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llvm-mirror/lib/WindowsManifest/WindowsManifestMerger.cpp
Chandler Carruth ae65e281f3 Update the file headers across all of the LLVM projects in the monorepo
to reflect the new license.

We understand that people may be surprised that we're moving the header
entirely to discuss the new license. We checked this carefully with the
Foundation's lawyer and we believe this is the correct approach.

Essentially, all code in the project is now made available by the LLVM
project under our new license, so you will see that the license headers
include that license only. Some of our contributors have contributed
code under our old license, and accordingly, we have retained a copy of
our old license notice in the top-level files in each project and
repository.

llvm-svn: 351636
2019-01-19 08:50:56 +00:00

730 lines
27 KiB
C++

//===-- WindowsManifestMerger.cpp ------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===---------------------------------------------------------------------===//
//
// This file implements the .manifest merger class.
//
//===---------------------------------------------------------------------===//
#include "llvm/WindowsManifest/WindowsManifestMerger.h"
#include "llvm/Config/config.h"
#include "llvm/Support/MemoryBuffer.h"
#include <map>
#if LLVM_LIBXML2_ENABLED
#include <libxml/xmlreader.h>
#endif
#define TO_XML_CHAR(X) reinterpret_cast<const unsigned char *>(X)
#define FROM_XML_CHAR(X) reinterpret_cast<const char *>(X)
using namespace llvm;
using namespace windows_manifest;
char WindowsManifestError::ID = 0;
WindowsManifestError::WindowsManifestError(const Twine &Msg) : Msg(Msg.str()) {}
void WindowsManifestError::log(raw_ostream &OS) const { OS << Msg; }
class WindowsManifestMerger::WindowsManifestMergerImpl {
public:
~WindowsManifestMergerImpl();
Error merge(const MemoryBuffer &Manifest);
std::unique_ptr<MemoryBuffer> getMergedManifest();
private:
static void errorCallback(void *Ctx, const char *Format, ...);
Error getParseError();
#if LLVM_LIBXML2_ENABLED
xmlDocPtr CombinedDoc = nullptr;
std::vector<xmlDocPtr> MergedDocs;
bool Merged = false;
struct XmlDeleter {
void operator()(xmlChar *Ptr) { xmlFree(Ptr); }
void operator()(xmlDoc *Ptr) { xmlFreeDoc(Ptr); }
};
int BufferSize = 0;
std::unique_ptr<xmlChar, XmlDeleter> Buffer;
#endif
bool ParseErrorOccurred = false;
};
#if LLVM_LIBXML2_ENABLED
static const std::pair<StringRef, StringRef> MtNsHrefsPrefixes[] = {
{"urn:schemas-microsoft-com:asm.v1", "ms_asmv1"},
{"urn:schemas-microsoft-com:asm.v2", "ms_asmv2"},
{"urn:schemas-microsoft-com:asm.v3", "ms_asmv3"},
{"http://schemas.microsoft.com/SMI/2005/WindowsSettings",
"ms_windowsSettings"},
{"urn:schemas-microsoft-com:compatibility.v1", "ms_compatibilityv1"}};
static bool xmlStringsEqual(const unsigned char *A, const unsigned char *B) {
// Handle null pointers. Comparison of 2 null pointers returns true because
// this indicates the prefix of a default namespace.
if (!A || !B)
return A == B;
return strcmp(FROM_XML_CHAR(A), FROM_XML_CHAR(B)) == 0;
}
static bool isMergeableElement(const unsigned char *ElementName) {
for (StringRef S : {"application", "assembly", "assemblyIdentity",
"compatibility", "noInherit", "requestedExecutionLevel",
"requestedPrivileges", "security", "trustInfo"}) {
if (S == FROM_XML_CHAR(ElementName)) {
return true;
}
}
return false;
}
static xmlNodePtr getChildWithName(xmlNodePtr Parent,
const unsigned char *ElementName) {
for (xmlNodePtr Child = Parent->children; Child; Child = Child->next) {
if (xmlStringsEqual(Child->name, ElementName)) {
return Child;
}
}
return nullptr;
}
static xmlAttrPtr getAttribute(xmlNodePtr Node,
const unsigned char *AttributeName) {
for (xmlAttrPtr Attribute = Node->properties; Attribute != nullptr;
Attribute = Attribute->next) {
if (xmlStringsEqual(Attribute->name, AttributeName)) {
return Attribute;
}
}
return nullptr;
}
// Check if namespace specified by HRef1 overrides that of HRef2.
static bool namespaceOverrides(const unsigned char *HRef1,
const unsigned char *HRef2) {
auto HRef1Position = llvm::find_if(
MtNsHrefsPrefixes, [=](const std::pair<StringRef, StringRef> &Element) {
return xmlStringsEqual(HRef1, TO_XML_CHAR(Element.first.data()));
});
auto HRef2Position = llvm::find_if(
MtNsHrefsPrefixes, [=](const std::pair<StringRef, StringRef> &Element) {
return xmlStringsEqual(HRef2, TO_XML_CHAR(Element.first.data()));
});
return HRef1Position < HRef2Position;
}
// Search for prefix-defined namespace specified by HRef, starting on Node and
// continuing recursively upwards. Returns the namespace or nullptr if not
// found.
static xmlNsPtr search(const unsigned char *HRef, xmlNodePtr Node) {
for (xmlNsPtr Def = Node->nsDef; Def; Def = Def->next) {
if (Def->prefix && xmlStringsEqual(Def->href, HRef)) {
return Def;
}
}
if (Node->parent) {
return search(HRef, Node->parent);
}
return nullptr;
}
// Return the prefix that corresponds to the HRef. If HRef is not a recognized
// URI, then just return the HRef itself to use as the prefix.
static const unsigned char *getPrefixForHref(const unsigned char *HRef) {
for (auto &Ns : MtNsHrefsPrefixes) {
if (xmlStringsEqual(HRef, TO_XML_CHAR(Ns.first.data()))) {
return TO_XML_CHAR(Ns.second.data());
}
}
return HRef;
}
// Search for prefix-defined namespace specified by HRef, starting on Node and
// continuing recursively upwards. If it is found, then return it. If it is
// not found, then prefix-define that namespace on the node and return a
// reference to it.
static Expected<xmlNsPtr> searchOrDefine(const unsigned char *HRef,
xmlNodePtr Node) {
if (xmlNsPtr Def = search(HRef, Node))
return Def;
if (xmlNsPtr Def = xmlNewNs(Node, HRef, getPrefixForHref(HRef)))
return Def;
return make_error<WindowsManifestError>("failed to create new namespace");
}
// Set the namespace of OrigionalAttribute on OriginalNode to be that of
// AdditionalAttribute's.
static Error copyAttributeNamespace(xmlAttrPtr OriginalAttribute,
xmlNodePtr OriginalNode,
xmlAttrPtr AdditionalAttribute) {
Expected<xmlNsPtr> ExplicitOrError =
searchOrDefine(AdditionalAttribute->ns->href, OriginalNode);
if (!ExplicitOrError)
return ExplicitOrError.takeError();
OriginalAttribute->ns = std::move(ExplicitOrError.get());
return Error::success();
}
// Return the corresponding namespace definition for the prefix, defined on the
// given Node. Returns nullptr if there is no such definition.
static xmlNsPtr getNamespaceWithPrefix(const unsigned char *Prefix,
xmlNodePtr Node) {
if (Node == nullptr)
return nullptr;
for (xmlNsPtr Def = Node->nsDef; Def; Def = Def->next) {
if (xmlStringsEqual(Def->prefix, Prefix)) {
return Def;
}
}
return nullptr;
}
// Search for the closest inheritable default namespace, starting on (and
// including) the Node and traveling upwards through parent nodes. Returns
// nullptr if there are no inheritable default namespaces.
static xmlNsPtr getClosestDefault(xmlNodePtr Node) {
if (xmlNsPtr Ret = getNamespaceWithPrefix(nullptr, Node))
return Ret;
if (Node->parent == nullptr)
return nullptr;
return getClosestDefault(Node->parent);
}
// Merge the attributes of AdditionalNode into OriginalNode. If attributes
// with identical types are present, they are not duplicated but rather if
// their values are not consistent and error is thrown. In addition, the
// higher priority namespace is used for each attribute, EXCEPT in the case
// of merging two default namespaces and the lower priority namespace
// definition occurs closer than the higher priority one.
static Error mergeAttributes(xmlNodePtr OriginalNode,
xmlNodePtr AdditionalNode) {
xmlNsPtr ClosestDefault = getClosestDefault(OriginalNode);
for (xmlAttrPtr Attribute = AdditionalNode->properties; Attribute;
Attribute = Attribute->next) {
if (xmlAttrPtr OriginalAttribute =
getAttribute(OriginalNode, Attribute->name)) {
if (!xmlStringsEqual(OriginalAttribute->children->content,
Attribute->children->content)) {
return make_error<WindowsManifestError>(
Twine("conflicting attributes for ") +
FROM_XML_CHAR(OriginalNode->name));
}
if (!Attribute->ns) {
continue;
}
if (!OriginalAttribute->ns) {
if (auto E = copyAttributeNamespace(OriginalAttribute, OriginalNode,
Attribute)) {
return E;
}
continue;
}
if (namespaceOverrides(OriginalAttribute->ns->href,
Attribute->ns->href)) {
// In this case, the original attribute has a higher priority namespace
// than the incomiing attribute, however the namespace definition of
// the lower priority namespace occurs first traveling upwards in the
// tree. Therefore the lower priority namespace is applied.
if (!OriginalAttribute->ns->prefix && !Attribute->ns->prefix &&
ClosestDefault &&
xmlStringsEqual(Attribute->ns->href, ClosestDefault->href)) {
if (auto E = copyAttributeNamespace(OriginalAttribute, OriginalNode,
Attribute)) {
return E;
}
continue;
}
continue;
// This covers the case where the incoming attribute has the higher
// priority. The higher priority namespace is applied in all cases
// EXCEPT when both of the namespaces are default inherited, and the
// closest inherited default is the lower priority one.
}
if (Attribute->ns->prefix || OriginalAttribute->ns->prefix ||
(ClosestDefault && !xmlStringsEqual(OriginalAttribute->ns->href,
ClosestDefault->href))) {
if (auto E = copyAttributeNamespace(OriginalAttribute, OriginalNode,
Attribute)) {
return E;
}
continue;
}
continue;
}
// If the incoming attribute is not already found on the node, append it
// to the end of the properties list. Also explicitly apply its
// namespace as a prefix because it might be contained in a separate
// namespace that doesn't use the attribute.
xmlAttrPtr NewProp =
xmlNewProp(OriginalNode, Attribute->name, Attribute->children->content);
Expected<xmlNsPtr> ExplicitOrError =
searchOrDefine(Attribute->ns->href, OriginalNode);
if (!ExplicitOrError)
return ExplicitOrError.takeError();
NewProp->ns = std::move(ExplicitOrError.get());
}
return Error::success();
}
// Given two nodes, return the one with the higher priority namespace.
static xmlNodePtr getDominantNode(xmlNodePtr Node1, xmlNodePtr Node2) {
if (!Node1 || !Node1->ns)
return Node2;
if (!Node2 || !Node2->ns)
return Node1;
if (namespaceOverrides(Node1->ns->href, Node2->ns->href))
return Node1;
return Node2;
}
// Checks if this Node's namespace is inherited or one it defined itself.
static bool hasInheritedNs(xmlNodePtr Node) {
return Node->ns && Node->ns != getNamespaceWithPrefix(Node->ns->prefix, Node);
}
// Check if this Node's namespace is a default namespace that it inherited, as
// opposed to defining itself.
static bool hasInheritedDefaultNs(xmlNodePtr Node) {
return hasInheritedNs(Node) && Node->ns->prefix == nullptr;
}
// Check if this Node's namespace is a default namespace it defined itself.
static bool hasDefinedDefaultNamespace(xmlNodePtr Node) {
return Node->ns && (Node->ns == getNamespaceWithPrefix(nullptr, Node));
}
// For the given explicit prefix-definition of a namespace, travel downwards
// from a node recursively, and for every implicit, inherited default usage of
// that namespace replace it with that explicit prefix use. This is important
// when namespace overriding occurs when merging, so that elements unique to a
// namespace will still stay in that namespace.
static void explicateNamespace(xmlNsPtr PrefixDef, xmlNodePtr Node) {
// If a node as its own default namespace definition it clearly cannot have
// inherited the given default namespace, and neither will any of its
// children.
if (hasDefinedDefaultNamespace(Node))
return;
if (Node->ns && xmlStringsEqual(Node->ns->href, PrefixDef->href) &&
hasInheritedDefaultNs(Node))
Node->ns = PrefixDef;
for (xmlAttrPtr Attribute = Node->properties; Attribute;
Attribute = Attribute->next) {
if (Attribute->ns &&
xmlStringsEqual(Attribute->ns->href, PrefixDef->href)) {
Attribute->ns = PrefixDef;
}
}
for (xmlNodePtr Child = Node->children; Child; Child = Child->next) {
explicateNamespace(PrefixDef, Child);
}
}
// Perform the namespace merge between two nodes.
static Error mergeNamespaces(xmlNodePtr OriginalNode,
xmlNodePtr AdditionalNode) {
// Save the original default namespace definition in case the incoming node
// overrides it.
const unsigned char *OriginalDefinedDefaultHref = nullptr;
if (xmlNsPtr OriginalDefinedDefaultNs =
getNamespaceWithPrefix(nullptr, OriginalNode)) {
OriginalDefinedDefaultHref = xmlStrdup(OriginalDefinedDefaultNs->href);
}
const unsigned char *NewDefinedDefaultHref = nullptr;
// Copy all namespace definitions. There can only be one default namespace
// definition per node, so the higher priority one takes precedence in the
// case of collision.
for (xmlNsPtr Def = AdditionalNode->nsDef; Def; Def = Def->next) {
if (xmlNsPtr OriginalNsDef =
getNamespaceWithPrefix(Def->prefix, OriginalNode)) {
if (!Def->prefix) {
if (namespaceOverrides(Def->href, OriginalNsDef->href)) {
NewDefinedDefaultHref = TO_XML_CHAR(strdup(FROM_XML_CHAR(Def->href)));
}
} else if (!xmlStringsEqual(OriginalNsDef->href, Def->href)) {
return make_error<WindowsManifestError>(
Twine("conflicting namespace definitions for ") +
FROM_XML_CHAR(Def->prefix));
}
} else {
xmlNsPtr NewDef = xmlCopyNamespace(Def);
NewDef->next = OriginalNode->nsDef;
OriginalNode->nsDef = NewDef;
}
}
// Check whether the original node or the incoming node has the higher
// priority namespace. Depending on which one is dominant, we will have
// to recursively apply namespace changes down to children of the original
// node.
xmlNodePtr DominantNode = getDominantNode(OriginalNode, AdditionalNode);
xmlNodePtr NonDominantNode =
DominantNode == OriginalNode ? AdditionalNode : OriginalNode;
if (DominantNode == OriginalNode) {
if (OriginalDefinedDefaultHref) {
xmlNsPtr NonDominantDefinedDefault =
getNamespaceWithPrefix(nullptr, NonDominantNode);
// In this case, both the nodes defined a default namespace. However
// the lower priority node ended up having a higher priority default
// definition. This can occur if the higher priority node is prefix
// namespace defined. In this case we have to define an explicit
// prefix for the overridden definition and apply it to all children
// who relied on that definition.
if (NonDominantDefinedDefault &&
namespaceOverrides(NonDominantDefinedDefault->href,
OriginalDefinedDefaultHref)) {
Expected<xmlNsPtr> EC =
searchOrDefine(OriginalDefinedDefaultHref, DominantNode);
if (!EC) {
return EC.takeError();
}
xmlNsPtr PrefixDominantDefinedDefault = std::move(EC.get());
explicateNamespace(PrefixDominantDefinedDefault, DominantNode);
}
// In this case the node with a higher priority namespace did not have a
// default namespace definition, but the lower priority node did. In this
// case the new default namespace definition is copied. A side effect of
// this is that all children will suddenly find themselves in a different
// default namespace. To maintain correctness we need to ensure that all
// children now explicitly refer to the namespace that they had previously
// implicitly inherited.
} else if (getNamespaceWithPrefix(nullptr, NonDominantNode)) {
if (DominantNode->parent) {
xmlNsPtr ClosestDefault = getClosestDefault(DominantNode->parent);
Expected<xmlNsPtr> EC =
searchOrDefine(ClosestDefault->href, DominantNode);
if (!EC) {
return EC.takeError();
}
xmlNsPtr ExplicitDefault = std::move(EC.get());
explicateNamespace(ExplicitDefault, DominantNode);
}
}
} else {
// Covers case where the incoming node has a default namespace definition
// that overrides the original node's namespace. This always leads to
// the original node receiving that new default namespace.
if (hasDefinedDefaultNamespace(DominantNode)) {
NonDominantNode->ns = getNamespaceWithPrefix(nullptr, NonDominantNode);
} else {
// This covers the case where the incoming node either has a prefix
// namespace, or an inherited default namespace. Since the namespace
// may not yet be defined in the original tree we do a searchOrDefine
// for it, and then set the namespace equal to it.
Expected<xmlNsPtr> EC =
searchOrDefine(DominantNode->ns->href, NonDominantNode);
if (!EC) {
return EC.takeError();
}
xmlNsPtr Explicit = std::move(EC.get());
NonDominantNode->ns = Explicit;
}
// This covers cases where the incoming dominant node HAS a default
// namespace definition, but MIGHT NOT NECESSARILY be in that namespace.
if (xmlNsPtr DominantDefaultDefined =
getNamespaceWithPrefix(nullptr, DominantNode)) {
if (OriginalDefinedDefaultHref) {
if (namespaceOverrides(DominantDefaultDefined->href,
OriginalDefinedDefaultHref)) {
// In this case, the incoming node's default definition overrides
// the original default definition, all children who relied on that
// definition must be updated accordingly.
Expected<xmlNsPtr> EC =
searchOrDefine(OriginalDefinedDefaultHref, NonDominantNode);
if (!EC) {
return EC.takeError();
}
xmlNsPtr ExplicitDefault = std::move(EC.get());
explicateNamespace(ExplicitDefault, NonDominantNode);
}
} else {
// The original did not define a default definition, however the new
// default definition still applies to all children, so they must be
// updated to explicitly refer to the namespace they had previously
// been inheriting implicitly.
xmlNsPtr ClosestDefault = getClosestDefault(NonDominantNode);
Expected<xmlNsPtr> EC =
searchOrDefine(ClosestDefault->href, NonDominantNode);
if (!EC) {
return EC.takeError();
}
xmlNsPtr ExplicitDefault = std::move(EC.get());
explicateNamespace(ExplicitDefault, NonDominantNode);
}
}
}
if (NewDefinedDefaultHref) {
xmlNsPtr OriginalNsDef = getNamespaceWithPrefix(nullptr, OriginalNode);
xmlFree(const_cast<unsigned char *>(OriginalNsDef->href));
OriginalNsDef->href = NewDefinedDefaultHref;
}
xmlFree(const_cast<unsigned char *>(OriginalDefinedDefaultHref));
return Error::success();
}
static bool isRecognizedNamespace(const unsigned char *NsHref) {
for (auto &Ns : MtNsHrefsPrefixes) {
if (xmlStringsEqual(NsHref, TO_XML_CHAR(Ns.first.data()))) {
return true;
}
}
return false;
}
static bool hasRecognizedNamespace(xmlNodePtr Node) {
return isRecognizedNamespace(Node->ns->href);
}
// Ensure a node's inherited namespace is actually defined in the tree it
// resides in.
static Error reconcileNamespaces(xmlNodePtr Node) {
if (!Node) {
return Error::success();
}
if (hasInheritedNs(Node)) {
Expected<xmlNsPtr> ExplicitOrError = searchOrDefine(Node->ns->href, Node);
if (!ExplicitOrError) {
return ExplicitOrError.takeError();
}
xmlNsPtr Explicit = std::move(ExplicitOrError.get());
Node->ns = Explicit;
}
for (xmlNodePtr Child = Node->children; Child; Child = Child->next) {
if (auto E = reconcileNamespaces(Child)) {
return E;
}
}
return Error::success();
}
// Recursively merge the two given manifest trees, depending on which elements
// are of a mergeable type, and choose namespaces according to which have
// higher priority.
static Error treeMerge(xmlNodePtr OriginalRoot, xmlNodePtr AdditionalRoot) {
if (auto E = mergeAttributes(OriginalRoot, AdditionalRoot))
return E;
if (auto E = mergeNamespaces(OriginalRoot, AdditionalRoot))
return E;
xmlNodePtr AdditionalFirstChild = AdditionalRoot->children;
xmlNode StoreNext;
for (xmlNodePtr Child = AdditionalFirstChild; Child; Child = Child->next) {
xmlNodePtr OriginalChildWithName;
if (!isMergeableElement(Child->name) ||
!(OriginalChildWithName =
getChildWithName(OriginalRoot, Child->name)) ||
!hasRecognizedNamespace(Child)) {
StoreNext.next = Child->next;
xmlUnlinkNode(Child);
if (!xmlAddChild(OriginalRoot, Child)) {
return make_error<WindowsManifestError>(Twine("could not merge ") +
FROM_XML_CHAR(Child->name));
}
if (auto E = reconcileNamespaces(Child)) {
return E;
}
Child = &StoreNext;
} else if (auto E = treeMerge(OriginalChildWithName, Child)) {
return E;
}
}
return Error::success();
}
static void stripComments(xmlNodePtr Root) {
xmlNode StoreNext;
for (xmlNodePtr Child = Root->children; Child; Child = Child->next) {
if (!xmlStringsEqual(Child->name, TO_XML_CHAR("comment"))) {
stripComments(Child);
continue;
}
StoreNext.next = Child->next;
xmlNodePtr Remove = Child;
Child = &StoreNext;
xmlUnlinkNode(Remove);
xmlFreeNode(Remove);
}
}
// libxml2 assumes that attributes do not inherit default namespaces, whereas
// the original mt.exe does make this assumption. This function reconciles
// this by setting all attributes to have the inherited default namespace.
static void setAttributeNamespaces(xmlNodePtr Node) {
for (xmlAttrPtr Attribute = Node->properties; Attribute;
Attribute = Attribute->next) {
if (!Attribute->ns) {
Attribute->ns = getClosestDefault(Node);
}
}
for (xmlNodePtr Child = Node->children; Child; Child = Child->next) {
setAttributeNamespaces(Child);
}
}
// The merging process may create too many prefix defined namespaces. This
// function removes all unnecessary ones from the tree.
static void checkAndStripPrefixes(xmlNodePtr Node,
std::vector<xmlNsPtr> &RequiredPrefixes) {
for (xmlNodePtr Child = Node->children; Child; Child = Child->next) {
checkAndStripPrefixes(Child, RequiredPrefixes);
}
if (Node->ns && Node->ns->prefix != nullptr) {
xmlNsPtr ClosestDefault = getClosestDefault(Node);
if (ClosestDefault &&
xmlStringsEqual(ClosestDefault->href, Node->ns->href)) {
Node->ns = ClosestDefault;
} else if (!llvm::is_contained(RequiredPrefixes, Node->ns)) {
RequiredPrefixes.push_back(Node->ns);
}
}
for (xmlAttrPtr Attribute = Node->properties; Attribute;
Attribute = Attribute->next) {
if (Attribute->ns && Attribute->ns->prefix != nullptr) {
xmlNsPtr ClosestDefault = getClosestDefault(Node);
if (ClosestDefault &&
xmlStringsEqual(ClosestDefault->href, Attribute->ns->href)) {
Attribute->ns = ClosestDefault;
} else if (!llvm::is_contained(RequiredPrefixes, Node->ns)) {
RequiredPrefixes.push_back(Attribute->ns);
}
}
}
xmlNsPtr Prev;
xmlNs Temp;
for (xmlNsPtr Def = Node->nsDef; Def; Def = Def->next) {
if (!Def->prefix || llvm::is_contained(RequiredPrefixes, Def)) {
Prev = Def;
continue;
}
if (Def == Node->nsDef) {
Node->nsDef = Def->next;
} else {
Prev->next = Def->next;
}
Temp.next = Def->next;
xmlFreeNs(Def);
Def = &Temp;
}
}
WindowsManifestMerger::WindowsManifestMergerImpl::~WindowsManifestMergerImpl() {
for (auto &Doc : MergedDocs)
xmlFreeDoc(Doc);
}
Error WindowsManifestMerger::WindowsManifestMergerImpl::merge(
const MemoryBuffer &Manifest) {
if (Merged)
return make_error<WindowsManifestError>(
"merge after getMergedManifest is not supported");
if (Manifest.getBufferSize() == 0)
return make_error<WindowsManifestError>(
"attempted to merge empty manifest");
xmlSetGenericErrorFunc((void *)this,
WindowsManifestMergerImpl::errorCallback);
xmlDocPtr ManifestXML = xmlReadMemory(
Manifest.getBufferStart(), Manifest.getBufferSize(), "manifest.xml",
nullptr, XML_PARSE_NOBLANKS | XML_PARSE_NODICT);
xmlSetGenericErrorFunc(nullptr, nullptr);
if (auto E = getParseError())
return E;
xmlNodePtr AdditionalRoot = xmlDocGetRootElement(ManifestXML);
stripComments(AdditionalRoot);
setAttributeNamespaces(AdditionalRoot);
if (CombinedDoc == nullptr) {
CombinedDoc = ManifestXML;
} else {
xmlNodePtr CombinedRoot = xmlDocGetRootElement(CombinedDoc);
if (!xmlStringsEqual(CombinedRoot->name, AdditionalRoot->name) ||
!isMergeableElement(AdditionalRoot->name) ||
!hasRecognizedNamespace(AdditionalRoot)) {
return make_error<WindowsManifestError>("multiple root nodes");
}
if (auto E = treeMerge(CombinedRoot, AdditionalRoot)) {
return E;
}
}
MergedDocs.push_back(ManifestXML);
return Error::success();
}
std::unique_ptr<MemoryBuffer>
WindowsManifestMerger::WindowsManifestMergerImpl::getMergedManifest() {
if (!Merged) {
Merged = true;
if (!CombinedDoc)
return nullptr;
xmlNodePtr CombinedRoot = xmlDocGetRootElement(CombinedDoc);
std::vector<xmlNsPtr> RequiredPrefixes;
checkAndStripPrefixes(CombinedRoot, RequiredPrefixes);
std::unique_ptr<xmlDoc, XmlDeleter> OutputDoc(
xmlNewDoc((const unsigned char *)"1.0"));
xmlDocSetRootElement(OutputDoc.get(), CombinedRoot);
assert(0 == xmlDocGetRootElement(CombinedDoc));
xmlKeepBlanksDefault(0);
xmlChar *Buff = nullptr;
xmlDocDumpFormatMemoryEnc(OutputDoc.get(), &Buff, &BufferSize, "UTF-8", 1);
Buffer.reset(Buff);
}
return BufferSize ? MemoryBuffer::getMemBufferCopy(StringRef(
FROM_XML_CHAR(Buffer.get()), (size_t)BufferSize))
: nullptr;
}
bool windows_manifest::isAvailable() { return true; }
#else
WindowsManifestMerger::WindowsManifestMergerImpl::~WindowsManifestMergerImpl() {
}
Error WindowsManifestMerger::WindowsManifestMergerImpl::merge(
const MemoryBuffer &Manifest) {
return make_error<WindowsManifestError>("no libxml2");
}
std::unique_ptr<MemoryBuffer>
WindowsManifestMerger::WindowsManifestMergerImpl::getMergedManifest() {
return nullptr;
}
bool windows_manifest::isAvailable() { return false; }
#endif
WindowsManifestMerger::WindowsManifestMerger()
: Impl(make_unique<WindowsManifestMergerImpl>()) {}
WindowsManifestMerger::~WindowsManifestMerger() {}
Error WindowsManifestMerger::merge(const MemoryBuffer &Manifest) {
return Impl->merge(Manifest);
}
std::unique_ptr<MemoryBuffer> WindowsManifestMerger::getMergedManifest() {
return Impl->getMergedManifest();
}
void WindowsManifestMerger::WindowsManifestMergerImpl::errorCallback(
void *Ctx, const char *Format, ...) {
auto *Merger = (WindowsManifestMergerImpl *)Ctx;
Merger->ParseErrorOccurred = true;
}
Error WindowsManifestMerger::WindowsManifestMergerImpl::getParseError() {
if (!ParseErrorOccurred)
return Error::success();
return make_error<WindowsManifestError>("invalid xml document");
}