AppendASCIItoUTF16(entityText, aOutputStr);
advanceLength++;
}
}
}
void
nsXMLContentSerializer::MaybeAddNewlineForRootNode(nsAString& aStr)
{
if (mAddNewlineForRootNode) {
AppendNewLineToString(aStr);
}
}
void
nsXMLContentSerializer::MaybeFlagNewlineForRootNode(nsINode* aNode)
{
nsINode* parent = aNode->GetParentNode();
if (parent) {
mAddNewlineForRootNode = parent->IsNodeOfType(nsINode::eDOCUMENT);
}
}
void
nsXMLContentSerializer::MaybeEnterInPreContent(nsIContent* aNode)
{
// support of the xml:space attribute
if (ShouldMaintainPreLevel() &&
aNode->HasAttr(kNameSpaceID_XML, nsGkAtoms::space)) {
nsAutoString space;
aNode->GetAttr(kNameSpaceID_XML, nsGkAtoms::space, space);
if (space.EqualsLiteral("preserve"))
++PreLevel();
}
}
void
nsXMLContentSerializer::MaybeLeaveFromPreContent(nsIContent* aNode)
{
// support of the xml:space attribute
if (ShouldMaintainPreLevel() &&
aNode->HasAttr(kNameSpaceID_XML, nsGkAtoms::space)) {
nsAutoString space;
aNode->GetAttr(kNameSpaceID_XML, nsGkAtoms::space, space);
if (space.EqualsLiteral("preserve"))
--PreLevel();
}
}
void
nsXMLContentSerializer::AppendNewLineToString(nsAString& aStr)
{
AppendToString(mLineBreak, aStr);
mMayIgnoreLineBreakSequence = true;
mColPos = 0;
mAddSpace = false;
mIsIndentationAddedOnCurrentLine = false;
}
void
nsXMLContentSerializer::AppendIndentation(nsAString& aStr)
{
mIsIndentationAddedOnCurrentLine = true;
AppendToString(mIndent, aStr);
mAddSpace = false;
mMayIgnoreLineBreakSequence = false;
}
void
nsXMLContentSerializer::IncrIndentation(nsIAtom* aName)
{
// we want to keep the source readable
if (mDoWrap &&
mIndent.Length() >= uint32_t(mMaxColumn) - MIN_INDENTED_LINE_LENGTH) {
++mIndentOverflow;
}
else {
mIndent.AppendLiteral(INDENT_STRING);
}
}
void
nsXMLContentSerializer::DecrIndentation(nsIAtom* aName)
{
if(mIndentOverflow)
--mIndentOverflow;
else
mIndent.Cut(0, INDENT_STRING_LENGTH);
}
bool
nsXMLContentSerializer::LineBreakBeforeOpen(int32_t aNamespaceID, nsIAtom* aName)
{
return mAddSpace;
}
bool
nsXMLContentSerializer::LineBreakAfterOpen(int32_t aNamespaceID, nsIAtom* aName)
{
return false;
}
bool
nsXMLContentSerializer::LineBreakBeforeClose(int32_t aNamespaceID, nsIAtom* aName)
{
return mAddSpace;
}
bool
nsXMLContentSerializer::LineBreakAfterClose(int32_t aNamespaceID, nsIAtom* aName)
{
return false;
}
void
nsXMLContentSerializer::AppendToStringConvertLF(const nsAString& aStr,
nsAString& aOutputStr)
{
if (mBodyOnly && !mInBody) {
return;
}
if (mDoRaw) {
AppendToString(aStr, aOutputStr);
}
else {
// Convert line-endings to mLineBreak
uint32_t start = 0;
uint32_t theLen = aStr.Length();
while (start < theLen) {
int32_t eol = aStr.FindChar('\n', start);
if (eol == kNotFound) {
nsDependentSubstring dataSubstring(aStr, start, theLen - start);
AppendToString(dataSubstring, aOutputStr);
start = theLen;
// if there was a line break before this substring
// AppendNewLineToString was called, so we should reverse
// this flag
mMayIgnoreLineBreakSequence = false;
}
else {
nsDependentSubstring dataSubstring(aStr, start, eol - start);
AppendToString(dataSubstring, aOutputStr);
AppendNewLineToString(aOutputStr);
start = eol + 1;
}
}
}
}
void
nsXMLContentSerializer::AppendFormatedWrapped_WhitespaceSequence(
nsASingleFragmentString::const_char_iterator &aPos,
const nsASingleFragmentString::const_char_iterator aEnd,
const nsASingleFragmentString::const_char_iterator aSequenceStart,
bool &aMayIgnoreStartOfLineWhitespaceSequence,
nsAString &aOutputStr)
{
// Handle the complete sequence of whitespace.
// Continue to iterate until we find the first non-whitespace char.
// Updates "aPos" to point to the first unhandled char.
// Also updates the aMayIgnoreStartOfLineWhitespaceSequence flag,
// as well as the other "global" state flags.
bool sawBlankOrTab = false;
bool leaveLoop = false;
do {
switch (*aPos) {
case ' ':
case '\t':
sawBlankOrTab = true;
// no break
case '\n':
++aPos;
// do not increase mColPos,
// because we will reduce the whitespace to a single char
break;
default:
leaveLoop = true;
break;
}
} while (!leaveLoop && aPos < aEnd);
if (mAddSpace) {
// if we had previously been asked to add space,
// our situation has not changed
}
else if (!sawBlankOrTab && mMayIgnoreLineBreakSequence) {
// nothing to do in the case where line breaks have already been added
// before the call of AppendToStringWrapped
// and only if we found line break in the sequence
mMayIgnoreLineBreakSequence = false;
}
else if (aMayIgnoreStartOfLineWhitespaceSequence) {
// nothing to do
aMayIgnoreStartOfLineWhitespaceSequence = false;
}
else {
if (sawBlankOrTab) {
if (mDoWrap && mColPos + 1 >= mMaxColumn) {
// no much sense in delaying, we only have one slot left,
// let's write a break now
aOutputStr.Append(mLineBreak);
mColPos = 0;
mIsIndentationAddedOnCurrentLine = false;
mMayIgnoreLineBreakSequence = true;
}
else {
// do not write out yet, we may write out either a space or a linebreak
// let's delay writing it out until we know more
mAddSpace = true;
++mColPos; // eat a slot of available space
}
}
else {
// Asian text usually does not contain spaces, therefore we should not
// transform a linebreak into a space.
// Since we only saw linebreaks, but no spaces or tabs,
// let's write a linebreak now.
AppendNewLineToString(aOutputStr);
}
}
}
void
nsXMLContentSerializer::AppendWrapped_NonWhitespaceSequence(
nsASingleFragmentString::const_char_iterator &aPos,
const nsASingleFragmentString::const_char_iterator aEnd,
const nsASingleFragmentString::const_char_iterator aSequenceStart,
bool &aMayIgnoreStartOfLineWhitespaceSequence,
bool &aSequenceStartAfterAWhiteSpace,
nsAString& aOutputStr)
{
mMayIgnoreLineBreakSequence = false;
aMayIgnoreStartOfLineWhitespaceSequence = false;
// Handle the complete sequence of non-whitespace in this block
// Iterate until we find the first whitespace char or an aEnd condition
// Updates "aPos" to point to the first unhandled char.
// Also updates the aMayIgnoreStartOfLineWhitespaceSequence flag,
// as well as the other "global" state flags.
bool thisSequenceStartsAtBeginningOfLine = !mColPos;
bool onceAgainBecauseWeAddedBreakInFront = false;
bool foundWhitespaceInLoop;
uint32_t length, colPos;
do {
if (mColPos) {
colPos = mColPos;
}
else {
if (mDoFormat && !mDoRaw && !PreLevel() && !onceAgainBecauseWeAddedBreakInFront) {
colPos = mIndent.Length();
}
else
colPos = 0;
}
foundWhitespaceInLoop = false;
length = 0;
// we iterate until the next whitespace character
// or until we reach the maximum of character per line
// or until the end of the string to add.
do {
if (*aPos == ' ' || *aPos == '\t' || *aPos == '\n') {
foundWhitespaceInLoop = true;
break;
}
++aPos;
++length;
} while ( (!mDoWrap || colPos + length < mMaxColumn) && aPos < aEnd);
// in the case we don't reached the end of the string, but we reached the maxcolumn,
// we see if there is a whitespace after the maxcolumn
// if yes, then we can append directly the string instead of
// appending a new line etc.
if (*aPos == ' ' || *aPos == '\t' || *aPos == '\n') {
foundWhitespaceInLoop = true;
}
if (aPos == aEnd || foundWhitespaceInLoop) {
// there is enough room for the complete block we found
if (mDoFormat && !mColPos) {
AppendIndentation(aOutputStr);
}
else if (mAddSpace) {
aOutputStr.Append(char16_t(' '));
mAddSpace = false;
}
mColPos += length;
aOutputStr.Append(aSequenceStart, aPos - aSequenceStart);
// We have not yet reached the max column, we will continue to
// fill the current line in the next outer loop iteration
// (this one in AppendToStringWrapped)
// make sure we return in this outer loop
onceAgainBecauseWeAddedBreakInFront = false;
}
else { // we reach the max column
if (!thisSequenceStartsAtBeginningOfLine &&
(mAddSpace || (!mDoFormat && aSequenceStartAfterAWhiteSpace))) {
// when !mDoFormat, mAddSpace is not used, mAddSpace is always false
// so, in the case where mDoWrap && !mDoFormat, if we want to enter in this condition...
// We can avoid to wrap. We try to add the whole block
// in an empty new line
AppendNewLineToString(aOutputStr);
aPos = aSequenceStart;
thisSequenceStartsAtBeginningOfLine = true;
onceAgainBecauseWeAddedBreakInFront = true;
}
else {
// we must wrap
onceAgainBecauseWeAddedBreakInFront = false;
bool foundWrapPosition = false;
int32_t wrapPosition;
nsILineBreaker *lineBreaker = nsContentUtils::LineBreaker();
wrapPosition = lineBreaker->Prev(aSequenceStart,
(aEnd - aSequenceStart),
(aPos - aSequenceStart) + 1);
if (wrapPosition != NS_LINEBREAKER_NEED_MORE_TEXT) {
foundWrapPosition = true;
}
else {
wrapPosition = lineBreaker->Next(aSequenceStart,
(aEnd - aSequenceStart),
(aPos - aSequenceStart));
if (wrapPosition != NS_LINEBREAKER_NEED_MORE_TEXT) {
foundWrapPosition = true;
}
}
if (foundWrapPosition) {
if (!mColPos && mDoFormat) {
AppendIndentation(aOutputStr);
}
else if (mAddSpace) {
aOutputStr.Append(char16_t(' '));
mAddSpace = false;
}
aOutputStr.Append(aSequenceStart, wrapPosition);
AppendNewLineToString(aOutputStr);
aPos = aSequenceStart + wrapPosition;
aMayIgnoreStartOfLineWhitespaceSequence = true;
}
else {
// try some simple fallback logic
// go forward up to the next whitespace position,
// in the worst case this will be all the rest of the data
// we update the mColPos variable with the length of
// the part already parsed.
mColPos += length;
// now try to find the next whitespace
do {
if (*aPos == ' ' || *aPos == '\t' || *aPos == '\n') {
break;
}
++aPos;
++mColPos;
} while (aPos < aEnd);
if (mAddSpace) {
aOutputStr.Append(char16_t(' '));
mAddSpace = false;
}
aOutputStr.Append(aSequenceStart, aPos - aSequenceStart);
}
}
aSequenceStartAfterAWhiteSpace = false;
}
} while (onceAgainBecauseWeAddedBreakInFront);
}
void
nsXMLContentSerializer::AppendToStringFormatedWrapped(const nsASingleFragmentString& aStr,
nsAString& aOutputStr)
{
if (mBodyOnly && !mInBody) {
return;
}
nsASingleFragmentString::const_char_iterator pos, end, sequenceStart;
aStr.BeginReading(pos);
aStr.EndReading(end);
bool sequenceStartAfterAWhitespace = false;
if (pos < end) {
nsAString::const_char_iterator end2;
aOutputStr.EndReading(end2);
--end2;
if (*end2 == ' ' || *end2 == '\n' || *end2 == '\t') {
sequenceStartAfterAWhitespace = true;
}
}
// if the current line already has text on it, such as a tag,
// leading whitespace is significant
bool mayIgnoreStartOfLineWhitespaceSequence =
(!mColPos || (mIsIndentationAddedOnCurrentLine &&
sequenceStartAfterAWhitespace &&
uint32_t(mColPos) == mIndent.Length()));
while (pos < end) {
sequenceStart = pos;
// if beginning of a whitespace sequence
if (*pos == ' ' || *pos == '\n' || *pos == '\t') {
AppendFormatedWrapped_WhitespaceSequence(pos, end, sequenceStart,
mayIgnoreStartOfLineWhitespaceSequence, aOutputStr);
}
else { // any other non-whitespace char
AppendWrapped_NonWhitespaceSequence(pos, end, sequenceStart,
mayIgnoreStartOfLineWhitespaceSequence, sequenceStartAfterAWhitespace, aOutputStr);
}
}
}
void
nsXMLContentSerializer::AppendWrapped_WhitespaceSequence(
nsASingleFragmentString::const_char_iterator &aPos,
const nsASingleFragmentString::const_char_iterator aEnd,
const nsASingleFragmentString::const_char_iterator aSequenceStart,
nsAString &aOutputStr)
{
// Handle the complete sequence of whitespace.
// Continue to iterate until we find the first non-whitespace char.
// Updates "aPos" to point to the first unhandled char.
mAddSpace = false;
mIsIndentationAddedOnCurrentLine = false;
bool leaveLoop = false;
nsASingleFragmentString::const_char_iterator lastPos = aPos;
do {
switch (*aPos) {
case ' ':
case '\t':
// if there are too many spaces on a line, we wrap
if (mColPos >= mMaxColumn) {
if (lastPos != aPos) {
aOutputStr.Append(lastPos, aPos - lastPos);
}
AppendToString(mLineBreak, aOutputStr);
mColPos = 0;
lastPos = aPos;
}
++mColPos;
++aPos;
break;
case '\n':
if (lastPos != aPos) {
aOutputStr.Append(lastPos, aPos - lastPos);
}
AppendToString(mLineBreak, aOutputStr);
mColPos = 0;
++aPos;
lastPos = aPos;
break;
default:
leaveLoop = true;
break;
}
} while (!leaveLoop && aPos < aEnd);
if (lastPos != aPos) {
aOutputStr.Append(lastPos, aPos - lastPos);
}
}
void
nsXMLContentSerializer::AppendToStringWrapped(const nsASingleFragmentString& aStr,
nsAString& aOutputStr)
{
if (mBodyOnly && !mInBody) {
return;
}
nsASingleFragmentString::const_char_iterator pos, end, sequenceStart;
aStr.BeginReading(pos);
aStr.EndReading(end);
// not used in this case, but needed by AppendWrapped_NonWhitespaceSequence
bool mayIgnoreStartOfLineWhitespaceSequence = false;
mMayIgnoreLineBreakSequence = false;
bool sequenceStartAfterAWhitespace = false;
if (pos < end && !aOutputStr.IsEmpty()) {
nsAString::const_char_iterator end2;
aOutputStr.EndReading(end2);
--end2;
if (*end2 == ' ' || *end2 == '\n' || *end2 == '\t') {
sequenceStartAfterAWhitespace = true;
}
}
while (pos < end) {
sequenceStart = pos;
// if beginning of a whitespace sequence
if (*pos == ' ' || *pos == '\n' || *pos == '\t') {
sequenceStartAfterAWhitespace = true;
AppendWrapped_WhitespaceSequence(pos, end, sequenceStart, aOutputStr);
}
else { // any other non-whitespace char
AppendWrapped_NonWhitespaceSequence(pos, end, sequenceStart,
mayIgnoreStartOfLineWhitespaceSequence, sequenceStartAfterAWhitespace, aOutputStr);
}
}
}
bool
nsXMLContentSerializer::ShouldMaintainPreLevel() const
{
// Only attempt to maintain the pre level for consumers who care about it.
return !mDoRaw || (mFlags & nsIDocumentEncoder::OutputNoFormattingInPre);
}