CMake/Source/cmMakefile.cxx

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/*============================================================================
CMake - Cross Platform Makefile Generator
Copyright 2000-2009 Kitware, Inc., Insight Software Consortium
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Distributed under the OSI-approved BSD License (the "License");
see accompanying file Copyright.txt for details.
2001-01-11 22:55:47 +03:00
This software is distributed WITHOUT ANY WARRANTY; without even the
implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the License for more information.
============================================================================*/
#include "cmMakefile.h"
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#include "cmCommand.h"
#include "cmCommandArgumentParserHelper.h"
#include "cmCommands.h"
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#include "cmFunctionBlocker.h"
#include "cmGeneratorExpression.h"
#include "cmGeneratorExpressionEvaluationFile.h"
#include "cmGlobalGenerator.h"
#include "cmListFileCache.h"
#include "cmOutputConverter.h"
#include "cmSourceFile.h"
#include "cmSourceFileLocation.h"
#include "cmState.h"
#include "cmSystemTools.h"
#include "cmTest.h"
#include "cmVersion.h"
#ifdef CMAKE_BUILD_WITH_CMAKE
#include "cmVariableWatch.h"
#endif
#include "cmAlgorithms.h"
#include "cmInstallGenerator.h"
#include "cmTestGenerator.h"
#include "cmake.h"
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#include <stdlib.h> // required for atoi
#include <cmsys/FStream.hxx>
#include <cmsys/RegularExpression.hxx>
#include <cmsys/auto_ptr.hxx>
#include <assert.h>
#include <ctype.h> // for isspace
#include <list>
// default is not to be building executables
cmMakefile::cmMakefile(cmGlobalGenerator* globalGenerator,
cmState::Snapshot const& snapshot)
: GlobalGenerator(globalGenerator)
, StateSnapshot(snapshot)
, Backtrace(snapshot)
{
this->IsSourceFileTryCompile = false;
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this->WarnUnused = this->GetCMakeInstance()->GetWarnUnused();
this->CheckSystemVars = this->GetCMakeInstance()->GetCheckSystemVars();
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this->SuppressWatches = false;
// Setup the default include complaint regular expression (match nothing).
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this->ComplainFileRegularExpression = "^$";
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this->DefineFlags = " ";
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this->cmDefineRegex.compile("#cmakedefine[ \t]+([A-Za-z_0-9]*)");
this->cmDefine01Regex.compile("#cmakedefine01[ \t]+([A-Za-z_0-9]*)");
this->cmAtVarRegex.compile("(@[A-Za-z_0-9/.+-]+@)");
this->cmNamedCurly.compile("^[A-Za-z0-9/_.+-]+{");
this->StateSnapshot =
this->StateSnapshot.GetState()->CreatePolicyScopeSnapshot(
this->StateSnapshot);
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// Enter a policy level for this directory.
this->PushPolicy();
// push empty loop block
this->PushLoopBlockBarrier();
// By default the check is not done. It is enabled by
// cmListFileCache in the top level if necessary.
this->CheckCMP0000 = false;
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->AddSourceGroup("", "^.*$");
this->AddSourceGroup("Source Files",
"\\.(C|M|c|c\\+\\+|cc|cpp|cxx|f|f90|for|fpp"
"|ftn|m|mm|rc|def|r|odl|idl|hpj|bat)$");
this->AddSourceGroup("Header Files", CM_HEADER_REGEX);
this->AddSourceGroup("CMake Rules", "\\.rule$");
this->AddSourceGroup("Resources", "\\.plist$");
this->AddSourceGroup("Object Files", "\\.(lo|o|obj)$");
#endif
}
cmMakefile::~cmMakefile()
{
cmDeleteAll(this->InstallGenerators);
cmDeleteAll(this->TestGenerators);
cmDeleteAll(this->SourceFiles);
cmDeleteAll(this->Tests);
cmDeleteAll(this->ImportedTargetsOwned);
cmDeleteAll(this->FinalPassCommands);
cmDeleteAll(this->FunctionBlockers);
cmDeleteAll(this->EvaluationFiles);
}
void cmMakefile::IssueMessage(cmake::MessageType t, std::string const& text,
bool force) const
{
// Collect context information.
if (!this->ExecutionStatusStack.empty()) {
if ((t == cmake::FATAL_ERROR) || (t == cmake::INTERNAL_ERROR)) {
this->ExecutionStatusStack.back()->SetNestedError(true);
}
}
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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this->GetCMakeInstance()->IssueMessage(t, text, this->GetBacktrace(), force);
}
cmStringRange cmMakefile::GetIncludeDirectoriesEntries() const
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{
return this->StateSnapshot.GetDirectory().GetIncludeDirectoriesEntries();
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}
cmBacktraceRange cmMakefile::GetIncludeDirectoriesBacktraces() const
{
return this->StateSnapshot.GetDirectory()
.GetIncludeDirectoriesEntryBacktraces();
}
cmStringRange cmMakefile::GetCompileOptionsEntries() const
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{
return this->StateSnapshot.GetDirectory().GetCompileOptionsEntries();
}
cmBacktraceRange cmMakefile::GetCompileOptionsBacktraces() const
{
return this->StateSnapshot.GetDirectory().GetCompileOptionsEntryBacktraces();
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}
cmStringRange cmMakefile::GetCompileDefinitionsEntries() const
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{
return this->StateSnapshot.GetDirectory().GetCompileDefinitionsEntries();
}
cmBacktraceRange cmMakefile::GetCompileDefinitionsBacktraces() const
{
return this->StateSnapshot.GetDirectory()
.GetCompileDefinitionsEntryBacktraces();
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}
cmListFileBacktrace cmMakefile::GetBacktrace() const
{
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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return this->Backtrace;
}
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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cmListFileBacktrace cmMakefile::GetBacktrace(cmCommandContext const& cc) const
{
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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cmListFileContext lfc;
lfc.Name = cc.Name;
lfc.Line = cc.Line;
lfc.FilePath = this->StateSnapshot.GetExecutionListFile();
return this->Backtrace.Push(lfc);
}
cmListFileContext cmMakefile::GetExecutionContext() const
{
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
cmListFileContext const& cur = this->Backtrace.Top();
cmListFileContext lfc;
lfc.Name = cur.Name;
lfc.Line = cur.Line;
lfc.FilePath = this->StateSnapshot.GetExecutionListFile();
return lfc;
}
void cmMakefile::PrintCommandTrace(const cmListFileFunction& lff) const
{
std::ostringstream msg;
msg << this->GetExecutionFilePath() << "(" << lff.Line << "): ";
msg << lff.Name << "(";
bool expand = this->GetCMakeInstance()->GetTraceExpand();
std::string temp;
for (std::vector<cmListFileArgument>::const_iterator i =
lff.Arguments.begin();
i != lff.Arguments.end(); ++i) {
if (expand) {
temp = i->Value;
this->ExpandVariablesInString(temp);
msg << temp;
} else {
msg << i->Value;
}
msg << " ";
}
msg << ")";
cmSystemTools::Message(msg.str().c_str());
}
// Helper class to make sure the call stack is valid.
class cmMakefileCall
{
public:
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
cmMakefileCall(cmMakefile* mf, cmCommandContext const& cc,
cmExecutionStatus& status)
: Makefile(mf)
{
cmListFileContext const& lfc = cmListFileContext::FromCommandContext(
cc, this->Makefile->StateSnapshot.GetExecutionListFile());
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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this->Makefile->Backtrace = this->Makefile->Backtrace.Push(lfc);
this->Makefile->ExecutionStatusStack.push_back(&status);
}
~cmMakefileCall()
{
this->Makefile->ExecutionStatusStack.pop_back();
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
this->Makefile->Backtrace = this->Makefile->Backtrace.Pop();
}
private:
cmMakefile* Makefile;
};
bool cmMakefile::ExecuteCommand(const cmListFileFunction& lff,
cmExecutionStatus& status)
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{
bool result = true;
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// quick return if blocked
if (this->IsFunctionBlocked(lff, status)) {
// No error.
return result;
}
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std::string name = lff.Name;
// Place this call on the call stack.
cmMakefileCall stack_manager(this, lff, status);
static_cast<void>(stack_manager);
// Lookup the command prototype.
if (cmCommand* proto = this->GetState()->GetCommand(name)) {
// Clone the prototype.
cmsys::auto_ptr<cmCommand> pcmd(proto->Clone());
pcmd->SetMakefile(this);
// Decide whether to invoke the command.
if (pcmd->GetEnabled() && !cmSystemTools::GetFatalErrorOccured() &&
(this->GetCMakeInstance()->GetWorkingMode() != cmake::SCRIPT_MODE ||
pcmd->IsScriptable()))
{
// if trace is enabled, print out invoke information
if (this->GetCMakeInstance()->GetTrace()) {
this->PrintCommandTrace(lff);
}
// Try invoking the command.
if (!pcmd->InvokeInitialPass(lff.Arguments, status) ||
status.GetNestedError()) {
if (!status.GetNestedError()) {
// The command invocation requested that we report an error.
2008-03-11 17:29:56 +03:00
this->IssueMessage(cmake::FATAL_ERROR, pcmd->GetError());
}
result = false;
if (this->GetCMakeInstance()->GetWorkingMode() != cmake::NORMAL_MODE) {
cmSystemTools::SetFatalErrorOccured();
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}
} else if (pcmd->HasFinalPass()) {
// use the command
this->FinalPassCommands.push_back(pcmd.release());
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}
} else if (this->GetCMakeInstance()->GetWorkingMode() ==
cmake::SCRIPT_MODE &&
!pcmd->IsScriptable()) {
std::string error = "Command ";
error += pcmd->GetName();
error += "() is not scriptable";
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this->IssueMessage(cmake::FATAL_ERROR, error);
result = false;
cmSystemTools::SetFatalErrorOccured();
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}
} else {
if (!cmSystemTools::GetFatalErrorOccured()) {
std::string error = "Unknown CMake command \"";
error += lff.Name;
error += "\".";
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this->IssueMessage(cmake::FATAL_ERROR, error);
result = false;
cmSystemTools::SetFatalErrorOccured();
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}
}
return result;
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}
class cmMakefile::IncludeScope
{
public:
IncludeScope(cmMakefile* mf, std::string const& filenametoread,
bool noPolicyScope);
~IncludeScope();
void Quiet() { this->ReportError = false; }
private:
cmMakefile* Makefile;
bool NoPolicyScope;
bool CheckCMP0011;
bool ReportError;
void EnforceCMP0011();
};
cmMakefile::IncludeScope::IncludeScope(cmMakefile* mf,
std::string const& filenametoread,
bool noPolicyScope)
: Makefile(mf)
, NoPolicyScope(noPolicyScope)
, CheckCMP0011(false)
, ReportError(true)
{
this->Makefile->Backtrace = this->Makefile->Backtrace.Push(filenametoread);
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
this->Makefile->PushFunctionBlockerBarrier();
this->Makefile->StateSnapshot =
this->Makefile->GetState()->CreateIncludeFileSnapshot(
this->Makefile->StateSnapshot, filenametoread);
if (!this->NoPolicyScope) {
// Check CMP0011 to determine the policy scope type.
switch (this->Makefile->GetPolicyStatus(cmPolicies::CMP0011)) {
case cmPolicies::WARN:
// We need to push a scope to detect whether the script sets
// any policies that would affect the includer and therefore
// requires a warning. We use a weak scope to simulate OLD
// behavior by allowing policy changes to affect the includer.
this->Makefile->PushPolicy(true);
this->CheckCMP0011 = true;
break;
case cmPolicies::OLD:
// OLD behavior is to not push a scope at all.
this->NoPolicyScope = true;
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
// We should never make this policy required, but we handle it
// here just in case.
this->CheckCMP0011 = true;
case cmPolicies::NEW:
// NEW behavior is to push a (strong) scope.
this->Makefile->PushPolicy();
break;
}
}
}
cmMakefile::IncludeScope::~IncludeScope()
{
if (!this->NoPolicyScope) {
// If we need to enforce policy CMP0011 then the top entry is the
// one we pushed above. If the entry is empty, then the included
// script did not set any policies that might affect the includer so
// we do not need to enforce the policy.
if (this->CheckCMP0011 &&
!this->Makefile->StateSnapshot.HasDefinedPolicyCMP0011()) {
this->CheckCMP0011 = false;
}
// Pop the scope we pushed for the script.
this->Makefile->PopPolicy();
// We enforce the policy after the script's policy stack entry has
// been removed.
if (this->CheckCMP0011) {
this->EnforceCMP0011();
}
}
this->Makefile->PopSnapshot(this->ReportError);
this->Makefile->PopFunctionBlockerBarrier(this->ReportError);
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
this->Makefile->Backtrace = this->Makefile->Backtrace.Pop();
}
void cmMakefile::IncludeScope::EnforceCMP0011()
{
// We check the setting of this policy again because the included
// script might actually set this policy for its includer.
switch (this->Makefile->GetPolicyStatus(cmPolicies::CMP0011)) {
case cmPolicies::WARN:
// Warn because the user did not set this policy.
{
std::ostringstream w;
w << cmPolicies::GetPolicyWarning(cmPolicies::CMP0011) << "\n"
<< "The included script\n "
<< this->Makefile->GetExecutionFilePath() << "\n"
<< "affects policy settings. "
<< "CMake is implying the NO_POLICY_SCOPE option for compatibility, "
<< "so the effects are applied to the including context.";
this->Makefile->IssueMessage(cmake::AUTHOR_WARNING, w.str());
}
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS: {
std::ostringstream e;
/* clang-format off */
2015-05-03 11:12:10 +03:00
e << cmPolicies::GetRequiredPolicyError(cmPolicies::CMP0011) << "\n"
<< "The included script\n "
<< this->Makefile->GetExecutionFilePath() << "\n"
<< "affects policy settings, so it requires this policy to be set.";
/* clang-format on */
this->Makefile->IssueMessage(cmake::FATAL_ERROR, e.str());
} break;
case cmPolicies::OLD:
case cmPolicies::NEW:
// The script set this policy. We assume the purpose of the
// script is to initialize policies for its includer, and since
// the policy is now set for later scripts, we do not warn.
break;
}
}
2015-06-21 21:02:16 +03:00
bool cmMakefile::ReadDependentFile(const char* filename, bool noPolicyScope)
{
this->AddDefinition("CMAKE_PARENT_LIST_FILE",
this->GetDefinition("CMAKE_CURRENT_LIST_FILE"));
std::string filenametoread = cmSystemTools::CollapseFullPath(
filename, this->GetCurrentSourceDirectory());
IncludeScope incScope(this, filenametoread, noPolicyScope);
cmListFile listFile;
if (!listFile.ParseFile(filenametoread.c_str(), false, this)) {
return false;
}
this->ReadListFile(listFile, filenametoread);
if (cmSystemTools::GetFatalErrorOccured()) {
incScope.Quiet();
}
return true;
}
class cmMakefile::ListFileScope
{
public:
ListFileScope(cmMakefile* mf, std::string const& filenametoread)
: Makefile(mf)
, ReportError(true)
{
this->Makefile->Backtrace = this->Makefile->Backtrace.Push(filenametoread);
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
this->Makefile->StateSnapshot =
this->Makefile->GetState()->CreateInlineListFileSnapshot(
this->Makefile->StateSnapshot, filenametoread);
assert(this->Makefile->StateSnapshot.IsValid());
this->Makefile->PushFunctionBlockerBarrier();
}
~ListFileScope()
{
this->Makefile->PopSnapshot(this->ReportError);
this->Makefile->PopFunctionBlockerBarrier(this->ReportError);
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
2016-04-14 18:24:08 +03:00
this->Makefile->Backtrace = this->Makefile->Backtrace.Pop();
}
void Quiet() { this->ReportError = false; }
private:
cmMakefile* Makefile;
bool ReportError;
};
2015-06-21 21:02:16 +03:00
bool cmMakefile::ReadListFile(const char* filename)
{
std::string filenametoread = cmSystemTools::CollapseFullPath(
filename, this->GetCurrentSourceDirectory());
ListFileScope scope(this, filenametoread);
cmListFile listFile;
if (!listFile.ParseFile(filenametoread.c_str(), false, this)) {
return false;
}
this->ReadListFile(listFile, filenametoread);
if (cmSystemTools::GetFatalErrorOccured()) {
scope.Quiet();
}
return true;
}
void cmMakefile::ReadListFile(cmListFile const& listFile,
std::string const& filenametoread)
{
// add this list file to the list of dependencies
this->ListFiles.push_back(filenametoread);
std::string currentParentFile =
this->GetSafeDefinition("CMAKE_PARENT_LIST_FILE");
std::string currentFile = this->GetSafeDefinition("CMAKE_CURRENT_LIST_FILE");
this->AddDefinition("CMAKE_CURRENT_LIST_FILE", filenametoread.c_str());
this->AddDefinition("CMAKE_CURRENT_LIST_DIR",
cmSystemTools::GetFilenamePath(filenametoread).c_str());
this->MarkVariableAsUsed("CMAKE_PARENT_LIST_FILE");
this->MarkVariableAsUsed("CMAKE_CURRENT_LIST_FILE");
this->MarkVariableAsUsed("CMAKE_CURRENT_LIST_DIR");
// Run the parsed commands.
2015-06-21 20:38:02 +03:00
const size_t numberFunctions = listFile.Functions.size();
for (size_t i = 0; i < numberFunctions; ++i) {
cmExecutionStatus status;
this->ExecuteCommand(listFile.Functions[i], status);
if (cmSystemTools::GetFatalErrorOccured()) {
break;
}
if (status.GetReturnInvoked()) {
// Exit early due to return command.
break;
}
}
this->CheckForUnusedVariables();
this->AddDefinition("CMAKE_PARENT_LIST_FILE", currentParentFile.c_str());
this->AddDefinition("CMAKE_CURRENT_LIST_FILE", currentFile.c_str());
this->AddDefinition("CMAKE_CURRENT_LIST_DIR",
cmSystemTools::GetFilenamePath(currentFile).c_str());
this->MarkVariableAsUsed("CMAKE_PARENT_LIST_FILE");
this->MarkVariableAsUsed("CMAKE_CURRENT_LIST_FILE");
this->MarkVariableAsUsed("CMAKE_CURRENT_LIST_DIR");
}
void cmMakefile::EnforceDirectoryLevelRules() const
{
// Diagnose a violation of CMP0000 if necessary.
if (this->CheckCMP0000) {
std::ostringstream msg;
msg << "No cmake_minimum_required command is present. "
<< "A line of code such as\n"
<< " cmake_minimum_required(VERSION " << cmVersion::GetMajorVersion()
<< "." << cmVersion::GetMinorVersion() << ")\n"
<< "should be added at the top of the file. "
<< "The version specified may be lower if you wish to "
<< "support older CMake versions for this project. "
<< "For more information run "
<< "\"cmake --help-policy CMP0000\".";
switch (this->GetPolicyStatus(cmPolicies::CMP0000)) {
case cmPolicies::WARN:
// Warn because the user did not provide a mimimum required
// version.
this->IssueMessage(cmake::AUTHOR_WARNING, msg.str());
case cmPolicies::OLD:
// OLD behavior is to use policy version 2.4 set in
// cmListFileCache.
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::NEW:
// NEW behavior is to issue an error.
this->IssueMessage(cmake::FATAL_ERROR, msg.str());
cmSystemTools::SetFatalErrorOccured();
return;
}
}
}
void cmMakefile::AddEvaluationFile(
const std::string& inputFile,
cmsys::auto_ptr<cmCompiledGeneratorExpression> outputName,
cmsys::auto_ptr<cmCompiledGeneratorExpression> condition,
bool inputIsContent)
{
this->EvaluationFiles.push_back(new cmGeneratorExpressionEvaluationFile(
inputFile, outputName, condition, inputIsContent));
}
std::vector<cmGeneratorExpressionEvaluationFile*>
cmMakefile::GetEvaluationFiles() const
{
return this->EvaluationFiles;
}
std::vector<cmExportBuildFileGenerator*>
cmMakefile::GetExportBuildFileGenerators() const
{
return this->ExportBuildFileGenerators;
}
void cmMakefile::RemoveExportBuildFileGeneratorCMP0024(
cmExportBuildFileGenerator* gen)
{
std::vector<cmExportBuildFileGenerator*>::iterator it =
std::find(this->ExportBuildFileGenerators.begin(),
this->ExportBuildFileGenerators.end(), gen);
if (it != this->ExportBuildFileGenerators.end()) {
this->ExportBuildFileGenerators.erase(it);
}
}
void cmMakefile::AddExportBuildFileGenerator(cmExportBuildFileGenerator* gen)
{
this->ExportBuildFileGenerators.push_back(gen);
}
namespace {
struct file_not_persistent
{
bool operator()(const std::string& path) const
{
return !(path.find("CMakeTmp") == path.npos &&
cmSystemTools::FileExists(path.c_str()));
}
};
}
void cmMakefile::FinalPass()
{
// do all the variable expansions here
this->ExpandVariablesCMP0019();
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// give all the commands a chance to do something
// after the file has been parsed before generation
for (std::vector<cmCommand*>::iterator i = this->FinalPassCommands.begin();
i != this->FinalPassCommands.end(); ++i) {
(*i)->FinalPass();
}
// go through all configured files and see which ones still exist.
// we don't want cmake to re-run if a configured file is created and deleted
// during processing as that would make it a transient file that can't
// influence the build process
// remove_if will move all items that don't have a valid file name to the
// back of the vector
std::vector<std::string>::iterator new_output_files_end = std::remove_if(
this->OutputFiles.begin(), this->OutputFiles.end(), file_not_persistent());
// we just have to erase all items at the back
this->OutputFiles.erase(new_output_files_end, this->OutputFiles.end());
// if a configured file is used as input for another configured file,
// and then deleted it will show up in the input list files so we
// need to scan those too
std::vector<std::string>::iterator new_list_files_end = std::remove_if(
this->ListFiles.begin(), this->ListFiles.end(), file_not_persistent());
this->ListFiles.erase(new_list_files_end, this->ListFiles.end());
}
2005-07-13 19:21:30 +04:00
// Generate the output file
void cmMakefile::ConfigureFinalPass()
{
this->FinalPass();
const char* oldValue = this->GetDefinition("CMAKE_BACKWARDS_COMPATIBILITY");
if (oldValue &&
cmSystemTools::VersionCompare(cmSystemTools::OP_LESS, oldValue, "2.4")) {
this->IssueMessage(
cmake::FATAL_ERROR,
"You have set CMAKE_BACKWARDS_COMPATIBILITY to a CMake version less "
"than 2.4. This version of CMake only supports backwards compatibility "
"with CMake 2.4 or later. For compatibility with older versions please "
"use any CMake 2.8.x release or lower.");
}
}
void cmMakefile::AddCustomCommandToTarget(
const std::string& target, const std::vector<std::string>& byproducts,
const std::vector<std::string>& depends,
const cmCustomCommandLines& commandLines, cmTarget::CustomCommandType type,
const char* comment, const char* workingDir, bool escapeOldStyle,
bool uses_terminal)
2003-06-03 18:30:23 +04:00
{
// Find the target to which to add the custom command.
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cmTargets::iterator ti = this->Targets.find(target);
if (ti == this->Targets.end()) {
cmake::MessageType messageType = cmake::AUTHOR_WARNING;
bool issueMessage = false;
std::ostringstream e;
switch (this->GetPolicyStatus(cmPolicies::CMP0040)) {
case cmPolicies::WARN:
2015-05-03 11:12:10 +03:00
e << cmPolicies::GetPolicyWarning(cmPolicies::CMP0040) << "\n";
issueMessage = true;
case cmPolicies::OLD:
break;
case cmPolicies::NEW:
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
issueMessage = true;
messageType = cmake::FATAL_ERROR;
}
if (issueMessage) {
if (cmTarget const* t = this->FindTargetToUse(target)) {
if (t->IsImported()) {
e << "TARGET '" << target
<< "' is IMPORTED and does not build here.";
} else {
e << "TARGET '" << target << "' was not created in this directory.";
}
} else {
e << "No TARGET '" << target
<< "' has been created in this directory.";
}
IssueMessage(messageType, e.str());
}
return;
}
if (ti->second.GetType() == cmState::OBJECT_LIBRARY) {
std::ostringstream e;
e << "Target \"" << target
<< "\" is an OBJECT library "
"that may not have PRE_BUILD, PRE_LINK, or POST_BUILD commands.";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return;
}
if (ti->second.GetType() == cmState::INTERFACE_LIBRARY) {
std::ostringstream e;
e << "Target \"" << target
<< "\" is an INTERFACE library "
"that may not have PRE_BUILD, PRE_LINK, or POST_BUILD commands.";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return;
}
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
// Always create the byproduct sources and mark them generated.
for (std::vector<std::string>::const_iterator o = byproducts.begin();
o != byproducts.end(); ++o) {
if (cmSourceFile* out = this->GetOrCreateSource(*o, true)) {
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
out->SetProperty("GENERATED", "1");
}
}
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
// Add the command to the appropriate build step for the target.
std::vector<std::string> no_output;
cmCustomCommand cc(this, no_output, byproducts, depends, commandLines,
comment, workingDir);
cc.SetEscapeOldStyle(escapeOldStyle);
cc.SetEscapeAllowMakeVars(true);
cc.SetUsesTerminal(uses_terminal);
switch (type) {
case cmTarget::PRE_BUILD:
ti->second.AddPreBuildCommand(cc);
break;
case cmTarget::PRE_LINK:
ti->second.AddPreLinkCommand(cc);
break;
case cmTarget::POST_BUILD:
ti->second.AddPostBuildCommand(cc);
break;
}
2003-06-03 18:30:23 +04:00
}
cmSourceFile* cmMakefile::AddCustomCommandToOutput(
const std::vector<std::string>& outputs,
const std::vector<std::string>& byproducts,
const std::vector<std::string>& depends, const std::string& main_dependency,
const cmCustomCommandLines& commandLines, const char* comment,
const char* workingDir, bool replace, bool escapeOldStyle,
bool uses_terminal)
2003-06-03 18:30:23 +04:00
{
// Make sure there is at least one output.
if (outputs.empty()) {
cmSystemTools::Error("Attempt to add a custom rule with no output!");
return 0;
}
// Validate custom commands. TODO: More strict?
for (cmCustomCommandLines::const_iterator i = commandLines.begin();
i != commandLines.end(); ++i) {
cmCustomCommandLine const& cl = *i;
if (!cl.empty() && !cl[0].empty() && cl[0][0] == '"') {
std::ostringstream e;
e << "COMMAND may not contain literal quotes:\n " << cl[0] << "\n";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return 0;
}
}
// Choose a source file on which to store the custom command.
cmSourceFile* file = 0;
if (!commandLines.empty() && !main_dependency.empty()) {
// The main dependency was specified. Use it unless a different
// custom command already used it.
file = this->GetSource(main_dependency);
if (file && file->GetCustomCommand() && !replace) {
// The main dependency already has a custom command.
if (commandLines == file->GetCustomCommand()->GetCommandLines()) {
// The existing custom command is identical. Silently ignore
// the duplicate.
return file;
} else {
// The existing custom command is different. We need to
// generate a rule file for this new command.
file = 0;
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}
} else if (!file) {
file = this->CreateSource(main_dependency);
2003-06-03 18:30:23 +04:00
}
}
2003-06-03 18:30:23 +04:00
// Generate a rule file if the main dependency is not available.
if (!file) {
cmGlobalGenerator* gg = this->GetGlobalGenerator();
// Construct a rule file associated with the first output produced.
std::string outName = gg->GenerateRuleFile(outputs[0]);
// Check if the rule file already exists.
file = this->GetSource(outName);
if (file && file->GetCustomCommand() && !replace) {
// The rule file already exists.
if (commandLines != file->GetCustomCommand()->GetCommandLines()) {
cmSystemTools::Error("Attempt to add a custom rule to output \"",
outName.c_str(),
"\" which already has a custom rule.");
2003-06-03 18:30:23 +04:00
}
return file;
}
// Create a cmSourceFile for the rule file.
if (!file) {
file = this->CreateSource(outName, true);
2003-06-03 18:30:23 +04:00
}
file->SetProperty("__CMAKE_RULE", "1");
}
// Always create the output sources and mark them generated.
for (std::vector<std::string>::const_iterator o = outputs.begin();
o != outputs.end(); ++o) {
if (cmSourceFile* out = this->GetOrCreateSource(*o, true)) {
out->SetProperty("GENERATED", "1");
}
}
for (std::vector<std::string>::const_iterator o = byproducts.begin();
o != byproducts.end(); ++o) {
if (cmSourceFile* out = this->GetOrCreateSource(*o, true)) {
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
out->SetProperty("GENERATED", "1");
}
}
// Attach the custom command to the file.
if (file) {
// Construct a complete list of dependencies.
std::vector<std::string> depends2(depends);
if (!main_dependency.empty()) {
depends2.push_back(main_dependency);
}
cmCustomCommand* cc = new cmCustomCommand(
this, outputs, byproducts, depends2, commandLines, comment, workingDir);
cc->SetEscapeOldStyle(escapeOldStyle);
cc->SetEscapeAllowMakeVars(true);
cc->SetUsesTerminal(uses_terminal);
file->SetCustomCommand(cc);
this->UpdateOutputToSourceMap(outputs, file);
}
return file;
2003-06-03 18:30:23 +04:00
}
void cmMakefile::UpdateOutputToSourceMap(
std::vector<std::string> const& outputs, cmSourceFile* source)
{
for (std::vector<std::string>::const_iterator o = outputs.begin();
o != outputs.end(); ++o) {
this->UpdateOutputToSourceMap(*o, source);
}
}
void cmMakefile::UpdateOutputToSourceMap(std::string const& output,
cmSourceFile* source)
{
OutputToSourceMap::iterator i = this->OutputToSource.find(output);
if (i != this->OutputToSource.end()) {
// Multiple custom commands produce the same output but may
// be attached to a different source file (MAIN_DEPENDENCY).
// LinearGetSourceFileWithOutput would return the first one,
// so keep the mapping for the first one.
//
// TODO: Warn the user about this case. However, the VS 8 generator
// triggers it for separate generate.stamp rules in ZERO_CHECK and
// individual targets.
return;
}
this->OutputToSource[output] = source;
}
cmSourceFile* cmMakefile::AddCustomCommandToOutput(
const std::string& output, const std::vector<std::string>& depends,
const std::string& main_dependency, const cmCustomCommandLines& commandLines,
const char* comment, const char* workingDir, bool replace,
bool escapeOldStyle, bool uses_terminal)
{
std::vector<std::string> outputs;
outputs.push_back(output);
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
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std::vector<std::string> no_byproducts;
return this->AddCustomCommandToOutput(
outputs, no_byproducts, depends, main_dependency, commandLines, comment,
workingDir, replace, escapeOldStyle, uses_terminal);
}
void cmMakefile::AddCustomCommandOldStyle(
const std::string& target, const std::vector<std::string>& outputs,
const std::vector<std::string>& depends, const std::string& source,
const cmCustomCommandLines& commandLines, const char* comment)
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{
// Translate the old-style signature to one of the new-style
// signatures.
if (source == target) {
// In the old-style signature if the source and target were the
// same then it added a post-build rule to the target. Preserve
// this behavior.
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
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std::vector<std::string> no_byproducts;
this->AddCustomCommandToTarget(target, no_byproducts, depends,
commandLines, cmTarget::POST_BUILD, comment,
0);
return;
}
2003-06-06 00:45:06 +04:00
// Each output must get its own copy of this rule.
cmsys::RegularExpression sourceFiles("\\.(C|M|c|c\\+\\+|cc|cpp|cxx|m|mm|"
"rc|def|r|odl|idl|hpj|bat|h|h\\+\\+|"
"hm|hpp|hxx|in|txx|inl)$");
for (std::vector<std::string>::const_iterator oi = outputs.begin();
oi != outputs.end(); ++oi) {
// Get the name of this output.
const char* output = oi->c_str();
cmSourceFile* sf;
// Choose whether to use a main dependency.
if (sourceFiles.find(source)) {
// The source looks like a real file. Use it as the main dependency.
sf = this->AddCustomCommandToOutput(output, depends, source,
commandLines, comment, 0);
} else {
// The source may not be a real file. Do not use a main dependency.
std::string no_main_dependency = "";
std::vector<std::string> depends2 = depends;
depends2.push_back(source);
sf = this->AddCustomCommandToOutput(output, depends2, no_main_dependency,
commandLines, comment, 0);
}
// If the rule was added to the source (and not a .rule file),
// then add the source to the target to make sure the rule is
// included.
if (sf && !sf->GetPropertyAsBool("__CMAKE_RULE")) {
if (this->Targets.find(target) != this->Targets.end()) {
this->Targets[target].AddSource(sf->GetFullPath());
} else {
cmSystemTools::Error("Attempt to add a custom rule to a target "
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"that does not exist yet for target ",
target.c_str());
return;
}
}
}
}
cmTarget* cmMakefile::AddUtilityCommand(
const std::string& utilityName, bool excludeFromAll,
const std::vector<std::string>& depends, const char* workingDirectory,
const char* command, const char* arg1, const char* arg2, const char* arg3,
const char* arg4)
{
// Construct the command line for the custom command.
cmCustomCommandLine commandLine;
commandLine.push_back(command);
if (arg1) {
commandLine.push_back(arg1);
}
if (arg2) {
commandLine.push_back(arg2);
}
if (arg3) {
commandLine.push_back(arg3);
}
if (arg4) {
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commandLine.push_back(arg4);
}
cmCustomCommandLines commandLines;
commandLines.push_back(commandLine);
// Call the real signature of this method.
return this->AddUtilityCommand(utilityName, excludeFromAll, workingDirectory,
depends, commandLines);
}
cmTarget* cmMakefile::AddUtilityCommand(
const std::string& utilityName, bool excludeFromAll,
const char* workingDirectory, const std::vector<std::string>& depends,
const cmCustomCommandLines& commandLines, bool escapeOldStyle,
const char* comment, bool uses_terminal)
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
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{
std::vector<std::string> no_byproducts;
return this->AddUtilityCommand(utilityName, excludeFromAll, workingDirectory,
no_byproducts, depends, commandLines,
escapeOldStyle, comment, uses_terminal);
}
cmTarget* cmMakefile::AddUtilityCommand(
const std::string& utilityName, bool excludeFromAll,
const char* workingDirectory, const std::vector<std::string>& byproducts,
const std::vector<std::string>& depends,
const cmCustomCommandLines& commandLines, bool escapeOldStyle,
const char* comment, bool uses_terminal)
{
// Create a target instance for this utility.
cmTarget* target = this->AddNewTarget(cmState::UTILITY, utilityName);
if (excludeFromAll) {
target->SetProperty("EXCLUDE_FROM_ALL", "TRUE");
}
if (!comment) {
// Use an empty comment to avoid generation of default comment.
comment = "";
}
// Store the custom command in the target.
if (!commandLines.empty() || !depends.empty()) {
std::string force = this->GetCurrentBinaryDirectory();
force += cmake::GetCMakeFilesDirectory();
force += "/";
force += utilityName;
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
std::vector<std::string> forced;
forced.push_back(force);
std::string no_main_dependency = "";
bool no_replace = false;
this->AddCustomCommandToOutput(
forced, byproducts, depends, no_main_dependency, commandLines, comment,
workingDirectory, no_replace, escapeOldStyle, uses_terminal);
cmSourceFile* sf = target->AddSourceCMP0049(force);
// The output is not actually created so mark it symbolic.
if (sf) {
sf->SetProperty("SYMBOLIC", "1");
} else {
cmSystemTools::Error("Could not get source file entry for ",
force.c_str());
}
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
// Always create the byproduct sources and mark them generated.
for (std::vector<std::string>::const_iterator o = byproducts.begin();
o != byproducts.end(); ++o) {
if (cmSourceFile* out = this->GetOrCreateSource(*o, true)) {
Add an option for explicit BYPRODUCTS of custom commands (#14963) A common idiom in CMake-based build systems is to have custom commands that generate files not listed explicitly as outputs so that these files do not have to be newer than the inputs. The file modification times of such "byproducts" are updated only when their content changes. Then other build rules can depend on the byproducts explicitly so that their dependents rebuild when the content of the original byproducts really does change. This "undeclared byproduct" approach is necessary for Makefile, VS, and Xcode build tools because if a byproduct were listed as an output of a rule then the rule would always rerun when the input is newer than the byproduct but the byproduct may never be updated. Ninja solves this problem by offering a 'restat' feature to check whether an output was really modified after running a rule and tracking the fact that it is up to date separately from its timestamp. However, Ninja also stats all dependencies up front and will only restat files that are listed as outputs of rules with the 'restat' option enabled. Therefore an undeclared byproduct that does not exist at the start of the build will be considered missing and the build will fail even if other dependencies would cause the byproduct to be available before its dependents build. CMake works around this limitation by adding 'phony' build rules for custom command dependencies in the build tree that do not have any explicit specification of what produces them. This is not optimal because it prevents Ninja from reporting an error when an input to a rule really is missing. A better approach is to allow projects to explicitly specify the byproducts of their custom commands so that no phony rules are needed for them. In order to work with the non-Ninja generators, the byproducts must be known separately from the outputs. Add a new "BYPRODUCTS" option to the add_custom_command and add_custom_target commands to specify byproducts explicitly. Teach the Ninja generator to specify byproducts as outputs of the custom commands. In the case of POST_BUILD, PRE_LINK, and PRE_BUILD events on targets that link, the byproducts must be specified as outputs of the link rule that runs the commands. Activate 'restat' for such rules so that Ninja knows it needs to check the byproducts, but not for link rules that have no byproducts.
2014-11-14 02:54:52 +03:00
out->SetProperty("GENERATED", "1");
}
}
}
return target;
}
void cmMakefile::AddDefineFlag(const char* flag)
{
if (!flag) {
return;
}
// Update the string used for the old DEFINITIONS property.
this->AddDefineFlag(flag, this->DefineFlagsOrig);
// If this is really a definition, update COMPILE_DEFINITIONS.
if (this->ParseDefineFlag(flag, false)) {
return;
}
// Add this flag that does not look like a definition.
this->AddDefineFlag(flag, this->DefineFlags);
}
void cmMakefile::AddDefineFlag(const char* flag, std::string& dflags)
{
// remove any \n\r
std::string::size_type initSize = dflags.size();
dflags += std::string(" ") + flag;
std::string::iterator flagStart = dflags.begin() + initSize + 1;
std::replace(flagStart, dflags.end(), '\n', ' ');
std::replace(flagStart, dflags.end(), '\r', ' ');
}
void cmMakefile::RemoveDefineFlag(const char* flag)
{
// Check the length of the flag to remove.
std::string::size_type len = strlen(flag);
if (len < 1) {
return;
}
// Update the string used for the old DEFINITIONS property.
this->RemoveDefineFlag(flag, len, this->DefineFlagsOrig);
// If this is really a definition, update COMPILE_DEFINITIONS.
if (this->ParseDefineFlag(flag, true)) {
return;
}
// Remove this flag that does not look like a definition.
this->RemoveDefineFlag(flag, len, this->DefineFlags);
}
void cmMakefile::RemoveDefineFlag(const char* flag, std::string::size_type len,
std::string& dflags)
{
// Remove all instances of the flag that are surrounded by
// whitespace or the beginning/end of the string.
for (std::string::size_type lpos = dflags.find(flag, 0);
lpos != std::string::npos; lpos = dflags.find(flag, lpos)) {
std::string::size_type rpos = lpos + len;
if ((lpos <= 0 || isspace(dflags[lpos - 1])) &&
(rpos >= dflags.size() || isspace(dflags[rpos]))) {
dflags.erase(lpos, len);
} else {
++lpos;
}
}
}
void cmMakefile::AddCompileOption(const char* option)
{
this->AppendProperty("COMPILE_OPTIONS", option);
}
bool cmMakefile::ParseDefineFlag(std::string const& def, bool remove)
{
// Create a regular expression to match valid definitions.
static cmsys::RegularExpression valid("^[-/]D[A-Za-z_][A-Za-z0-9_]*(=.*)?$");
// Make sure the definition matches.
if (!valid.find(def.c_str())) {
return false;
}
// Definitions with non-trivial values require a policy check.
static cmsys::RegularExpression trivial(
"^[-/]D[A-Za-z_][A-Za-z0-9_]*(=[A-Za-z0-9_.]+)?$");
if (!trivial.find(def.c_str())) {
// This definition has a non-trivial value.
switch (this->GetPolicyStatus(cmPolicies::CMP0005)) {
case cmPolicies::WARN:
this->IssueMessage(cmake::AUTHOR_WARNING,
cmPolicies::GetPolicyWarning(cmPolicies::CMP0005));
case cmPolicies::OLD:
// OLD behavior is to not escape the value. We should not
// convert the definition to use the property.
return false;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
this->IssueMessage(
cmake::FATAL_ERROR,
cmPolicies::GetRequiredPolicyError(cmPolicies::CMP0005));
return false;
case cmPolicies::NEW:
// NEW behavior is to escape the value. Proceed to convert it
// to an entry in the property.
break;
}
}
// Get the definition part after the flag.
const char* define = def.c_str() + 2;
if (remove) {
if (const char* cdefs = this->GetProperty("COMPILE_DEFINITIONS")) {
// Expand the list.
std::vector<std::string> defs;
cmSystemTools::ExpandListArgument(cdefs, defs);
// Recompose the list without the definition.
std::vector<std::string>::const_iterator defEnd =
std::remove(defs.begin(), defs.end(), define);
std::vector<std::string>::const_iterator defBegin = defs.begin();
std::string ndefs = cmJoin(cmMakeRange(defBegin, defEnd), ";");
// Store the new list.
this->SetProperty("COMPILE_DEFINITIONS", ndefs.c_str());
}
} else {
// Append the definition to the directory property.
this->AppendProperty("COMPILE_DEFINITIONS", define);
}
return true;
}
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void cmMakefile::AddLinkLibrary(const std::string& lib,
cmTargetLinkLibraryType llt)
2001-04-27 00:22:53 +04:00
{
cmTarget::LibraryID tmp;
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tmp.first = lib;
tmp.second = llt;
this->LinkLibraries.push_back(tmp);
}
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void cmMakefile::AddLinkLibraryForTarget(const std::string& target,
const std::string& lib,
cmTargetLinkLibraryType llt)
{
2006-03-15 19:02:08 +03:00
cmTargets::iterator i = this->Targets.find(target);
if (i != this->Targets.end()) {
cmTarget* tgt = this->GetGlobalGenerator()->FindTarget(lib);
if (tgt) {
// if it is not a static or shared library then you can not link to it
if (!((tgt->GetType() == cmState::STATIC_LIBRARY) ||
(tgt->GetType() == cmState::SHARED_LIBRARY) ||
(tgt->GetType() == cmState::INTERFACE_LIBRARY) ||
tgt->IsExecutableWithExports())) {
std::ostringstream e;
e << "Target \"" << lib << "\" of type "
<< cmState::GetTargetTypeName(tgt->GetType())
<< " may not be linked into another target. "
<< "One may link only to STATIC or SHARED libraries, or "
<< "to executables with the ENABLE_EXPORTS property set.";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
}
}
i->second.AddLinkLibrary(*this, target, lib, llt);
} else {
std::ostringstream e;
e << "Attempt to add link library \"" << lib << "\" to target \"" << target
<< "\" which is not built in this directory.";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
}
2001-04-27 00:22:53 +04:00
}
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void cmMakefile::AddLinkDirectoryForTarget(const std::string& target,
const std::string& d)
{
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cmTargets::iterator i = this->Targets.find(target);
if (i != this->Targets.end()) {
if (this->IsAlias(target)) {
std::ostringstream e;
e << "ALIAS target \"" << target << "\" "
<< "may not be linked into another target.";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return;
}
i->second.AddLinkDirectory(d);
} else {
cmSystemTools::Error(
"Attempt to add link directories to non-existent target: ",
target.c_str(), " for directory ", d.c_str());
}
}
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void cmMakefile::AddLinkLibrary(const std::string& lib)
{
this->AddLinkLibrary(lib, GENERAL_LibraryType);
}
void cmMakefile::InitializeFromParent(cmMakefile* parent)
{
this->SystemIncludeDirectories = parent->SystemIncludeDirectories;
// define flags
2006-03-15 19:02:08 +03:00
this->DefineFlags = parent->DefineFlags;
this->DefineFlagsOrig = parent->DefineFlagsOrig;
// Include transform property. There is no per-config version.
{
const char* prop = "IMPLICIT_DEPENDS_INCLUDE_TRANSFORM";
this->SetProperty(prop, parent->GetProperty(prop));
}
// compile definitions property and per-config versions
cmPolicies::PolicyStatus polSt = this->GetPolicyStatus(cmPolicies::CMP0043);
if (polSt == cmPolicies::WARN || polSt == cmPolicies::OLD) {
this->SetProperty("COMPILE_DEFINITIONS",
parent->GetProperty("COMPILE_DEFINITIONS"));
std::vector<std::string> configs;
this->GetConfigurations(configs);
for (std::vector<std::string>::const_iterator ci = configs.begin();
ci != configs.end(); ++ci) {
std::string defPropName = "COMPILE_DEFINITIONS_";
defPropName += cmSystemTools::UpperCase(*ci);
const char* prop = parent->GetProperty(defPropName);
this->SetProperty(defPropName, prop);
}
}
// link libraries
2006-03-15 19:02:08 +03:00
this->LinkLibraries = parent->LinkLibraries;
// link directories
this->SetProperty("LINK_DIRECTORIES",
parent->GetProperty("LINK_DIRECTORIES"));
// the initial project name
this->StateSnapshot.SetProjectName(parent->StateSnapshot.GetProjectName());
// Copy include regular expressions.
2006-03-15 19:02:08 +03:00
this->ComplainFileRegularExpression = parent->ComplainFileRegularExpression;
// Imported targets.
this->ImportedTargets = parent->ImportedTargets;
}
void cmMakefile::PushFunctionScope(std::string const& fileName,
const cmPolicies::PolicyMap& pm)
{
this->StateSnapshot = this->GetState()->CreateFunctionCallSnapshot(
this->StateSnapshot, fileName);
assert(this->StateSnapshot.IsValid());
this->PushLoopBlockBarrier();
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->GetGlobalGenerator()->GetFileLockPool().PushFunctionScope();
#endif
this->PushFunctionBlockerBarrier();
this->PushPolicy(true, pm);
}
void cmMakefile::PopFunctionScope(bool reportError)
{
this->PopPolicy();
this->PopSnapshot(reportError);
this->PopFunctionBlockerBarrier(reportError);
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->GetGlobalGenerator()->GetFileLockPool().PopFunctionScope();
#endif
this->PopLoopBlockBarrier();
this->CheckForUnusedVariables();
}
void cmMakefile::PushMacroScope(std::string const& fileName,
const cmPolicies::PolicyMap& pm)
{
this->StateSnapshot =
this->GetState()->CreateMacroCallSnapshot(this->StateSnapshot, fileName);
assert(this->StateSnapshot.IsValid());
this->PushFunctionBlockerBarrier();
this->PushPolicy(true, pm);
}
void cmMakefile::PopMacroScope(bool reportError)
{
this->PopPolicy();
this->PopSnapshot(reportError);
this->PopFunctionBlockerBarrier(reportError);
}
bool cmMakefile::IsRootMakefile() const
{
return !this->StateSnapshot.GetBuildsystemDirectoryParent().IsValid();
}
class cmMakefile::BuildsystemFileScope
{
public:
BuildsystemFileScope(cmMakefile* mf)
: Makefile(mf)
, ReportError(true)
{
std::string currentStart =
this->Makefile->StateSnapshot.GetDirectory().GetCurrentSource();
currentStart += "/CMakeLists.txt";
this->Makefile->StateSnapshot.SetListFile(currentStart);
this->Makefile->StateSnapshot =
this->Makefile->StateSnapshot.GetState()->CreatePolicyScopeSnapshot(
this->Makefile->StateSnapshot);
this->Makefile->PushFunctionBlockerBarrier();
this->GG = mf->GetGlobalGenerator();
this->CurrentMakefile = this->GG->GetCurrentMakefile();
this->Snapshot = this->GG->GetCMakeInstance()->GetCurrentSnapshot();
this->GG->GetCMakeInstance()->SetCurrentSnapshot(this->Snapshot);
this->GG->SetCurrentMakefile(mf);
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->GG->GetFileLockPool().PushFileScope();
#endif
}
~BuildsystemFileScope()
{
this->Makefile->PopFunctionBlockerBarrier(this->ReportError);
this->Makefile->PopSnapshot(this->ReportError);
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->GG->GetFileLockPool().PopFileScope();
#endif
this->GG->SetCurrentMakefile(this->CurrentMakefile);
this->GG->GetCMakeInstance()->SetCurrentSnapshot(this->Snapshot);
}
void Quiet() { this->ReportError = false; }
private:
cmMakefile* Makefile;
cmGlobalGenerator* GG;
cmMakefile* CurrentMakefile;
cmState::Snapshot Snapshot;
bool ReportError;
};
void cmMakefile::Configure()
{
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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std::string currentStart =
this->StateSnapshot.GetDirectory().GetCurrentSource();
cmListFileBacktrace: Refactor storage to provide efficient value semantics Since commit v3.4.0-rc1~321^2~2 (Genex: Store a backtrace, not a pointer to one, 2015-07-08) we treat cmListFileBacktrace instances as lightweight values. This was true at the time only because the backtrace information was kept in the cmState snapshot hierarchy. However, that forced us to accumulate a lot of otherwise short-lived snapshots just to have the backtrace fields available for reference by cmListFileBacktrace instances. Recent refactoring made backtrace instances independent of the snapshot hierarchy to avoid accumulating short-lived snapshots. This came at the cost of making backtrace values heavy again, leading to lots of string coying and slower execution. Fix this by refactoring cmListFileBacktrace to provide value semantics with efficient shared storage underneath. Teach cmMakefile to maintain its call stack using an instance of cmListFileBacktrace. This approach allows the current backtrace to be efficiently saved whenever it is needed. Also teach cmListFileBacktrace the notion of a file-level scope. This is useful for messages about the whole file (e.g. during parsing) that are not specific to any line within it. Push the CMakeLists.txt scope for each directory and never pop it. This ensures that we always have some context information and simplifies cmMakefile::IssueMessage. Push/pop a file-level scope as each included file is processed. This supersedes cmParseFileScope and improves diagnostic message context information in a few places. Fix the corresponding test cases to expect the improved output.
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currentStart += "/CMakeLists.txt";
// Add the bottom of all backtraces within this directory.
// We will never pop this scope because it should be available
// for messages during the generate step too.
this->Backtrace = this->Backtrace.Push(currentStart);
BuildsystemFileScope scope(this);
// make sure the CMakeFiles dir is there
std::string filesDir = this->StateSnapshot.GetDirectory().GetCurrentBinary();
filesDir += cmake::GetCMakeFilesDirectory();
cmSystemTools::MakeDirectory(filesDir.c_str());
assert(cmSystemTools::FileExists(currentStart.c_str(), true));
this->AddDefinition("CMAKE_PARENT_LIST_FILE", currentStart.c_str());
cmListFile listFile;
if (!listFile.ParseFile(currentStart.c_str(), this->IsRootMakefile(),
this)) {
return;
}
this->ReadListFile(listFile, currentStart);
if (cmSystemTools::GetFatalErrorOccured()) {
scope.Quiet();
}
// at the end handle any old style subdirs
std::vector<cmMakefile*> subdirs = this->UnConfiguredDirectories;
// for each subdir recurse
std::vector<cmMakefile*>::iterator sdi = subdirs.begin();
for (; sdi != subdirs.end(); ++sdi) {
(*sdi)->StateSnapshot.InitializeFromParent_ForSubdirsCommand();
this->ConfigureSubDirectory(*sdi);
}
this->AddCMakeDependFilesFromUser();
}
void cmMakefile::ConfigureSubDirectory(cmMakefile* mf)
{
mf->InitializeFromParent(this);
std::string currentStart = mf->GetCurrentSourceDirectory();
if (this->GetCMakeInstance()->GetDebugOutput()) {
std::string msg = " Entering ";
msg += currentStart;
cmSystemTools::Message(msg.c_str());
}
std::string const currentStartFile = currentStart + "/CMakeLists.txt";
if (!cmSystemTools::FileExists(currentStartFile, true)) {
// The file is missing. Check policy CMP0014.
std::ostringstream e;
/* clang-format off */
e << "The source directory\n"
<< " " << currentStart << "\n"
<< "does not contain a CMakeLists.txt file.";
/* clang-format on */
switch (this->GetPolicyStatus(cmPolicies::CMP0014)) {
case cmPolicies::WARN:
// Print the warning.
/* clang-format off */
e << "\n"
<< "CMake does not support this case but it used "
<< "to work accidentally and is being allowed for "
<< "compatibility."
<< "\n"
<< cmPolicies::GetPolicyWarning(cmPolicies::CMP0014);
/* clang-format on */
this->IssueMessage(cmake::AUTHOR_WARNING, e.str());
case cmPolicies::OLD:
// OLD behavior does not warn.
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
e << "\n" << cmPolicies::GetRequiredPolicyError(cmPolicies::CMP0014);
case cmPolicies::NEW:
// NEW behavior prints the error.
this->IssueMessage(cmake::FATAL_ERROR, e.str());
}
return;
}
// finally configure the subdir
mf->Configure();
if (this->GetCMakeInstance()->GetDebugOutput()) {
std::string msg = " Returning to ";
msg += this->GetCurrentSourceDirectory();
cmSystemTools::Message(msg.c_str());
}
}
void cmMakefile::AddSubDirectory(const std::string& srcPath,
const std::string& binPath,
bool excludeFromAll, bool immediate)
{
// Make sure the binary directory is unique.
if (!this->EnforceUniqueDir(srcPath, binPath)) {
return;
}
cmState::Snapshot newSnapshot =
this->GetState()->CreateBuildsystemDirectorySnapshot(this->StateSnapshot);
newSnapshot.GetDirectory().SetCurrentSource(srcPath);
newSnapshot.GetDirectory().SetCurrentBinary(binPath);
cmSystemTools::MakeDirectory(binPath.c_str());
cmMakefile* subMf = new cmMakefile(this->GlobalGenerator, newSnapshot);
this->GetGlobalGenerator()->AddMakefile(subMf);
if (excludeFromAll) {
subMf->SetProperty("EXCLUDE_FROM_ALL", "TRUE");
}
if (immediate) {
this->ConfigureSubDirectory(subMf);
} else {
this->UnConfiguredDirectories.push_back(subMf);
}
}
const char* cmMakefile::GetCurrentSourceDirectory() const
{
return this->StateSnapshot.GetDirectory().GetCurrentSource();
}
const char* cmMakefile::GetCurrentBinaryDirectory() const
{
return this->StateSnapshot.GetDirectory().GetCurrentBinary();
}
std::vector<cmTarget*> cmMakefile::GetImportedTargets() const
{
std::vector<cmTarget*> tgts;
tgts.reserve(this->ImportedTargets.size());
for (TargetMap::const_iterator it = this->ImportedTargets.begin();
it != this->ImportedTargets.end(); ++it) {
tgts.push_back(it->second);
}
return tgts;
}
void cmMakefile::AddIncludeDirectories(const std::vector<std::string>& incs,
bool before)
{
if (incs.empty()) {
return;
}
cmListFileBacktrace lfbt = this->GetBacktrace();
std::string entryString = cmJoin(incs, ";");
if (before) {
this->StateSnapshot.GetDirectory().PrependIncludeDirectoriesEntry(
entryString, lfbt);
} else {
this->StateSnapshot.GetDirectory().AppendIncludeDirectoriesEntry(
entryString, lfbt);
}
// Property on each target:
for (cmTargets::iterator l = this->Targets.begin(); l != this->Targets.end();
++l) {
cmTarget& t = l->second;
t.InsertInclude(entryString, lfbt, before);
}
}
void cmMakefile::AddSystemIncludeDirectories(const std::set<std::string>& incs)
{
this->SystemIncludeDirectories.insert(incs.begin(), incs.end());
for (cmTargets::iterator l = this->Targets.begin(); l != this->Targets.end();
++l) {
cmTarget& t = l->second;
t.AddSystemIncludeDirectories(incs);
}
}
void cmMakefile::AddDefinition(const std::string& name, const char* value)
{
if (!value) {
return;
}
if (this->VariableInitialized(name)) {
this->LogUnused("changing definition", name);
}
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this->StateSnapshot.SetDefinition(name, value);
#ifdef CMAKE_BUILD_WITH_CMAKE
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cmVariableWatch* vv = this->GetVariableWatch();
if (vv) {
vv->VariableAccessed(name, cmVariableWatch::VARIABLE_MODIFIED_ACCESS,
value, this);
}
#endif
}
void cmMakefile::AddCacheDefinition(const std::string& name, const char* value,
const char* doc,
cmState::CacheEntryType type, bool force)
{
const char* existingValue = this->GetState()->GetInitializedCacheValue(name);
// must be outside the following if() to keep it alive long enough
std::string nvalue;
if (existingValue &&
(this->GetState()->GetCacheEntryType(name) == cmState::UNINITIALIZED)) {
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// if this is not a force, then use the value from the cache
// if it is a force, then use the value being passed in
if (!force) {
value = existingValue;
}
if (type == cmState::PATH || type == cmState::FILEPATH) {
std::vector<std::string>::size_type cc;
std::vector<std::string> files;
nvalue = value ? value : "";
cmSystemTools::ExpandListArgument(nvalue, files);
nvalue = "";
for (cc = 0; cc < files.size(); cc++) {
if (!cmSystemTools::IsOff(files[cc].c_str())) {
files[cc] = cmSystemTools::CollapseFullPath(files[cc]);
}
if (cc > 0) {
nvalue += ";";
}
nvalue += files[cc];
}
this->GetCMakeInstance()->AddCacheEntry(name, nvalue.c_str(), doc, type);
nvalue = this->GetState()->GetInitializedCacheValue(name);
value = nvalue.c_str();
}
}
this->GetCMakeInstance()->AddCacheEntry(name, value, doc, type);
// if there was a definition then remove it
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this->StateSnapshot.RemoveDefinition(name);
}
void cmMakefile::AddDefinition(const std::string& name, bool value)
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{
if (this->VariableInitialized(name)) {
this->LogUnused("changing definition", name);
}
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this->StateSnapshot.SetDefinition(name, value ? "ON" : "OFF");
#ifdef CMAKE_BUILD_WITH_CMAKE
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cmVariableWatch* vv = this->GetVariableWatch();
if (vv) {
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vv->VariableAccessed(name, cmVariableWatch::VARIABLE_MODIFIED_ACCESS,
value ? "ON" : "OFF", this);
}
#endif
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}
void cmMakefile::CheckForUnusedVariables() const
{
if (!this->WarnUnused) {
return;
}
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const std::vector<std::string>& unused = this->StateSnapshot.UnusedKeys();
std::vector<std::string>::const_iterator it = unused.begin();
for (; it != unused.end(); ++it) {
this->LogUnused("out of scope", *it);
}
}
void cmMakefile::MarkVariableAsUsed(const std::string& var)
{
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this->StateSnapshot.GetDefinition(var);
}
bool cmMakefile::VariableInitialized(const std::string& var) const
{
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return this->StateSnapshot.IsInitialized(var);
}
void cmMakefile::LogUnused(const char* reason, const std::string& name) const
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{
if (this->WarnUnused) {
std::string path;
if (!this->ExecutionStatusStack.empty()) {
path = this->GetExecutionContext().FilePath;
} else {
path = this->GetCurrentSourceDirectory();
path += "/CMakeLists.txt";
}
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if (this->CheckSystemVars ||
cmSystemTools::IsSubDirectory(path, this->GetHomeDirectory()) ||
(cmSystemTools::IsSubDirectory(path, this->GetHomeOutputDirectory()) &&
!cmSystemTools::IsSubDirectory(path,
cmake::GetCMakeFilesDirectory()))) {
std::ostringstream msg;
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msg << "unused variable (" << reason << ") \'" << name << "\'";
this->IssueMessage(cmake::AUTHOR_WARNING, msg.str());
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}
}
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}
void cmMakefile::RemoveDefinition(const std::string& name)
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{
if (this->VariableInitialized(name)) {
this->LogUnused("unsetting", name);
}
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this->StateSnapshot.RemoveDefinition(name);
#ifdef CMAKE_BUILD_WITH_CMAKE
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cmVariableWatch* vv = this->GetVariableWatch();
if (vv) {
vv->VariableAccessed(name, cmVariableWatch::VARIABLE_REMOVED_ACCESS, 0,
this);
}
#endif
2002-09-18 18:39:41 +04:00
}
void cmMakefile::RemoveCacheDefinition(const std::string& name)
{
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this->GetState()->RemoveCacheEntry(name);
}
void cmMakefile::SetProjectName(std::string const& p)
{
this->StateSnapshot.SetProjectName(p);
}
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void cmMakefile::AddGlobalLinkInformation(const std::string& name,
cmTarget& target)
{
// for these targets do not add anything
switch (target.GetType()) {
case cmState::UTILITY:
case cmState::GLOBAL_TARGET:
case cmState::INTERFACE_LIBRARY:
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return;
2002-06-19 01:20:27 +04:00
default:;
}
if (const char* linkDirsProp = this->GetProperty("LINK_DIRECTORIES")) {
std::vector<std::string> linkDirs;
cmSystemTools::ExpandListArgument(linkDirsProp, linkDirs);
for (std::vector<std::string>::iterator j = linkDirs.begin();
j != linkDirs.end(); ++j) {
std::string newdir = *j;
// remove trailing slashes
if (*j->rbegin() == '/') {
newdir = j->substr(0, j->size() - 1);
}
if (std::find(this->LinkDirectories.begin(), this->LinkDirectories.end(),
newdir) == this->LinkDirectories.end()) {
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target.AddLinkDirectory(*j);
}
}
}
target.MergeLinkLibraries(*this, name, this->LinkLibraries);
}
void cmMakefile::AddAlias(const std::string& lname, std::string const& tgtName)
{
this->AliasTargets[lname] = tgtName;
this->GetGlobalGenerator()->AddAlias(lname, tgtName);
}
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cmTarget* cmMakefile::AddLibrary(const std::string& lname,
cmState::TargetType type,
const std::vector<std::string>& srcs,
bool excludeFromAll)
{
// wrong type ? default to STATIC
if ((type != cmState::STATIC_LIBRARY) && (type != cmState::SHARED_LIBRARY) &&
(type != cmState::MODULE_LIBRARY) && (type != cmState::OBJECT_LIBRARY) &&
(type != cmState::INTERFACE_LIBRARY)) {
this->IssueMessage(cmake::INTERNAL_ERROR,
"cmMakefile::AddLibrary given invalid target type.");
type = cmState::STATIC_LIBRARY;
}
cmTarget* target = this->AddNewTarget(type, lname);
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// Clear its dependencies. Otherwise, dependencies might persist
// over changes in CMakeLists.txt, making the information stale and
// hence useless.
target->ClearDependencyInformation(*this, lname);
if (excludeFromAll) {
target->SetProperty("EXCLUDE_FROM_ALL", "TRUE");
}
target->AddSources(srcs);
this->AddGlobalLinkInformation(lname, *target);
return target;
}
cmTarget* cmMakefile::AddExecutable(const char* exeName,
const std::vector<std::string>& srcs,
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bool excludeFromAll)
{
cmTarget* target = this->AddNewTarget(cmState::EXECUTABLE, exeName);
if (excludeFromAll) {
target->SetProperty("EXCLUDE_FROM_ALL", "TRUE");
}
target->AddSources(srcs);
this->AddGlobalLinkInformation(exeName, *target);
return target;
}
cmTarget* cmMakefile::AddNewTarget(cmState::TargetType type,
const std::string& name)
{
cmTargets::iterator it =
this->Targets.insert(cmTargets::value_type(name, cmTarget())).first;
cmTarget& target = it->second;
target.SetType(type, name);
target.SetMakefile(this);
this->GetGlobalGenerator()->IndexTarget(&it->second);
return &it->second;
}
cmSourceFile* cmMakefile::LinearGetSourceFileWithOutput(
const std::string& name) const
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{
std::string out;
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// look through all the source files that have custom commands
// and see if the custom command has the passed source file as an output
for (std::vector<cmSourceFile*>::const_iterator i =
this->SourceFiles.begin();
i != this->SourceFiles.end(); ++i) {
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// does this source file have a custom command?
if ((*i)->GetCustomCommand()) {
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// Does the output of the custom command match the source file name?
const std::vector<std::string>& outputs =
(*i)->GetCustomCommand()->GetOutputs();
for (std::vector<std::string>::const_iterator o = outputs.begin();
o != outputs.end(); ++o) {
out = *o;
std::string::size_type pos = out.rfind(name);
// If the output matches exactly
if (pos != out.npos && pos == out.size() - name.size() &&
(pos == 0 || out[pos - 1] == '/')) {
return *i;
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}
}
}
}
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// otherwise return NULL
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return 0;
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}
cmSourceFile* cmMakefile::GetSourceFileWithOutput(
const std::string& name) const
{
// If the queried path is not absolute we use the backward compatible
// linear-time search for an output with a matching suffix.
if (!cmSystemTools::FileIsFullPath(name.c_str())) {
return this->LinearGetSourceFileWithOutput(name);
}
// Otherwise we use an efficient lookup map.
OutputToSourceMap::const_iterator o = this->OutputToSource.find(name);
if (o != this->OutputToSource.end()) {
return (*o).second;
}
return 0;
}
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#if defined(CMAKE_BUILD_WITH_CMAKE)
cmSourceGroup* cmMakefile::GetSourceGroup(
const std::vector<std::string>& name) const
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{
cmSourceGroup* sg = 0;
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// first look for source group starting with the same as the one we want
for (std::vector<cmSourceGroup>::const_iterator sgIt =
this->SourceGroups.begin();
sgIt != this->SourceGroups.end(); ++sgIt) {
std::string sgName = sgIt->GetName();
if (sgName == name[0]) {
sg = const_cast<cmSourceGroup*>(&(*sgIt));
break;
}
}
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if (sg != 0) {
// iterate through its children to find match source group
for (unsigned int i = 1; i < name.size(); ++i) {
sg = sg->LookupChild(name[i].c_str());
if (sg == 0) {
break;
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}
}
}
return sg;
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}
void cmMakefile::AddSourceGroup(const std::string& name, const char* regex)
{
std::vector<std::string> nameVector;
nameVector.push_back(name);
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this->AddSourceGroup(nameVector, regex);
}
void cmMakefile::AddSourceGroup(const std::vector<std::string>& name,
const char* regex)
{
cmSourceGroup* sg = 0;
std::vector<std::string> currentName;
int i = 0;
const int lastElement = static_cast<int>(name.size() - 1);
for (i = lastElement; i >= 0; --i) {
currentName.assign(name.begin(), name.begin() + i + 1);
sg = this->GetSourceGroup(currentName);
if (sg != 0) {
break;
}
}
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// i now contains the index of the last found component
if (i == lastElement) {
// group already exists, replace its regular expression
if (regex && sg) {
// We only want to set the regular expression. If there are already
// source files in the group, we don't want to remove them.
sg->SetGroupRegex(regex);
}
return;
} else if (i == -1) {
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// group does not exist nor belong to any existing group
// add its first component
this->SourceGroups.push_back(cmSourceGroup(name[0].c_str(), regex));
sg = this->GetSourceGroup(currentName);
i = 0; // last component found
}
if (!sg) {
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cmSystemTools::Error("Could not create source group ");
return;
}
// build the whole source group path
for (++i; i <= lastElement; ++i) {
sg->AddChild(cmSourceGroup(name[i].c_str(), 0, sg->GetFullName()));
sg = sg->LookupChild(name[i].c_str());
}
sg->SetGroupRegex(regex);
}
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#endif
static bool mightExpandVariablesCMP0019(const char* s)
{
return s && *s && strstr(s, "${") && strchr(s, '}');
}
void cmMakefile::ExpandVariablesCMP0019()
{
// Drop this ancient compatibility behavior with a policy.
cmPolicies::PolicyStatus pol = this->GetPolicyStatus(cmPolicies::CMP0019);
if (pol != cmPolicies::OLD && pol != cmPolicies::WARN) {
return;
}
std::ostringstream w;
const char* includeDirs = this->GetProperty("INCLUDE_DIRECTORIES");
if (mightExpandVariablesCMP0019(includeDirs)) {
std::string dirs = includeDirs;
this->ExpandVariablesInString(dirs, true, true);
if (pol == cmPolicies::WARN && dirs != includeDirs) {
/* clang-format off */
w << "Evaluated directory INCLUDE_DIRECTORIES\n"
<< " " << includeDirs << "\n"
<< "as\n"
<< " " << dirs << "\n";
/* clang-format on */
}
this->SetProperty("INCLUDE_DIRECTORIES", dirs.c_str());
}
// Also for each target's INCLUDE_DIRECTORIES property:
for (cmTargets::iterator l = this->Targets.begin(); l != this->Targets.end();
++l) {
cmTarget& t = l->second;
if (t.GetType() == cmState::INTERFACE_LIBRARY ||
t.GetType() == cmState::GLOBAL_TARGET) {
continue;
}
includeDirs = t.GetProperty("INCLUDE_DIRECTORIES");
if (mightExpandVariablesCMP0019(includeDirs)) {
std::string dirs = includeDirs;
this->ExpandVariablesInString(dirs, true, true);
if (pol == cmPolicies::WARN && dirs != includeDirs) {
/* clang-format off */
w << "Evaluated target " << t.GetName() << " INCLUDE_DIRECTORIES\n"
<< " " << includeDirs << "\n"
<< "as\n"
<< " " << dirs << "\n";
/* clang-format on */
}
t.SetProperty("INCLUDE_DIRECTORIES", dirs.c_str());
}
}
if (const char* linkDirsProp = this->GetProperty("LINK_DIRECTORIES")) {
if (mightExpandVariablesCMP0019(linkDirsProp)) {
std::string d = linkDirsProp;
std::string orig = linkDirsProp;
this->ExpandVariablesInString(d, true, true);
if (pol == cmPolicies::WARN && d != orig) {
/* clang-format off */
w << "Evaluated link directories\n"
<< " " << orig << "\n"
<< "as\n"
<< " " << d << "\n";
/* clang-format on */
}
}
}
for (cmTarget::LinkLibraryVectorType::iterator l =
this->LinkLibraries.begin();
l != this->LinkLibraries.end(); ++l) {
if (mightExpandVariablesCMP0019(l->first.c_str())) {
std::string orig = l->first;
this->ExpandVariablesInString(l->first, true, true);
if (pol == cmPolicies::WARN && l->first != orig) {
/* clang-format off */
w << "Evaluated link library\n"
<< " " << orig << "\n"
<< "as\n"
<< " " << l->first << "\n";
/* clang-format on */
}
}
}
if (!w.str().empty()) {
std::ostringstream m;
/* clang-format off */
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m << cmPolicies::GetPolicyWarning(cmPolicies::CMP0019)
<< "\n"
<< "The following variable evaluations were encountered:\n"
<< w.str();
/* clang-format on */
this->IssueMessage(cmake::AUTHOR_WARNING, m.str());
}
}
bool cmMakefile::IsOn(const std::string& name) const
{
const char* value = this->GetDefinition(name);
return cmSystemTools::IsOn(value);
}
bool cmMakefile::IsSet(const std::string& name) const
{
const char* value = this->GetDefinition(name);
if (!value) {
return false;
}
if (!*value) {
return false;
}
if (cmSystemTools::IsNOTFOUND(value)) {
return false;
}
return true;
}
bool cmMakefile::PlatformIs64Bit() const
{
if (const char* sizeof_dptr = this->GetDefinition("CMAKE_SIZEOF_VOID_P")) {
return atoi(sizeof_dptr) == 8;
}
return false;
}
bool cmMakefile::PlatformIsAppleIos() const
{
std::string sdkRoot;
sdkRoot = this->GetSafeDefinition("CMAKE_OSX_SYSROOT");
sdkRoot = cmSystemTools::LowerCase(sdkRoot);
const std::string embedded[] = {
"appletvos", "appletvsimulator", "iphoneos",
"iphonesimulator", "watchos", "watchsimulator",
};
for (size_t i = 0; i < sizeof(embedded) / sizeof(embedded[0]); ++i) {
if (sdkRoot.find(embedded[i]) == 0 ||
sdkRoot.find(std::string("/") + embedded[i]) != std::string::npos) {
return true;
}
}
return false;
}
const char* cmMakefile::GetSONameFlag(const std::string& language) const
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
{
std::string name = "CMAKE_SHARED_LIBRARY_SONAME";
if (!language.empty()) {
name += "_";
name += language;
}
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
name += "_FLAG";
return GetDefinition(name);
Support building shared libraries or modules without soname (#13155) Add a boolean target property NO_SONAME which may be used to disable soname for the specified shared library or module even if the platform supports it. This property should be useful for private shared libraries or various plugins which live in private directories and have not been designed to be found or loaded globally. Replace references to <CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG> and hard-coded -install_name flags with a conditional <SONAME_FLAG> which is expanded to the value of the CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG definition as long as soname supports is enabled for the target in question. Keep expanding CMAKE_SHARED_LIBRARY_SONAME_${LANG}_FLAG in rules in case third party projects still use it. Such projects would not yet use NO_SONAME so the adjacent <TARGET_SONAME> will always be expanded. Make <TARGET_INSTALLNAME_DIR> NO_SONAME aware as well. Since -install_name is soname on OS X, this should not be a problem if this variable is expanded only if soname is enabled. The Ninja generator performs rule variable substitution only once globally per rule to put its own placeholders. Final substitution is performed by ninja at build time. Therefore we cannot conditionally replace the soname placeholders on a per-target basis. Rather than omitting $SONAME from rules.ninja, simply do not write its contents for targets which have NO_SONAME. Since 3 variables are affected by NO_SONAME ($SONAME, $SONAME_FLAG, $INSTALLNAME_DIR), set them only if soname is enabled.
2012-04-22 17:42:55 +04:00
}
bool cmMakefile::CanIWriteThisFile(const char* fileName) const
{
if (!this->IsOn("CMAKE_DISABLE_SOURCE_CHANGES")) {
return true;
}
2013-01-22 06:44:08 +04:00
// If we are doing an in-source build, then the test will always fail
if (cmSystemTools::SameFile(this->GetHomeDirectory(),
this->GetHomeOutputDirectory())) {
if (this->IsOn("CMAKE_DISABLE_IN_SOURCE_BUILD")) {
return false;
}
return true;
}
2013-01-22 06:44:08 +04:00
// Check if this is a subdirectory of the source tree but not a
// subdirectory of the build tree
if (cmSystemTools::IsSubDirectory(fileName, this->GetHomeDirectory()) &&
!cmSystemTools::IsSubDirectory(fileName,
this->GetHomeOutputDirectory())) {
return false;
}
return true;
}
const char* cmMakefile::GetRequiredDefinition(const std::string& name) const
2004-08-06 22:51:41 +04:00
{
const char* ret = this->GetDefinition(name);
if (!ret) {
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cmSystemTools::Error("Error required internal CMake variable not "
"set, cmake may be not be built correctly.\n",
"Missing variable is:\n", name.c_str());
2004-08-06 22:51:41 +04:00
return "";
}
2004-08-06 22:51:41 +04:00
return ret;
}
bool cmMakefile::IsDefinitionSet(const std::string& name) const
{
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const char* def = this->StateSnapshot.GetDefinition(name);
if (!def) {
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def = this->GetState()->GetInitializedCacheValue(name);
}
#ifdef CMAKE_BUILD_WITH_CMAKE
if (cmVariableWatch* vv = this->GetVariableWatch()) {
if (!def) {
vv->VariableAccessed(
name, cmVariableWatch::UNKNOWN_VARIABLE_DEFINED_ACCESS, def, this);
}
}
#endif
return def ? true : false;
}
const char* cmMakefile::GetDefinition(const std::string& name) const
{
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const char* def = this->StateSnapshot.GetDefinition(name);
if (!def) {
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def = this->GetState()->GetInitializedCacheValue(name);
}
#ifdef CMAKE_BUILD_WITH_CMAKE
2003-01-08 20:59:52 +03:00
cmVariableWatch* vv = this->GetVariableWatch();
if (vv && !this->SuppressWatches) {
bool const watch_function_executed = vv->VariableAccessed(
name, def ? cmVariableWatch::VARIABLE_READ_ACCESS
: cmVariableWatch::UNKNOWN_VARIABLE_READ_ACCESS,
def, this);
if (watch_function_executed) {
// A callback was executed and may have caused re-allocation of the
// variable storage. Look it up again for now.
// FIXME: Refactor variable storage to avoid this problem.
def = this->StateSnapshot.GetDefinition(name);
if (!def) {
def = this->GetState()->GetInitializedCacheValue(name);
2003-01-08 20:59:52 +03:00
}
}
}
#endif
2003-01-08 20:59:52 +03:00
return def;
}
const char* cmMakefile::GetSafeDefinition(const std::string& def) const
{
const char* ret = this->GetDefinition(def);
if (!ret) {
return "";
}
return ret;
}
std::vector<std::string> cmMakefile::GetDefinitions() const
{
2015-06-21 22:26:43 +03:00
std::vector<std::string> res = this->StateSnapshot.ClosureKeys();
std::vector<std::string> cacheKeys = this->GetState()->GetCacheEntryKeys();
res.insert(res.end(), cacheKeys.begin(), cacheKeys.end());
std::sort(res.begin(), res.end());
return res;
}
const char* cmMakefile::ExpandVariablesInString(std::string& source) const
{
return this->ExpandVariablesInString(source, false, false);
}
const char* cmMakefile::ExpandVariablesInString(
std::string& source, bool escapeQuotes, bool noEscapes, bool atOnly,
const char* filename, long line, bool removeEmpty, bool replaceAt) const
{
bool compareResults = false;
cmake::MessageType mtype = cmake::LOG;
std::string errorstr;
std::string original;
// Sanity check the @ONLY mode.
if (atOnly && (!noEscapes || !removeEmpty)) {
// This case should never be called. At-only is for
// configure-file/string which always does no escapes.
this->IssueMessage(cmake::INTERNAL_ERROR,
"ExpandVariablesInString @ONLY called "
"on something with escapes.");
return source.c_str();
}
// Variables used in the WARN case.
std::string newResult;
std::string newErrorstr;
cmake::MessageType newError = cmake::LOG;
switch (this->GetPolicyStatus(cmPolicies::CMP0053)) {
case cmPolicies::WARN: {
// Save the original string for the warning.
original = source;
newResult = source;
compareResults = true;
// Suppress variable watches to avoid calling hooks twice. Suppress new
// dereferences since the OLD behavior is still what is actually used.
this->SuppressWatches = true;
newError = ExpandVariablesInStringNew(
newErrorstr, newResult, escapeQuotes, noEscapes, atOnly, filename,
line, removeEmpty, replaceAt);
this->SuppressWatches = false;
}
case cmPolicies::OLD:
mtype =
ExpandVariablesInStringOld(errorstr, source, escapeQuotes, noEscapes,
atOnly, filename, line, removeEmpty, true);
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
// Messaging here would be *very* verbose.
case cmPolicies::NEW:
mtype = ExpandVariablesInStringNew(errorstr, source, escapeQuotes,
noEscapes, atOnly, filename, line,
removeEmpty, replaceAt);
break;
}
// If it's an error in either case, just report the error...
if (mtype != cmake::LOG) {
if (mtype == cmake::FATAL_ERROR) {
cmSystemTools::SetFatalErrorOccured();
}
this->IssueMessage(mtype, errorstr);
}
// ...otherwise, see if there's a difference that needs to be warned about.
else if (compareResults && (newResult != source || newError != mtype)) {
std::string msg = cmPolicies::GetPolicyWarning(cmPolicies::CMP0053);
msg += "\n";
std::string msg_input = original;
cmSystemTools::ReplaceString(msg_input, "\n", "\n ");
msg += "For input:\n '";
msg += msg_input;
msg += "'\n";
std::string msg_old = source;
cmSystemTools::ReplaceString(msg_old, "\n", "\n ");
msg += "the old evaluation rules produce:\n '";
msg += msg_old;
msg += "'\n";
if (newError == mtype) {
std::string msg_new = newResult;
cmSystemTools::ReplaceString(msg_new, "\n", "\n ");
msg += "but the new evaluation rules produce:\n '";
msg += msg_new;
msg += "'\n";
} else {
std::string msg_err = newErrorstr;
cmSystemTools::ReplaceString(msg_err, "\n", "\n ");
msg += "but the new evaluation rules produce an error:\n ";
msg += msg_err;
msg += "\n";
}
msg +=
"Using the old result for compatibility since the policy is not set.";
this->IssueMessage(cmake::AUTHOR_WARNING, msg);
}
return source.c_str();
}
cmake::MessageType cmMakefile::ExpandVariablesInStringOld(
std::string& errorstr, std::string& source, bool escapeQuotes,
bool noEscapes, bool atOnly, const char* filename, long line,
bool removeEmpty, bool replaceAt) const
{
// Fast path strings without any special characters.
if (source.find_first_of("$@\\") == source.npos) {
return cmake::LOG;
}
// Special-case the @ONLY mode.
if (atOnly) {
// Store an original copy of the input.
std::string input = source;
// Start with empty output.
source = "";
// Look for one @VAR@ at a time.
const char* in = input.c_str();
while (this->cmAtVarRegex.find(in)) {
// Get the range of the string to replace.
const char* first = in + this->cmAtVarRegex.start();
const char* last = in + this->cmAtVarRegex.end();
// Store the unchanged part of the string now.
source.append(in, first - in);
// Lookup the definition of VAR.
std::string var(first + 1, last - first - 2);
if (const char* val = this->GetDefinition(var)) {
// Store the value in the output escaping as requested.
if (escapeQuotes) {
source.append(cmSystemTools::EscapeQuotes(val));
} else {
source.append(val);
}
}
// Continue looking for @VAR@ further along the string.
in = last;
}
// Append the rest of the unchanged part of the string.
source.append(in);
return cmake::LOG;
}
// This method replaces ${VAR} and @VAR@ where VAR is looked up
// with GetDefinition(), if not found in the map, nothing is expanded.
// It also supports the $ENV{VAR} syntax where VAR is looked up in
// the current environment variables.
cmCommandArgumentParserHelper parser;
parser.SetMakefile(this);
parser.SetLineFile(line, filename);
parser.SetEscapeQuotes(escapeQuotes);
parser.SetNoEscapeMode(noEscapes);
parser.SetReplaceAtSyntax(replaceAt);
parser.SetRemoveEmpty(removeEmpty);
int res = parser.ParseString(source.c_str(), 0);
const char* emsg = parser.GetError();
cmake::MessageType mtype = cmake::LOG;
if (res && !emsg[0]) {
source = parser.GetResult();
} else {
// Construct the main error message.
std::ostringstream error;
error << "Syntax error in cmake code ";
if (filename && line > 0) {
// This filename and line number may be more specific than the
// command context because one command invocation can have
// arguments on multiple lines.
error << "at\n"
<< " " << filename << ":" << line << "\n";
}
error << "when parsing string\n"
<< " " << source << "\n";
error << emsg;
// If the parser failed ("res" is false) then this is a real
// argument parsing error, so the policy applies. Otherwise the
// parser reported an error message without failing because the
// helper implementation is unhappy, which has always reported an
// error.
mtype = cmake::FATAL_ERROR;
if (!res) {
// This is a real argument parsing error. Use policy CMP0010 to
// decide whether it is an error.
switch (this->GetPolicyStatus(cmPolicies::CMP0010)) {
case cmPolicies::WARN:
2015-05-03 11:12:10 +03:00
error << "\n" << cmPolicies::GetPolicyWarning(cmPolicies::CMP0010);
case cmPolicies::OLD:
// OLD behavior is to just warn and continue.
mtype = cmake::AUTHOR_WARNING;
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
error << "\n"
2015-05-03 11:12:10 +03:00
<< cmPolicies::GetRequiredPolicyError(cmPolicies::CMP0010);
case cmPolicies::NEW:
// NEW behavior is to report the error.
break;
}
}
errorstr = error.str();
}
return mtype;
}
typedef enum { NORMAL, ENVIRONMENT, CACHE } t_domain;
struct t_lookup
{
t_lookup()
: domain(NORMAL)
, loc(0)
{
}
t_domain domain;
size_t loc;
};
cmake::MessageType cmMakefile::ExpandVariablesInStringNew(
std::string& errorstr, std::string& source, bool escapeQuotes,
bool noEscapes, bool atOnly, const char* filename, long line,
bool removeEmpty, bool replaceAt) const
{
// This method replaces ${VAR} and @VAR@ where VAR is looked up
// with GetDefinition(), if not found in the map, nothing is expanded.
// It also supports the $ENV{VAR} syntax where VAR is looked up in
// the current environment variables.
const char* in = source.c_str();
const char* last = in;
std::string result;
result.reserve(source.size());
std::vector<t_lookup> openstack;
bool error = false;
bool done = false;
cmake::MessageType mtype = cmake::LOG;
2015-04-06 11:52:45 +03:00
cmState* state = this->GetCMakeInstance()->GetState();
do {
char inc = *in;
switch (inc) {
case '}':
if (!openstack.empty()) {
t_lookup var = openstack.back();
openstack.pop_back();
result.append(last, in - last);
std::string const& lookup = result.substr(var.loc);
const char* value = NULL;
std::string varresult;
static const std::string lineVar = "CMAKE_CURRENT_LIST_LINE";
switch (var.domain) {
case NORMAL:
if (filename && lookup == lineVar) {
std::ostringstream ostr;
ostr << line;
varresult = ostr.str();
} else {
value = this->GetDefinition(lookup);
}
break;
case ENVIRONMENT:
value = cmSystemTools::GetEnv(lookup.c_str());
break;
case CACHE:
2015-04-06 11:52:45 +03:00
value = state->GetCacheEntryValue(lookup);
break;
}
// Get the string we're meant to append to.
if (value) {
if (escapeQuotes) {
varresult = cmSystemTools::EscapeQuotes(value);
} else {
varresult = value;
}
} else if (!removeEmpty) {
// check to see if we need to print a warning
// if strict mode is on and the variable has
// not been "cleared"/initialized with a set(foo ) call
if (this->GetCMakeInstance()->GetWarnUninitialized() &&
!this->VariableInitialized(lookup)) {
if (this->CheckSystemVars ||
cmSystemTools::IsSubDirectory(filename,
this->GetHomeDirectory()) ||
cmSystemTools::IsSubDirectory(
filename, this->GetHomeOutputDirectory())) {
std::ostringstream msg;
msg << "uninitialized variable \'" << lookup << "\'";
this->IssueMessage(cmake::AUTHOR_WARNING, msg.str());
}
}
}
result.replace(var.loc, result.size() - var.loc, varresult);
// Start looking from here on out.
last = in + 1;
}
break;
case '$':
if (!atOnly) {
t_lookup lookup;
const char* next = in + 1;
const char* start = NULL;
char nextc = *next;
if (nextc == '{') {
// Looking for a variable.
start = in + 2;
lookup.domain = NORMAL;
} else if (nextc == '<') {
} else if (!nextc) {
result.append(last, next - last);
last = next;
} else if (cmHasLiteralPrefix(next, "ENV{")) {
// Looking for an environment variable.
start = in + 5;
lookup.domain = ENVIRONMENT;
} else if (cmHasLiteralPrefix(next, "CACHE{")) {
// Looking for a cache variable.
start = in + 7;
lookup.domain = CACHE;
} else {
if (this->cmNamedCurly.find(next)) {
errorstr = "Syntax $" +
std::string(next, this->cmNamedCurly.end()) +
"{} is not supported. Only ${}, $ENV{}, "
"and $CACHE{} are allowed.";
mtype = cmake::FATAL_ERROR;
error = true;
}
}
if (start) {
result.append(last, in - last);
last = start;
in = start - 1;
lookup.loc = result.size();
openstack.push_back(lookup);
}
break;
}
case '\\':
if (!noEscapes) {
const char* next = in + 1;
char nextc = *next;
if (nextc == 't') {
result.append(last, in - last);
result.append("\t");
last = next + 1;
} else if (nextc == 'n') {
result.append(last, in - last);
result.append("\n");
last = next + 1;
} else if (nextc == 'r') {
result.append(last, in - last);
result.append("\r");
last = next + 1;
} else if (nextc == ';' && openstack.empty()) {
// Handled in ExpandListArgument; pass the backslash literally.
} else if (isalnum(nextc) || nextc == '\0') {
errorstr += "Invalid character escape '\\";
if (nextc) {
errorstr += nextc;
errorstr += "'.";
} else {
errorstr += "' (at end of input).";
}
error = true;
} else {
// Take what we've found so far, skipping the escape character.
result.append(last, in - last);
// Start tracking from the next character.
last = in + 1;
}
// Skip the next character since it was escaped, but don't read past
// the end of the string.
if (*last) {
++in;
}
}
break;
case '\n':
// Onto the next line.
++line;
break;
case '\0':
done = true;
break;
case '@':
if (replaceAt) {
const char* nextAt = strchr(in + 1, '@');
if (nextAt && nextAt != in + 1 &&
nextAt ==
in + 1 + strspn(in + 1, "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
"abcdefghijklmnopqrstuvwxyz"
"0123456789/_.+-")) {
std::string variable(in + 1, nextAt - in - 1);
std::string varresult = this->GetSafeDefinition(variable);
if (escapeQuotes) {
varresult = cmSystemTools::EscapeQuotes(varresult);
}
// Skip over the variable.
result.append(last, in - last);
result.append(varresult);
in = nextAt;
last = in + 1;
break;
}
}
// Failed to find a valid @ expansion; treat it as literal.
/* FALLTHROUGH */
default: {
if (!openstack.empty() &&
!(isalnum(inc) || inc == '_' || inc == '/' || inc == '.' ||
inc == '+' || inc == '-')) {
errorstr += "Invalid character (\'";
errorstr += inc;
result.append(last, in - last);
errorstr += "\') in a variable name: "
"'" +
result.substr(openstack.back().loc) + "'";
mtype = cmake::FATAL_ERROR;
error = true;
}
break;
}
}
// Look at the next character.
} while (!error && !done && *++in);
// Check for open variable references yet.
if (!error && !openstack.empty()) {
// There's an open variable reference waiting. Policy CMP0010 flags
// whether this is an error or not. The new parser now enforces
// CMP0010 as well.
errorstr += "There is an unterminated variable reference.";
error = true;
}
if (error) {
std::ostringstream emsg;
emsg << "Syntax error in cmake code ";
if (filename) {
// This filename and line number may be more specific than the
// command context because one command invocation can have
// arguments on multiple lines.
emsg << "at\n"
<< " " << filename << ":" << line << "\n";
}
emsg << "when parsing string\n"
<< " " << source << "\n";
emsg << errorstr;
mtype = cmake::FATAL_ERROR;
errorstr = emsg.str();
} else {
// Append the rest of the unchanged part of the string.
result.append(last);
source = result;
}
return mtype;
}
void cmMakefile::RemoveVariablesInString(std::string& source,
bool atOnly) const
{
if (!atOnly) {
cmsys::RegularExpression var("(\\${[A-Za-z_0-9]*})");
while (var.find(source)) {
source.erase(var.start(), var.end() - var.start());
}
}
if (!atOnly) {
cmsys::RegularExpression varb("(\\$ENV{[A-Za-z_0-9]*})");
while (varb.find(source)) {
source.erase(varb.start(), varb.end() - varb.start());
}
}
cmsys::RegularExpression var2("(@[A-Za-z_0-9]*@)");
while (var2.find(source)) {
source.erase(var2.start(), var2.end() - var2.start());
}
}
2001-02-23 03:24:43 +03:00
std::string cmMakefile::GetConfigurations(std::vector<std::string>& configs,
bool singleConfig) const
{
if (this->GetGlobalGenerator()->IsMultiConfig()) {
if (const char* configTypes =
this->GetDefinition("CMAKE_CONFIGURATION_TYPES")) {
cmSystemTools::ExpandListArgument(configTypes, configs);
}
return "";
} else {
const std::string& buildType = this->GetSafeDefinition("CMAKE_BUILD_TYPE");
if (singleConfig && !buildType.empty()) {
configs.push_back(buildType);
}
return buildType;
}
}
2006-03-22 17:58:11 +03:00
#if defined(CMAKE_BUILD_WITH_CMAKE)
/**
* Find a source group whose regular expression matches the filename
* part of the given source name. Search backward through the list of
* source groups, and take the first matching group found. This way
* non-inherited SOURCE_GROUP commands will have precedence over
* inherited ones.
*/
cmSourceGroup* cmMakefile::FindSourceGroup(
const char* source, std::vector<cmSourceGroup>& groups) const
{
// First search for a group that lists the file explicitly.
for (std::vector<cmSourceGroup>::reverse_iterator sg = groups.rbegin();
sg != groups.rend(); ++sg) {
cmSourceGroup* result = sg->MatchChildrenFiles(source);
if (result) {
return result;
}
}
// Now search for a group whose regex matches the file.
for (std::vector<cmSourceGroup>::reverse_iterator sg = groups.rbegin();
sg != groups.rend(); ++sg) {
cmSourceGroup* result = sg->MatchChildrenRegex(source);
if (result) {
return result;
}
}
// Shouldn't get here, but just in case, return the default group.
return &groups.front();
}
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#endif
bool cmMakefile::IsFunctionBlocked(const cmListFileFunction& lff,
cmExecutionStatus& status)
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{
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// if there are no blockers get out of here
if (this->FunctionBlockers.begin() == this->FunctionBlockers.end()) {
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return false;
}
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// loop over all function blockers to see if any block this command
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// evaluate in reverse, this is critical for balanced IF statements etc
std::vector<cmFunctionBlocker*>::reverse_iterator pos;
for (pos = this->FunctionBlockers.rbegin();
pos != this->FunctionBlockers.rend(); ++pos) {
if ((*pos)->IsFunctionBlocked(lff, *this, status)) {
return true;
}
}
return false;
}
void cmMakefile::PushFunctionBlockerBarrier()
{
this->FunctionBlockerBarriers.push_back(this->FunctionBlockers.size());
}
void cmMakefile::PopFunctionBlockerBarrier(bool reportError)
{
// Remove any extra entries pushed on the barrier.
FunctionBlockersType::size_type barrier =
this->FunctionBlockerBarriers.back();
while (this->FunctionBlockers.size() > barrier) {
cmsys::auto_ptr<cmFunctionBlocker> fb(this->FunctionBlockers.back());
this->FunctionBlockers.pop_back();
if (reportError) {
// Report the context in which the unclosed block was opened.
cmListFileContext const& lfc = fb->GetStartingContext();
std::ostringstream e;
/* clang-format off */
e << "A logical block opening on the line\n"
<< " " << lfc << "\n"
<< "is not closed.";
/* clang-format on */
this->IssueMessage(cmake::FATAL_ERROR, e.str());
reportError = false;
}
}
// Remove the barrier.
this->FunctionBlockerBarriers.pop_back();
}
void cmMakefile::PushLoopBlock()
{
assert(!this->LoopBlockCounter.empty());
this->LoopBlockCounter.top()++;
}
void cmMakefile::PopLoopBlock()
{
assert(!this->LoopBlockCounter.empty());
assert(this->LoopBlockCounter.top() > 0);
this->LoopBlockCounter.top()--;
}
void cmMakefile::PushLoopBlockBarrier()
{
this->LoopBlockCounter.push(0);
}
void cmMakefile::PopLoopBlockBarrier()
{
assert(!this->LoopBlockCounter.empty());
assert(this->LoopBlockCounter.top() == 0);
this->LoopBlockCounter.pop();
}
bool cmMakefile::IsLoopBlock() const
{
assert(!this->LoopBlockCounter.empty());
return !this->LoopBlockCounter.empty() && this->LoopBlockCounter.top() > 0;
}
std::string cmMakefile::GetExecutionFilePath() const
{
assert(this->StateSnapshot.IsValid());
return this->StateSnapshot.GetExecutionListFile();
}
bool cmMakefile::ExpandArguments(std::vector<cmListFileArgument> const& inArgs,
std::vector<std::string>& outArgs,
const char* filename) const
{
std::string efp = this->GetExecutionFilePath();
if (!filename) {
filename = efp.c_str();
}
std::vector<cmListFileArgument>::const_iterator i;
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std::string value;
outArgs.reserve(inArgs.size());
for (i = inArgs.begin(); i != inArgs.end(); ++i) {
// No expansion in a bracket argument.
if (i->Delim == cmListFileArgument::Bracket) {
outArgs.push_back(i->Value);
continue;
}
// Expand the variables in the argument.
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value = i->Value;
this->ExpandVariablesInString(value, false, false, false, filename,
i->Line, false, false);
// If the argument is quoted, it should be one argument.
// Otherwise, it may be a list of arguments.
if (i->Delim == cmListFileArgument::Quoted) {
outArgs.push_back(value);
} else {
cmSystemTools::ExpandListArgument(value, outArgs);
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}
}
return !cmSystemTools::GetFatalErrorOccured();
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}
bool cmMakefile::ExpandArguments(
std::vector<cmListFileArgument> const& inArgs,
std::vector<cmExpandedCommandArgument>& outArgs, const char* filename) const
{
std::string efp = this->GetExecutionFilePath();
if (!filename) {
filename = efp.c_str();
}
std::vector<cmListFileArgument>::const_iterator i;
std::string value;
outArgs.reserve(inArgs.size());
for (i = inArgs.begin(); i != inArgs.end(); ++i) {
// No expansion in a bracket argument.
if (i->Delim == cmListFileArgument::Bracket) {
outArgs.push_back(cmExpandedCommandArgument(i->Value, true));
continue;
}
// Expand the variables in the argument.
value = i->Value;
this->ExpandVariablesInString(value, false, false, false, filename,
i->Line, false, false);
// If the argument is quoted, it should be one argument.
// Otherwise, it may be a list of arguments.
if (i->Delim == cmListFileArgument::Quoted) {
outArgs.push_back(cmExpandedCommandArgument(value, true));
} else {
std::vector<std::string> stringArgs;
cmSystemTools::ExpandListArgument(value, stringArgs);
for (size_t j = 0; j < stringArgs.size(); ++j) {
outArgs.push_back(cmExpandedCommandArgument(stringArgs[j], false));
}
}
}
return !cmSystemTools::GetFatalErrorOccured();
}
void cmMakefile::AddFunctionBlocker(cmFunctionBlocker* fb)
{
if (!this->ExecutionStatusStack.empty()) {
// Record the context in which the blocker is created.
fb->SetStartingContext(this->GetExecutionContext());
}
this->FunctionBlockers.push_back(fb);
}
cmsys::auto_ptr<cmFunctionBlocker> cmMakefile::RemoveFunctionBlocker(
cmFunctionBlocker* fb, const cmListFileFunction& lff)
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{
// Find the function blocker stack barrier for the current scope.
// We only remove a blocker whose index is not less than the barrier.
FunctionBlockersType::size_type barrier = 0;
if (!this->FunctionBlockerBarriers.empty()) {
barrier = this->FunctionBlockerBarriers.back();
}
// Search for the function blocker whose scope this command ends.
for (FunctionBlockersType::size_type i = this->FunctionBlockers.size();
i > barrier; --i) {
std::vector<cmFunctionBlocker*>::iterator pos =
this->FunctionBlockers.begin() + (i - 1);
if (*pos == fb) {
// Warn if the arguments do not match, but always remove.
if (!(*pos)->ShouldRemove(lff, *this)) {
cmListFileContext const& lfc = fb->GetStartingContext();
cmListFileContext closingContext =
cmListFileContext::FromCommandContext(lff, lfc.FilePath);
std::ostringstream e;
/* clang-format off */
e << "A logical block opening on the line\n"
<< " " << lfc << "\n"
<< "closes on the line\n"
<< " " << closingContext << "\n"
<< "with mis-matching arguments.";
/* clang-format on */
this->IssueMessage(cmake::AUTHOR_WARNING, e.str());
}
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cmFunctionBlocker* b = *pos;
this->FunctionBlockers.erase(pos);
return cmsys::auto_ptr<cmFunctionBlocker>(b);
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}
}
return cmsys::auto_ptr<cmFunctionBlocker>();
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}
const char* cmMakefile::GetHomeDirectory() const
{
return this->GetCMakeInstance()->GetHomeDirectory();
}
const char* cmMakefile::GetHomeOutputDirectory() const
{
return this->GetCMakeInstance()->GetHomeOutputDirectory();
}
void cmMakefile::SetScriptModeFile(const char* scriptfile)
{
this->AddDefinition("CMAKE_SCRIPT_MODE_FILE", scriptfile);
}
void cmMakefile::SetArgcArgv(const std::vector<std::string>& args)
{
std::ostringstream strStream;
strStream << args.size();
this->AddDefinition("CMAKE_ARGC", strStream.str().c_str());
// this->MarkVariableAsUsed("CMAKE_ARGC");
for (unsigned int t = 0; t < args.size(); ++t) {
std::ostringstream tmpStream;
tmpStream << "CMAKE_ARGV" << t;
this->AddDefinition(tmpStream.str(), args[t].c_str());
// this->MarkVariableAsUsed(tmpStream.str().c_str());
}
}
cmSourceFile* cmMakefile::GetSource(const std::string& sourceName) const
{
cmSourceFileLocation sfl(this, sourceName);
for (std::vector<cmSourceFile*>::const_iterator sfi =
this->SourceFiles.begin();
sfi != this->SourceFiles.end(); ++sfi) {
cmSourceFile* sf = *sfi;
if (sf->Matches(sfl)) {
return sf;
}
}
return 0;
}
cmSourceFile* cmMakefile::CreateSource(const std::string& sourceName,
bool generated)
{
cmSourceFile* sf = new cmSourceFile(this, sourceName);
if (generated) {
sf->SetProperty("GENERATED", "1");
}
this->SourceFiles.push_back(sf);
return sf;
}
cmSourceFile* cmMakefile::GetOrCreateSource(const std::string& sourceName,
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bool generated)
{
if (cmSourceFile* esf = this->GetSource(sourceName)) {
return esf;
} else {
return this->CreateSource(sourceName, generated);
}
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}
void cmMakefile::EnableLanguage(std::vector<std::string> const& lang,
bool optional)
{
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this->AddDefinition("CMAKE_CFG_INTDIR",
this->GetGlobalGenerator()->GetCMakeCFGIntDir());
this->GetGlobalGenerator()->EnableLanguage(lang, this, optional);
}
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int cmMakefile::TryCompile(const std::string& srcdir,
const std::string& bindir,
const std::string& projectName,
const std::string& targetName, bool fast,
const std::vector<std::string>* cmakeArgs,
std::string& output)
{
this->IsSourceFileTryCompile = fast;
// does the binary directory exist ? If not create it...
if (!cmSystemTools::FileIsDirectory(bindir)) {
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cmSystemTools::MakeDirectory(bindir.c_str());
}
// change to the tests directory and run cmake
// use the cmake object instead of calling cmake
std::string cwd = cmSystemTools::GetCurrentWorkingDirectory();
cmSystemTools::ChangeDirectory(bindir);
// make sure the same generator is used
// use this program as the cmake to be run, it should not
// be run that way but the cmake object requires a vailid path
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cmake cm;
cm.SetIsInTryCompile(true);
cmGlobalGenerator* gg =
cm.CreateGlobalGenerator(this->GetGlobalGenerator()->GetName());
if (!gg) {
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cmSystemTools::Error(
"Internal CMake error, TryCompile bad GlobalGenerator");
// return to the original directory
cmSystemTools::ChangeDirectory(cwd);
this->IsSourceFileTryCompile = false;
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return 1;
}
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cm.SetGlobalGenerator(gg);
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// do a configure
cm.SetHomeDirectory(srcdir);
cm.SetHomeOutputDirectory(bindir);
cm.SetGeneratorPlatform(this->GetCMakeInstance()->GetGeneratorPlatform());
cm.SetGeneratorToolset(this->GetCMakeInstance()->GetGeneratorToolset());
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cm.LoadCache();
if (!gg->IsMultiConfig()) {
if (const char* config =
this->GetDefinition("CMAKE_TRY_COMPILE_CONFIGURATION")) {
// Tell the single-configuration generator which one to use.
// Add this before the user-provided CMake arguments in case
// one of the arguments is -DCMAKE_BUILD_TYPE=...
cm.AddCacheEntry("CMAKE_BUILD_TYPE", config, "Build configuration",
cmState::STRING);
}
}
// if cmake args were provided then pass them in
if (cmakeArgs) {
// FIXME: Workaround to ignore unused CLI variables in try-compile.
//
// Ideally we should use SetArgs to honor options like --warn-unused-vars.
// However, there is a subtle problem when certain arguments are passed to
// a macro wrapping around try_compile or try_run that does not escape
// semicolons in its parameters but just passes ${ARGV} or ${ARGN}. In
// this case a list argument like "-DVAR=a;b" gets split into multiple
// cmake arguments "-DVAR=a" and "b". Currently SetCacheArgs ignores
// argument "b" and uses just "-DVAR=a", leading to a subtle bug in that
// the try_compile or try_run does not get the proper value of VAR. If we
// call SetArgs here then it would treat "b" as the source directory and
// cause an error such as "The source directory .../CMakeFiles/CMakeTmp/b
// does not exist", thus breaking the try_compile or try_run completely.
//
// Strictly speaking the bug is in the wrapper macro because the CMake
// language has always flattened nested lists and the macro should escape
// the semicolons in its arguments before forwarding them. However, this
// bug is so subtle that projects typically work anyway, usually because
// the value VAR=a is sufficient for the try_compile or try_run to get the
// correct result. Calling SetArgs here would break such projects that
// previously built. Instead we work around the issue by never reporting
// unused arguments and ignoring options such as --warn-unused-vars.
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cm.SetWarnUnusedCli(false);
// cm.SetArgs(*cmakeArgs, true);
cm.SetCacheArgs(*cmakeArgs);
}
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// to save time we pass the EnableLanguage info directly
gg->EnableLanguagesFromGenerator(this->GetGlobalGenerator(), this);
if (this->IsOn("CMAKE_SUPPRESS_DEVELOPER_WARNINGS")) {
cm.AddCacheEntry("CMAKE_SUPPRESS_DEVELOPER_WARNINGS", "TRUE", "",
cmState::INTERNAL);
} else {
cm.AddCacheEntry("CMAKE_SUPPRESS_DEVELOPER_WARNINGS", "FALSE", "",
cmState::INTERNAL);
}
if (cm.Configure() != 0) {
cmSystemTools::Error(
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"Internal CMake error, TryCompile configure of cmake failed");
// return to the original directory
cmSystemTools::ChangeDirectory(cwd);
this->IsSourceFileTryCompile = false;
return 1;
}
if (cm.Generate() != 0) {
cmSystemTools::Error(
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"Internal CMake error, TryCompile generation of cmake failed");
// return to the original directory
cmSystemTools::ChangeDirectory(cwd);
this->IsSourceFileTryCompile = false;
return 1;
}
// finally call the generator to actually build the resulting project
int ret = this->GetGlobalGenerator()->TryCompile(
srcdir, bindir, projectName, targetName, fast, output, this);
cmSystemTools::ChangeDirectory(cwd);
this->IsSourceFileTryCompile = false;
return ret;
}
bool cmMakefile::GetIsSourceFileTryCompile() const
{
return this->IsSourceFileTryCompile;
}
cmake* cmMakefile::GetCMakeInstance() const
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{
return this->GlobalGenerator->GetCMakeInstance();
}
cmGlobalGenerator* cmMakefile::GetGlobalGenerator() const
{
return this->GlobalGenerator;
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}
#ifdef CMAKE_BUILD_WITH_CMAKE
cmVariableWatch* cmMakefile::GetVariableWatch() const
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{
if (this->GetCMakeInstance() &&
this->GetCMakeInstance()->GetVariableWatch()) {
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return this->GetCMakeInstance()->GetVariableWatch();
}
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return 0;
}
#endif
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cmState* cmMakefile::GetState() const
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{
return this->GetCMakeInstance()->GetState();
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}
void cmMakefile::DisplayStatus(const char* message, float s) const
{
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cmake* cm = this->GetCMakeInstance();
if (cm->GetWorkingMode() == cmake::FIND_PACKAGE_MODE) {
// don't output any STATUS message in FIND_PACKAGE_MODE, since they will
// directly be fed to the compiler, which will be confused.
return;
}
cm->UpdateProgress(message, s);
}
std::string cmMakefile::GetModulesFile(const char* filename) const
{
std::string result;
// We search the module always in CMAKE_ROOT and in CMAKE_MODULE_PATH,
// and then decide based on the policy setting which one to return.
// See CMP0017 for more details.
// The specific problem was that KDE 4.5.0 installs a
// FindPackageHandleStandardArgs.cmake which doesn't have the new features
// of FPHSA.cmake introduced in CMake 2.8.3 yet, and by setting
// CMAKE_MODULE_PATH also e.g. FindZLIB.cmake from cmake included
// FPHSA.cmake from kdelibs and not from CMake, and tried to use the
// new features, which were not there in the version from kdelibs, and so
// failed ("
std::string moduleInCMakeRoot;
std::string moduleInCMakeModulePath;
// Always search in CMAKE_MODULE_PATH:
const char* cmakeModulePath = this->GetDefinition("CMAKE_MODULE_PATH");
if (cmakeModulePath) {
std::vector<std::string> modulePath;
cmSystemTools::ExpandListArgument(cmakeModulePath, modulePath);
// Look through the possible module directories.
for (std::vector<std::string>::iterator i = modulePath.begin();
i != modulePath.end(); ++i) {
std::string itempl = *i;
cmSystemTools::ConvertToUnixSlashes(itempl);
itempl += "/";
itempl += filename;
if (cmSystemTools::FileExists(itempl.c_str())) {
moduleInCMakeModulePath = itempl;
break;
}
}
}
// Always search in the standard modules location.
moduleInCMakeRoot = cmSystemTools::GetCMakeRoot();
moduleInCMakeRoot += "/Modules/";
moduleInCMakeRoot += filename;
cmSystemTools::ConvertToUnixSlashes(moduleInCMakeRoot);
if (!cmSystemTools::FileExists(moduleInCMakeRoot.c_str())) {
moduleInCMakeRoot = "";
}
// Normally, prefer the files found in CMAKE_MODULE_PATH. Only when the file
// from which we are being called is located itself in CMAKE_ROOT, then
// prefer results from CMAKE_ROOT depending on the policy setting.
result = moduleInCMakeModulePath;
if (result.empty()) {
result = moduleInCMakeRoot;
}
if (!moduleInCMakeModulePath.empty() && !moduleInCMakeRoot.empty()) {
const char* currentFile = this->GetDefinition("CMAKE_CURRENT_LIST_FILE");
std::string mods = cmSystemTools::GetCMakeRoot() + "/Modules/";
if (currentFile && strncmp(currentFile, mods.c_str(), mods.size()) == 0) {
switch (this->GetPolicyStatus(cmPolicies::CMP0017)) {
case cmPolicies::WARN: {
std::ostringstream e;
/* clang-format off */
e << "File " << currentFile << " includes "
<< moduleInCMakeModulePath
<< " (found via CMAKE_MODULE_PATH) which shadows "
<< moduleInCMakeRoot << ". This may cause errors later on .\n"
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<< cmPolicies::GetPolicyWarning(cmPolicies::CMP0017);
/* clang-format on */
this->IssueMessage(cmake::AUTHOR_WARNING, e.str());
// break; // fall through to OLD behaviour
}
case cmPolicies::OLD:
result = moduleInCMakeModulePath;
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::NEW:
result = moduleInCMakeRoot;
break;
}
}
}
return result;
}
void cmMakefile::ConfigureString(const std::string& input, std::string& output,
bool atOnly, bool escapeQuotes) const
{
// Split input to handle one line at a time.
std::string::const_iterator lineStart = input.begin();
while (lineStart != input.end()) {
// Find the end of this line.
std::string::const_iterator lineEnd = lineStart;
while (lineEnd != input.end() && *lineEnd != '\n') {
++lineEnd;
}
// Copy the line.
std::string line(lineStart, lineEnd);
// Skip the newline character.
bool haveNewline = (lineEnd != input.end());
if (haveNewline) {
++lineEnd;
}
// Replace #cmakedefine instances.
if (this->cmDefineRegex.find(line)) {
const char* def = this->GetDefinition(this->cmDefineRegex.match(1));
if (!cmSystemTools::IsOff(def)) {
cmSystemTools::ReplaceString(line, "#cmakedefine", "#define");
output += line;
} else {
output += "/* #undef ";
output += this->cmDefineRegex.match(1);
output += " */";
}
} else if (this->cmDefine01Regex.find(line)) {
const char* def = this->GetDefinition(this->cmDefine01Regex.match(1));
cmSystemTools::ReplaceString(line, "#cmakedefine01", "#define");
output += line;
if (!cmSystemTools::IsOff(def)) {
output += " 1";
} else {
output += " 0";
}
} else {
output += line;
}
if (haveNewline) {
output += "\n";
}
// Move to the next line.
lineStart = lineEnd;
}
// Perform variable replacements.
this->ExpandVariablesInString(output, escapeQuotes, true, atOnly, 0, -1,
true, true);
}
int cmMakefile::ConfigureFile(const char* infile, const char* outfile,
bool copyonly, bool atOnly, bool escapeQuotes,
const cmNewLineStyle& newLine)
{
int res = 1;
if (!this->CanIWriteThisFile(outfile)) {
cmSystemTools::Error("Attempt to write file: ", outfile,
" into a source directory.");
return 0;
}
if (!cmSystemTools::FileExists(infile)) {
cmSystemTools::Error("File ", infile, " does not exist.");
return 0;
}
std::string soutfile = outfile;
std::string sinfile = infile;
this->AddCMakeDependFile(sinfile);
cmSystemTools::ConvertToUnixSlashes(soutfile);
// Re-generate if non-temporary outputs are missing.
// when we finalize the configuration we will remove all
// output files that now don't exist.
this->AddCMakeOutputFile(soutfile);
mode_t perm = 0;
cmSystemTools::GetPermissions(sinfile.c_str(), perm);
std::string::size_type pos = soutfile.rfind('/');
if (pos != std::string::npos) {
std::string path = soutfile.substr(0, pos);
cmSystemTools::MakeDirectory(path.c_str());
}
if (copyonly) {
if (!cmSystemTools::CopyFileIfDifferent(sinfile.c_str(),
soutfile.c_str())) {
return 0;
}
} else {
std::string newLineCharacters;
std::ios_base::openmode omode = std::ios_base::out | std::ios_base::trunc;
if (newLine.IsValid()) {
newLineCharacters = newLine.GetCharacters();
omode |= std::ios::binary;
} else {
newLineCharacters = "\n";
}
std::string tempOutputFile = soutfile;
tempOutputFile += ".tmp";
cmsys::ofstream fout(tempOutputFile.c_str(), omode);
if (!fout) {
cmSystemTools::Error("Could not open file for write in copy operation ",
tempOutputFile.c_str());
cmSystemTools::ReportLastSystemError("");
return 0;
}
cmsys::ifstream fin(sinfile.c_str());
if (!fin) {
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cmSystemTools::Error("Could not open file for read in copy operation ",
sinfile.c_str());
return 0;
}
cmsys::FStream::BOM bom = cmsys::FStream::ReadBOM(fin);
if (bom != cmsys::FStream::BOM_None && bom != cmsys::FStream::BOM_UTF8) {
std::ostringstream e;
e << "File starts with a Byte-Order-Mark that is not UTF-8:\n "
<< sinfile;
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return 0;
}
// rewind to copy BOM to output file
fin.seekg(0);
// now copy input to output and expand variables in the
// input file at the same time
std::string inLine;
std::string outLine;
while (cmSystemTools::GetLineFromStream(fin, inLine)) {
outLine = "";
this->ConfigureString(inLine, outLine, atOnly, escapeQuotes);
fout << outLine.c_str() << newLineCharacters;
}
// close the files before attempting to copy
fin.close();
fout.close();
if (!cmSystemTools::CopyFileIfDifferent(tempOutputFile.c_str(),
soutfile.c_str())) {
res = 0;
} else {
cmSystemTools::SetPermissions(soutfile.c_str(), perm);
}
cmSystemTools::RemoveFile(tempOutputFile);
}
return res;
}
void cmMakefile::SetProperty(const std::string& prop, const char* value)
{
cmListFileBacktrace lfbt = this->GetBacktrace();
this->StateSnapshot.GetDirectory().SetProperty(prop, value, lfbt);
}
void cmMakefile::AppendProperty(const std::string& prop, const char* value,
bool asString)
{
cmListFileBacktrace lfbt = this->GetBacktrace();
this->StateSnapshot.GetDirectory().AppendProperty(prop, value, asString,
lfbt);
}
const char* cmMakefile::GetProperty(const std::string& prop) const
{
return this->StateSnapshot.GetDirectory().GetProperty(prop);
}
const char* cmMakefile::GetProperty(const std::string& prop, bool chain) const
{
return this->StateSnapshot.GetDirectory().GetProperty(prop, chain);
}
bool cmMakefile::GetPropertyAsBool(const std::string& prop) const
{
return cmSystemTools::IsOn(this->GetProperty(prop));
}
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std::vector<std::string> cmMakefile::GetPropertyKeys() const
{
return this->StateSnapshot.GetDirectory().GetPropertyKeys();
}
cmTarget* cmMakefile::FindLocalNonAliasTarget(const std::string& name) const
2005-02-17 00:35:32 +03:00
{
cmTargets::iterator i = this->Targets.find(name);
if (i != this->Targets.end()) {
return &i->second;
}
return 0;
2005-02-17 00:35:32 +03:00
}
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cmTest* cmMakefile::CreateTest(const std::string& testName)
{
cmTest* test = this->GetTest(testName);
if (test) {
return test;
}
test = new cmTest(this);
test->SetName(testName);
this->Tests[testName] = test;
return test;
}
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cmTest* cmMakefile::GetTest(const std::string& testName) const
{
std::map<std::string, cmTest*>::const_iterator mi =
this->Tests.find(testName);
if (mi != this->Tests.end()) {
2014-02-04 06:20:33 +04:00
return mi->second;
}
return 0;
}
void cmMakefile::AddCMakeDependFilesFromUser()
{
std::vector<std::string> deps;
if (const char* deps_str = this->GetProperty("CMAKE_CONFIGURE_DEPENDS")) {
cmSystemTools::ExpandListArgument(deps_str, deps);
}
for (std::vector<std::string>::iterator i = deps.begin(); i != deps.end();
++i) {
if (cmSystemTools::FileIsFullPath(i->c_str())) {
this->AddCMakeDependFile(*i);
} else {
std::string f = this->GetCurrentSourceDirectory();
f += "/";
f += *i;
this->AddCMakeDependFile(f);
}
}
}
std::string cmMakefile::FormatListFileStack() const
{
std::vector<std::string> listFiles;
cmState::Snapshot snp = this->StateSnapshot;
while (snp.IsValid()) {
listFiles.push_back(snp.GetExecutionListFile());
snp = snp.GetCallStackParent();
}
std::reverse(listFiles.begin(), listFiles.end());
std::ostringstream tmp;
size_t depth = listFiles.size();
if (depth > 0) {
std::vector<std::string>::const_iterator it = listFiles.end();
do {
if (depth != listFiles.size()) {
tmp << "\n ";
}
--it;
tmp << "[";
tmp << depth;
tmp << "]\t";
tmp << *it;
depth--;
} while (it != listFiles.begin());
}
return tmp.str();
}
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void cmMakefile::PushScope()
{
this->StateSnapshot =
this->GetState()->CreateVariableScopeSnapshot(this->StateSnapshot);
this->PushLoopBlockBarrier();
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->GetGlobalGenerator()->GetFileLockPool().PushFunctionScope();
#endif
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}
void cmMakefile::PopScope()
{
#if defined(CMAKE_BUILD_WITH_CMAKE)
this->GetGlobalGenerator()->GetFileLockPool().PopFunctionScope();
#endif
this->PopLoopBlockBarrier();
this->CheckForUnusedVariables();
this->PopSnapshot();
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}
void cmMakefile::RaiseScope(const std::string& var, const char* varDef)
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{
if (var.empty()) {
return;
}
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if (!this->StateSnapshot.RaiseScope(var, varDef)) {
std::ostringstream m;
m << "Cannot set \"" << var << "\": current scope has no parent.";
this->IssueMessage(cmake::AUTHOR_WARNING, m.str());
}
2007-12-03 21:35:41 +03:00
}
cmTarget* cmMakefile::AddImportedTarget(const std::string& name,
cmState::TargetType type, bool global)
{
// Create the target.
cmsys::auto_ptr<cmTarget> target(new cmTarget);
target->SetType(type, name);
target->MarkAsImported(global);
target->SetMakefile(this);
// Add to the set of available imported targets.
this->ImportedTargets[name] = target.get();
this->GetGlobalGenerator()->IndexTarget(target.get());
// Transfer ownership to this cmMakefile object.
this->ImportedTargetsOwned.push_back(target.get());
return target.release();
}
cmTarget* cmMakefile::FindTargetToUse(const std::string& name,
bool excludeAliases) const
{
// Look for an imported target. These take priority because they
// are more local in scope and do not have to be globally unique.
TargetMap::const_iterator imported = this->ImportedTargets.find(name);
if (imported != this->ImportedTargets.end()) {
return imported->second;
}
// Look for a target built in this directory.
if (cmTarget* t = this->FindLocalNonAliasTarget(name)) {
return t;
}
// Look for a target built in this project.
return this->GetGlobalGenerator()->FindTarget(name, excludeAliases);
}
bool cmMakefile::IsAlias(const std::string& name) const
{
if (this->AliasTargets.find(name) != this->AliasTargets.end())
return true;
return this->GetGlobalGenerator()->IsAlias(name);
}
bool cmMakefile::EnforceUniqueName(std::string const& name, std::string& msg,
bool isCustom) const
{
if (this->IsAlias(name)) {
std::ostringstream e;
e << "cannot create target \"" << name
<< "\" because an alias with the same name already exists.";
msg = e.str();
return false;
}
if (cmTarget* existing = this->FindTargetToUse(name)) {
// The name given conflicts with an existing target. Produce an
// error in a compatible way.
if (existing->IsImported()) {
// Imported targets were not supported in previous versions.
// This is new code, so we can make it an error.
std::ostringstream e;
e << "cannot create target \"" << name
<< "\" because an imported target with the same name already exists.";
msg = e.str();
return false;
} else {
// target names must be globally unique
switch (this->GetPolicyStatus(cmPolicies::CMP0002)) {
case cmPolicies::WARN:
this->IssueMessage(
cmake::AUTHOR_WARNING,
cmPolicies::GetPolicyWarning(cmPolicies::CMP0002));
case cmPolicies::OLD:
return true;
case cmPolicies::REQUIRED_IF_USED:
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case cmPolicies::REQUIRED_ALWAYS:
this->IssueMessage(
cmake::FATAL_ERROR,
cmPolicies::GetRequiredPolicyError(cmPolicies::CMP0002));
return true;
case cmPolicies::NEW:
break;
}
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// The conflict is with a non-imported target.
// Allow this if the user has requested support.
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cmake* cm = this->GetCMakeInstance();
if (isCustom && existing->GetType() == cmState::UTILITY &&
this != existing->GetMakefile() &&
cm->GetState()->GetGlobalPropertyAsBool(
"ALLOW_DUPLICATE_CUSTOM_TARGETS")) {
return true;
}
// Produce an error that tells the user how to work around the
// problem.
std::ostringstream e;
e << "cannot create target \"" << name
<< "\" because another target with the same name already exists. "
<< "The existing target is ";
switch (existing->GetType()) {
case cmState::EXECUTABLE:
e << "an executable ";
break;
case cmState::STATIC_LIBRARY:
e << "a static library ";
break;
case cmState::SHARED_LIBRARY:
e << "a shared library ";
break;
case cmState::MODULE_LIBRARY:
e << "a module library ";
break;
case cmState::UTILITY:
e << "a custom target ";
break;
case cmState::INTERFACE_LIBRARY:
e << "an interface library ";
break;
default:
break;
}
e << "created in source directory \""
<< existing->GetMakefile()->GetCurrentSourceDirectory() << "\". "
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<< "See documentation for policy CMP0002 for more details.";
msg = e.str();
return false;
}
}
return true;
}
bool cmMakefile::EnforceUniqueDir(const std::string& srcPath,
const std::string& binPath) const
{
// Make sure the binary directory is unique.
cmGlobalGenerator* gg = this->GetGlobalGenerator();
if (gg->BinaryDirectoryIsNew(binPath)) {
return true;
}
std::ostringstream e;
switch (this->GetPolicyStatus(cmPolicies::CMP0013)) {
case cmPolicies::WARN:
// Print the warning.
/* clang-format off */
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e << cmPolicies::GetPolicyWarning(cmPolicies::CMP0013)
<< "\n"
<< "The binary directory\n"
<< " " << binPath << "\n"
<< "is already used to build a source directory. "
<< "This command uses it to build source directory\n"
<< " " << srcPath << "\n"
<< "which can generate conflicting build files. "
<< "CMake does not support this use case but it used "
<< "to work accidentally and is being allowed for "
<< "compatibility.";
/* clang-format on */
this->IssueMessage(cmake::AUTHOR_WARNING, e.str());
case cmPolicies::OLD:
// OLD behavior does not warn.
return true;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
e << cmPolicies::GetRequiredPolicyError(cmPolicies::CMP0013) << "\n";
case cmPolicies::NEW:
// NEW behavior prints the error.
/* clang-format off */
e << "The binary directory\n"
<< " " << binPath << "\n"
<< "is already used to build a source directory. "
<< "It cannot be used to build source directory\n"
<< " " << srcPath << "\n"
<< "Specify a unique binary directory name.";
/* clang-format on */
this->IssueMessage(cmake::FATAL_ERROR, e.str());
break;
}
return false;
}
void cmMakefile::AddQtUiFileWithOptions(cmSourceFile* sf)
{
this->QtUiFilesWithOptions.push_back(sf);
}
std::vector<cmSourceFile*> cmMakefile::GetQtUiFilesWithOptions() const
{
return this->QtUiFilesWithOptions;
}
static std::string const matchVariables[] = {
"CMAKE_MATCH_0", "CMAKE_MATCH_1", "CMAKE_MATCH_2", "CMAKE_MATCH_3",
"CMAKE_MATCH_4", "CMAKE_MATCH_5", "CMAKE_MATCH_6", "CMAKE_MATCH_7",
"CMAKE_MATCH_8", "CMAKE_MATCH_9"
};
static std::string const nMatchesVariable = "CMAKE_MATCH_COUNT";
void cmMakefile::ClearMatches()
{
const char* nMatchesStr = this->GetDefinition(nMatchesVariable);
if (!nMatchesStr) {
return;
}
int nMatches = atoi(nMatchesStr);
for (int i = 0; i <= nMatches; i++) {
std::string const& var = matchVariables[i];
std::string const& s = this->GetSafeDefinition(var);
if (!s.empty()) {
this->AddDefinition(var, "");
this->MarkVariableAsUsed(var);
}
}
this->AddDefinition(nMatchesVariable, "0");
this->MarkVariableAsUsed(nMatchesVariable);
}
void cmMakefile::StoreMatches(cmsys::RegularExpression& re)
{
char highest = 0;
for (int i = 0; i < 10; i++) {
std::string const& m = re.match(i);
if (!m.empty()) {
std::string const& var = matchVariables[i];
this->AddDefinition(var, m.c_str());
this->MarkVariableAsUsed(var);
highest = static_cast<char>('0' + i);
}
}
char nMatches[] = { highest, '\0' };
this->AddDefinition(nMatchesVariable, nMatches);
this->MarkVariableAsUsed(nMatchesVariable);
}
cmState::Snapshot cmMakefile::GetStateSnapshot() const
{
return this->StateSnapshot;
}
const char* cmMakefile::GetDefineFlagsCMP0059() const
{
return this->DefineFlagsOrig.c_str();
}
cmPolicies::PolicyStatus cmMakefile::GetPolicyStatus(
cmPolicies::PolicyID id) const
{
return this->StateSnapshot.GetPolicy(id);
}
bool cmMakefile::PolicyOptionalWarningEnabled(std::string const& var)
{
// Check for an explicit CMAKE_POLICY_WARNING_CMP<NNNN> setting.
if (!var.empty()) {
if (const char* val = this->GetDefinition(var)) {
return cmSystemTools::IsOn(val);
}
}
// Enable optional policy warnings with --debug-output, --trace,
// or --trace-expand.
cmake* cm = this->GetCMakeInstance();
return cm->GetDebugOutput() || cm->GetTrace();
}
bool cmMakefile::SetPolicy(const char* id, cmPolicies::PolicyStatus status)
{
cmPolicies::PolicyID pid;
if (!cmPolicies::GetPolicyID(id, /* out */ pid)) {
std::ostringstream e;
e << "Policy \"" << id << "\" is not known to this version of CMake.";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return false;
}
return this->SetPolicy(pid, status);
}
bool cmMakefile::SetPolicy(cmPolicies::PolicyID id,
cmPolicies::PolicyStatus status)
{
// A REQUIRED_ALWAYS policy may be set only to NEW.
if (status != cmPolicies::NEW &&
cmPolicies::GetPolicyStatus(id) == cmPolicies::REQUIRED_ALWAYS) {
std::string msg = cmPolicies::GetRequiredAlwaysPolicyError(id);
this->IssueMessage(cmake::FATAL_ERROR, msg);
return false;
}
this->StateSnapshot.SetPolicy(id, status);
return true;
}
cmMakefile::PolicyPushPop::PolicyPushPop(cmMakefile* m)
: Makefile(m)
{
this->Makefile->PushPolicy();
}
cmMakefile::PolicyPushPop::~PolicyPushPop()
{
this->Makefile->PopPolicy();
}
void cmMakefile::PushPolicy(bool weak, cmPolicies::PolicyMap const& pm)
{
this->StateSnapshot.PushPolicy(pm, weak);
}
void cmMakefile::PopPolicy()
{
if (!this->StateSnapshot.PopPolicy()) {
this->IssueMessage(cmake::FATAL_ERROR,
"cmake_policy POP without matching PUSH");
}
}
void cmMakefile::PopSnapshot(bool reportError)
{
// cmState::Snapshot manages nested policy scopes within it.
// Since the scope corresponding to the snapshot is closing,
// reject any still-open nested policy scopes with an error.
while (!this->StateSnapshot.CanPopPolicyScope()) {
if (reportError) {
this->IssueMessage(cmake::FATAL_ERROR,
"cmake_policy PUSH without matching POP");
reportError = false;
}
this->PopPolicy();
}
this->StateSnapshot = this->GetState()->Pop(this->StateSnapshot);
assert(this->StateSnapshot.IsValid());
}
bool cmMakefile::SetPolicyVersion(const char* version)
{
return cmPolicies::ApplyPolicyVersion(this, version);
}
bool cmMakefile::HasCMP0054AlreadyBeenReported(
cmListFileContext const& context) const
{
return !this->CMP0054ReportedIds.insert(context).second;
}
void cmMakefile::RecordPolicies(cmPolicies::PolicyMap& pm)
{
/* Record the setting of every policy. */
typedef cmPolicies::PolicyID PolicyID;
for (PolicyID pid = cmPolicies::CMP0000; pid != cmPolicies::CMPCOUNT;
pid = PolicyID(pid + 1)) {
pm.Set(pid, this->GetPolicyStatus(pid));
}
}
bool cmMakefile::IgnoreErrorsCMP0061() const
{
bool ignoreErrors = true;
switch (this->GetPolicyStatus(cmPolicies::CMP0061)) {
case cmPolicies::WARN:
// No warning for this policy!
case cmPolicies::OLD:
break;
case cmPolicies::REQUIRED_IF_USED:
case cmPolicies::REQUIRED_ALWAYS:
case cmPolicies::NEW:
ignoreErrors = false;
break;
}
return ignoreErrors;
}
#define FEATURE_STRING(F) , #F
static const char* const C_FEATURES[] = { 0 FOR_EACH_C_FEATURE(
FEATURE_STRING) };
static const char* const CXX_FEATURES[] = { 0 FOR_EACH_CXX_FEATURE(
FEATURE_STRING) };
#undef FEATURE_STRING
static const char* const C_STANDARDS[] = { "90", "99", "11" };
static const char* const CXX_STANDARDS[] = { "98", "11", "14" };
bool cmMakefile::AddRequiredTargetFeature(cmTarget* target,
const std::string& feature,
std::string* error) const
{
if (cmGeneratorExpression::Find(feature) != std::string::npos) {
target->AppendProperty("COMPILE_FEATURES", feature.c_str());
return true;
}
std::string lang;
if (!this->CompileFeatureKnown(target, feature, lang, error)) {
return false;
}
const char* features = this->CompileFeaturesAvailable(lang, error);
if (!features) {
return false;
}
std::vector<std::string> availableFeatures;
cmSystemTools::ExpandListArgument(features, availableFeatures);
if (std::find(availableFeatures.begin(), availableFeatures.end(), feature) ==
availableFeatures.end()) {
std::ostringstream e;
e << "The compiler feature \"" << feature << "\" is not known to " << lang
<< " compiler\n\""
<< this->GetDefinition("CMAKE_" + lang + "_COMPILER_ID")
<< "\"\nversion "
<< this->GetDefinition("CMAKE_" + lang + "_COMPILER_VERSION") << ".";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return false;
}
target->AppendProperty("COMPILE_FEATURES", feature.c_str());
return lang == "C" ? this->AddRequiredTargetCFeature(target, feature)
: this->AddRequiredTargetCxxFeature(target, feature);
}
bool cmMakefile::CompileFeatureKnown(cmTarget const* target,
const std::string& feature,
std::string& lang,
std::string* error) const
{
assert(cmGeneratorExpression::Find(feature) == std::string::npos);
bool isCFeature =
std::find_if(cmArrayBegin(C_FEATURES) + 1, cmArrayEnd(C_FEATURES),
cmStrCmp(feature)) != cmArrayEnd(C_FEATURES);
if (isCFeature) {
lang = "C";
return true;
}
bool isCxxFeature =
std::find_if(cmArrayBegin(CXX_FEATURES) + 1, cmArrayEnd(CXX_FEATURES),
cmStrCmp(feature)) != cmArrayEnd(CXX_FEATURES);
if (isCxxFeature) {
lang = "CXX";
return true;
}
std::ostringstream e;
if (error) {
e << "specified";
} else {
e << "Specified";
}
e << " unknown feature \"" << feature << "\" for "
"target \""
<< target->GetName() << "\".";
if (error) {
*error = e.str();
} else {
this->IssueMessage(cmake::FATAL_ERROR, e.str());
}
return false;
}
const char* cmMakefile::CompileFeaturesAvailable(const std::string& lang,
std::string* error) const
{
const char* featuresKnown =
this->GetDefinition("CMAKE_" + lang + "_COMPILE_FEATURES");
if (!featuresKnown || !*featuresKnown) {
std::ostringstream e;
if (error) {
e << "no";
} else {
e << "No";
}
e << " known features for " << lang << " compiler\n\""
<< this->GetDefinition("CMAKE_" + lang + "_COMPILER_ID")
<< "\"\nversion "
<< this->GetDefinition("CMAKE_" + lang + "_COMPILER_VERSION") << ".";
if (error) {
*error = e.str();
} else {
this->IssueMessage(cmake::FATAL_ERROR, e.str());
}
return 0;
}
return featuresKnown;
}
bool cmMakefile::HaveStandardAvailable(cmTarget const* target,
std::string const& lang,
const std::string& feature) const
{
return lang == "C" ? this->HaveCStandardAvailable(target, feature)
: this->HaveCxxStandardAvailable(target, feature);
}
bool cmMakefile::HaveCStandardAvailable(cmTarget const* target,
const std::string& feature) const
{
const char* defaultCStandard =
this->GetDefinition("CMAKE_C_STANDARD_DEFAULT");
if (!defaultCStandard) {
std::ostringstream e;
e << "CMAKE_C_STANDARD_DEFAULT is not set. COMPILE_FEATURES support "
"not fully configured for this compiler.";
this->IssueMessage(cmake::INTERNAL_ERROR, e.str());
// Return true so the caller does not try to lookup the default standard.
return true;
}
if (std::find_if(cmArrayBegin(C_STANDARDS), cmArrayEnd(C_STANDARDS),
cmStrCmp(defaultCStandard)) == cmArrayEnd(C_STANDARDS)) {
std::ostringstream e;
e << "The CMAKE_C_STANDARD_DEFAULT variable contains an "
"invalid value: \""
<< defaultCStandard << "\".";
this->IssueMessage(cmake::INTERNAL_ERROR, e.str());
return false;
}
bool needC90 = false;
bool needC99 = false;
bool needC11 = false;
this->CheckNeededCLanguage(feature, needC90, needC99, needC11);
const char* existingCStandard = target->GetProperty("C_STANDARD");
if (!existingCStandard) {
existingCStandard = defaultCStandard;
}
if (std::find_if(cmArrayBegin(C_STANDARDS), cmArrayEnd(C_STANDARDS),
cmStrCmp(existingCStandard)) == cmArrayEnd(C_STANDARDS)) {
std::ostringstream e;
e << "The C_STANDARD property on target \"" << target->GetName()
<< "\" contained an invalid value: \"" << existingCStandard << "\".";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return false;
}
const char* const* existingCIt = existingCStandard
? std::find_if(cmArrayBegin(C_STANDARDS), cmArrayEnd(C_STANDARDS),
cmStrCmp(existingCStandard))
: cmArrayEnd(C_STANDARDS);
if (needC11 && existingCStandard &&
existingCIt < std::find_if(cmArrayBegin(C_STANDARDS),
cmArrayEnd(C_STANDARDS), cmStrCmp("11"))) {
return false;
} else if (needC99 && existingCStandard &&
existingCIt < std::find_if(cmArrayBegin(C_STANDARDS),
cmArrayEnd(C_STANDARDS),
cmStrCmp("99"))) {
return false;
} else if (needC90 && existingCStandard &&
existingCIt < std::find_if(cmArrayBegin(C_STANDARDS),
cmArrayEnd(C_STANDARDS),
cmStrCmp("90"))) {
return false;
}
return true;
}
bool cmMakefile::IsLaterStandard(std::string const& lang,
std::string const& lhs,
std::string const& rhs)
{
if (lang == "C") {
const char* const* rhsIt = std::find_if(
cmArrayBegin(C_STANDARDS), cmArrayEnd(C_STANDARDS), cmStrCmp(rhs));
return std::find_if(rhsIt, cmArrayEnd(C_STANDARDS), cmStrCmp(lhs)) !=
cmArrayEnd(C_STANDARDS);
}
const char* const* rhsIt = std::find_if(
cmArrayBegin(CXX_STANDARDS), cmArrayEnd(CXX_STANDARDS), cmStrCmp(rhs));
return std::find_if(rhsIt, cmArrayEnd(CXX_STANDARDS), cmStrCmp(lhs)) !=
cmArrayEnd(CXX_STANDARDS);
}
bool cmMakefile::HaveCxxStandardAvailable(cmTarget const* target,
const std::string& feature) const
{
const char* defaultCxxStandard =
this->GetDefinition("CMAKE_CXX_STANDARD_DEFAULT");
if (!defaultCxxStandard) {
std::ostringstream e;
e << "CMAKE_CXX_STANDARD_DEFAULT is not set. COMPILE_FEATURES support "
"not fully configured for this compiler.";
this->IssueMessage(cmake::INTERNAL_ERROR, e.str());
// Return true so the caller does not try to lookup the default standard.
return true;
}
if (std::find_if(cmArrayBegin(CXX_STANDARDS), cmArrayEnd(CXX_STANDARDS),
cmStrCmp(defaultCxxStandard)) ==
cmArrayEnd(CXX_STANDARDS)) {
std::ostringstream e;
e << "The CMAKE_CXX_STANDARD_DEFAULT variable contains an "
"invalid value: \""
<< defaultCxxStandard << "\".";
this->IssueMessage(cmake::INTERNAL_ERROR, e.str());
return false;
}
bool needCxx98 = false;
bool needCxx11 = false;
bool needCxx14 = false;
this->CheckNeededCxxLanguage(feature, needCxx98, needCxx11, needCxx14);
const char* existingCxxStandard = target->GetProperty("CXX_STANDARD");
if (!existingCxxStandard) {
existingCxxStandard = defaultCxxStandard;
}
if (std::find_if(cmArrayBegin(CXX_STANDARDS), cmArrayEnd(CXX_STANDARDS),
cmStrCmp(existingCxxStandard)) ==
cmArrayEnd(CXX_STANDARDS)) {
std::ostringstream e;
e << "The CXX_STANDARD property on target \"" << target->GetName()
<< "\" contained an invalid value: \"" << existingCxxStandard << "\".";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return false;
}
const char* const* existingCxxIt = existingCxxStandard
? std::find_if(cmArrayBegin(CXX_STANDARDS), cmArrayEnd(CXX_STANDARDS),
cmStrCmp(existingCxxStandard))
: cmArrayEnd(CXX_STANDARDS);
if (needCxx11 &&
existingCxxIt < std::find_if(cmArrayBegin(CXX_STANDARDS),
cmArrayEnd(CXX_STANDARDS),
cmStrCmp("11"))) {
return false;
} else if (needCxx98 &&
existingCxxIt < std::find_if(cmArrayBegin(CXX_STANDARDS),
cmArrayEnd(CXX_STANDARDS),
cmStrCmp("98"))) {
return false;
}
return true;
}
void cmMakefile::CheckNeededCxxLanguage(const std::string& feature,
bool& needCxx98, bool& needCxx11,
bool& needCxx14) const
{
if (const char* propCxx98 =
this->GetDefinition("CMAKE_CXX98_COMPILE_FEATURES")) {
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(propCxx98, props);
needCxx98 = std::find(props.begin(), props.end(), feature) != props.end();
}
if (const char* propCxx11 =
this->GetDefinition("CMAKE_CXX11_COMPILE_FEATURES")) {
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(propCxx11, props);
needCxx11 = std::find(props.begin(), props.end(), feature) != props.end();
}
if (const char* propCxx14 =
this->GetDefinition("CMAKE_CXX14_COMPILE_FEATURES")) {
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(propCxx14, props);
needCxx14 = std::find(props.begin(), props.end(), feature) != props.end();
}
}
bool cmMakefile::AddRequiredTargetCxxFeature(cmTarget* target,
const std::string& feature) const
{
bool needCxx98 = false;
bool needCxx11 = false;
bool needCxx14 = false;
this->CheckNeededCxxLanguage(feature, needCxx98, needCxx11, needCxx14);
const char* existingCxxStandard = target->GetProperty("CXX_STANDARD");
if (existingCxxStandard) {
if (std::find_if(cmArrayBegin(CXX_STANDARDS), cmArrayEnd(CXX_STANDARDS),
cmStrCmp(existingCxxStandard)) ==
cmArrayEnd(CXX_STANDARDS)) {
std::ostringstream e;
e << "The CXX_STANDARD property on target \"" << target->GetName()
<< "\" contained an invalid value: \"" << existingCxxStandard << "\".";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return false;
}
}
const char* const* existingCxxIt = existingCxxStandard
? std::find_if(cmArrayBegin(CXX_STANDARDS), cmArrayEnd(CXX_STANDARDS),
cmStrCmp(existingCxxStandard))
: cmArrayEnd(CXX_STANDARDS);
bool setCxx98 = needCxx98 && !existingCxxStandard;
bool setCxx11 = needCxx11 && !existingCxxStandard;
bool setCxx14 = needCxx14 && !existingCxxStandard;
if (needCxx14 && existingCxxStandard &&
existingCxxIt < std::find_if(cmArrayBegin(CXX_STANDARDS),
cmArrayEnd(CXX_STANDARDS),
cmStrCmp("14"))) {
setCxx14 = true;
} else if (needCxx11 && existingCxxStandard &&
existingCxxIt < std::find_if(cmArrayBegin(CXX_STANDARDS),
cmArrayEnd(CXX_STANDARDS),
cmStrCmp("11"))) {
setCxx11 = true;
} else if (needCxx98 && existingCxxStandard &&
existingCxxIt < std::find_if(cmArrayBegin(CXX_STANDARDS),
cmArrayEnd(CXX_STANDARDS),
cmStrCmp("98"))) {
setCxx98 = true;
}
if (setCxx14) {
target->SetProperty("CXX_STANDARD", "14");
} else if (setCxx11) {
target->SetProperty("CXX_STANDARD", "11");
} else if (setCxx98) {
target->SetProperty("CXX_STANDARD", "98");
}
return true;
}
void cmMakefile::CheckNeededCLanguage(const std::string& feature,
bool& needC90, bool& needC99,
bool& needC11) const
{
if (const char* propC90 =
this->GetDefinition("CMAKE_C90_COMPILE_FEATURES")) {
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(propC90, props);
needC90 = std::find(props.begin(), props.end(), feature) != props.end();
}
if (const char* propC99 =
this->GetDefinition("CMAKE_C99_COMPILE_FEATURES")) {
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(propC99, props);
needC99 = std::find(props.begin(), props.end(), feature) != props.end();
}
if (const char* propC11 =
this->GetDefinition("CMAKE_C11_COMPILE_FEATURES")) {
std::vector<std::string> props;
cmSystemTools::ExpandListArgument(propC11, props);
needC11 = std::find(props.begin(), props.end(), feature) != props.end();
}
}
bool cmMakefile::AddRequiredTargetCFeature(cmTarget* target,
const std::string& feature) const
{
bool needC90 = false;
bool needC99 = false;
bool needC11 = false;
this->CheckNeededCLanguage(feature, needC90, needC99, needC11);
const char* existingCStandard = target->GetProperty("C_STANDARD");
if (existingCStandard) {
if (std::find_if(cmArrayBegin(C_STANDARDS), cmArrayEnd(C_STANDARDS),
cmStrCmp(existingCStandard)) == cmArrayEnd(C_STANDARDS)) {
std::ostringstream e;
e << "The C_STANDARD property on target \"" << target->GetName()
<< "\" contained an invalid value: \"" << existingCStandard << "\".";
this->IssueMessage(cmake::FATAL_ERROR, e.str());
return false;
}
}
const char* const* existingCIt = existingCStandard
? std::find_if(cmArrayBegin(C_STANDARDS), cmArrayEnd(C_STANDARDS),
cmStrCmp(existingCStandard))
: cmArrayEnd(C_STANDARDS);
bool setC90 = needC90 && !existingCStandard;
bool setC99 = needC99 && !existingCStandard;
bool setC11 = needC11 && !existingCStandard;
if (needC11 && existingCStandard &&
existingCIt < std::find_if(cmArrayBegin(C_STANDARDS),
cmArrayEnd(C_STANDARDS), cmStrCmp("11"))) {
setC11 = true;
} else if (needC99 && existingCStandard &&
existingCIt < std::find_if(cmArrayBegin(C_STANDARDS),
cmArrayEnd(C_STANDARDS),
cmStrCmp("99"))) {
setC99 = true;
} else if (needC90 && existingCStandard &&
existingCIt < std::find_if(cmArrayBegin(C_STANDARDS),
cmArrayEnd(C_STANDARDS),
cmStrCmp("90"))) {
setC90 = true;
}
if (setC11) {
target->SetProperty("C_STANDARD", "11");
} else if (setC99) {
target->SetProperty("C_STANDARD", "99");
} else if (setC90) {
target->SetProperty("C_STANDARD", "90");
}
return true;
}
cmMakefile::FunctionPushPop::FunctionPushPop(cmMakefile* mf,
const std::string& fileName,
cmPolicies::PolicyMap const& pm)
: Makefile(mf)
, ReportError(true)
{
this->Makefile->PushFunctionScope(fileName, pm);
}
cmMakefile::FunctionPushPop::~FunctionPushPop()
{
this->Makefile->PopFunctionScope(this->ReportError);
}
cmMakefile::MacroPushPop::MacroPushPop(cmMakefile* mf,
const std::string& fileName,
const cmPolicies::PolicyMap& pm)
: Makefile(mf)
, ReportError(true)
{
this->Makefile->PushMacroScope(fileName, pm);
}
cmMakefile::MacroPushPop::~MacroPushPop()
{
this->Makefile->PopMacroScope(this->ReportError);
}