llvm-project/clang/lib/Driver/Driver.cpp

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//===--- Driver.cpp - Clang GCC Compatible Driver -------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "clang/Driver/Driver.h"
#include "InputInfo.h"
#include "ToolChains.h"
#include "clang/Basic/Version.h"
#include "clang/Driver/Action.h"
#include "clang/Driver/Compilation.h"
#include "clang/Driver/DriverDiagnostic.h"
#include "clang/Driver/Job.h"
#include "clang/Driver/Options.h"
#include "clang/Driver/Tool.h"
#include "clang/Driver/ToolChain.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/OwningPtr.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/StringSet.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/Option/Arg.h"
#include "llvm/Option/ArgList.h"
#include "llvm/Option/OptSpecifier.h"
#include "llvm/Option/OptTable.h"
#include "llvm/Option/Option.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/PrettyStackTrace.h"
#include "llvm/Support/Program.h"
#include "llvm/Support/raw_ostream.h"
#include <map>
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// FIXME: It would prevent us from including llvm-config.h
// if config.h were included before system_error.h.
#include "clang/Config/config.h"
using namespace clang::driver;
using namespace clang;
using namespace llvm::opt;
Driver::Driver(StringRef ClangExecutable,
StringRef DefaultTargetTriple,
StringRef DefaultImageName,
DiagnosticsEngine &Diags)
: Opts(createDriverOptTable()), Diags(Diags), Mode(GCCMode),
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ClangExecutable(ClangExecutable), SysRoot(DEFAULT_SYSROOT),
UseStdLib(true), DefaultTargetTriple(DefaultTargetTriple),
DefaultImageName(DefaultImageName),
DriverTitle("clang LLVM compiler"),
CCPrintOptionsFilename(0), CCPrintHeadersFilename(0),
CCLogDiagnosticsFilename(0),
CCCPrintBindings(false),
CCPrintHeaders(false), CCLogDiagnostics(false),
CCGenDiagnostics(false), CCCGenericGCCName(""), CheckInputsExist(true),
CCCUsePCH(true), SuppressMissingInputWarning(false) {
Name = llvm::sys::path::stem(ClangExecutable);
Dir = llvm::sys::path::parent_path(ClangExecutable);
// Compute the path to the resource directory.
StringRef ClangResourceDir(CLANG_RESOURCE_DIR);
SmallString<128> P(Dir);
if (ClangResourceDir != "")
llvm::sys::path::append(P, ClangResourceDir);
else
llvm::sys::path::append(P, "..", "lib", "clang", CLANG_VERSION_STRING);
ResourceDir = P.str();
}
Driver::~Driver() {
delete Opts;
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
llvm::DeleteContainerSeconds(ToolChains);
}
void Driver::ParseDriverMode(ArrayRef<const char *> Args) {
const std::string OptName =
getOpts().getOption(options::OPT_driver_mode).getPrefixedName();
for (size_t I = 0, E = Args.size(); I != E; ++I) {
const StringRef Arg = Args[I];
if (!Arg.startswith(OptName))
continue;
const StringRef Value = Arg.drop_front(OptName.size());
const unsigned M = llvm::StringSwitch<unsigned>(Value)
.Case("gcc", GCCMode)
.Case("g++", GXXMode)
.Case("cpp", CPPMode)
.Case("cl", CLMode)
.Default(~0U);
if (M != ~0U)
Mode = static_cast<DriverMode>(M);
else
Diag(diag::err_drv_unsupported_option_argument) << OptName << Value;
}
}
InputArgList *Driver::ParseArgStrings(ArrayRef<const char *> ArgList) {
llvm::PrettyStackTraceString CrashInfo("Command line argument parsing");
unsigned IncludedFlagsBitmask;
unsigned ExcludedFlagsBitmask;
std::tie(IncludedFlagsBitmask, ExcludedFlagsBitmask) =
getIncludeExcludeOptionFlagMasks();
unsigned MissingArgIndex, MissingArgCount;
InputArgList *Args = getOpts().ParseArgs(ArgList.begin(), ArgList.end(),
MissingArgIndex, MissingArgCount,
IncludedFlagsBitmask,
ExcludedFlagsBitmask);
// Check for missing argument error.
if (MissingArgCount)
Diag(clang::diag::err_drv_missing_argument)
<< Args->getArgString(MissingArgIndex) << MissingArgCount;
// Check for unsupported options.
for (ArgList::const_iterator it = Args->begin(), ie = Args->end();
it != ie; ++it) {
Arg *A = *it;
if (A->getOption().hasFlag(options::Unsupported)) {
Diag(clang::diag::err_drv_unsupported_opt) << A->getAsString(*Args);
continue;
}
// Warn about -mcpu= without an argument.
if (A->getOption().matches(options::OPT_mcpu_EQ) &&
A->containsValue("")) {
Diag(clang::diag::warn_drv_empty_joined_argument) <<
A->getAsString(*Args);
}
}
for (arg_iterator it = Args->filtered_begin(options::OPT_UNKNOWN),
ie = Args->filtered_end(); it != ie; ++it) {
Diags.Report(diag::err_drv_unknown_argument) << (*it) ->getAsString(*Args);
}
return Args;
}
// Determine which compilation mode we are in. We look for options which
// affect the phase, starting with the earliest phases, and record which
// option we used to determine the final phase.
phases::ID Driver::getFinalPhase(const DerivedArgList &DAL, Arg **FinalPhaseArg)
const {
Arg *PhaseArg = 0;
phases::ID FinalPhase;
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// -{E,M,MM} and /P only run the preprocessor.
if (CCCIsCPP() ||
(PhaseArg = DAL.getLastArg(options::OPT_E)) ||
(PhaseArg = DAL.getLastArg(options::OPT_M, options::OPT_MM)) ||
(PhaseArg = DAL.getLastArg(options::OPT__SLASH_P))) {
FinalPhase = phases::Preprocess;
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// -{fsyntax-only,-analyze,emit-ast,S} only run up to the compiler.
} else if ((PhaseArg = DAL.getLastArg(options::OPT_fsyntax_only)) ||
(PhaseArg = DAL.getLastArg(options::OPT_module_file_info)) ||
(PhaseArg = DAL.getLastArg(options::OPT_verify_pch)) ||
(PhaseArg = DAL.getLastArg(options::OPT_rewrite_objc)) ||
(PhaseArg = DAL.getLastArg(options::OPT_rewrite_legacy_objc)) ||
(PhaseArg = DAL.getLastArg(options::OPT__migrate)) ||
(PhaseArg = DAL.getLastArg(options::OPT__analyze,
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options::OPT__analyze_auto)) ||
(PhaseArg = DAL.getLastArg(options::OPT_emit_ast)) ||
(PhaseArg = DAL.getLastArg(options::OPT_S))) {
FinalPhase = phases::Compile;
// -c only runs up to the assembler.
} else if ((PhaseArg = DAL.getLastArg(options::OPT_c))) {
FinalPhase = phases::Assemble;
// Otherwise do everything.
} else
FinalPhase = phases::Link;
if (FinalPhaseArg)
*FinalPhaseArg = PhaseArg;
return FinalPhase;
}
static Arg* MakeInputArg(const DerivedArgList &Args, OptTable *Opts,
StringRef Value) {
Arg *A = new Arg(Opts->getOption(options::OPT_INPUT), Value,
Args.getBaseArgs().MakeIndex(Value), Value.data());
A->claim();
return A;
}
DerivedArgList *Driver::TranslateInputArgs(const InputArgList &Args) const {
DerivedArgList *DAL = new DerivedArgList(Args);
bool HasNostdlib = Args.hasArg(options::OPT_nostdlib);
for (ArgList::const_iterator it = Args.begin(),
ie = Args.end(); it != ie; ++it) {
const Arg *A = *it;
// Unfortunately, we have to parse some forwarding options (-Xassembler,
// -Xlinker, -Xpreprocessor) because we either integrate their functionality
// (assembler and preprocessor), or bypass a previous driver ('collect2').
// Rewrite linker options, to replace --no-demangle with a custom internal
// option.
if ((A->getOption().matches(options::OPT_Wl_COMMA) ||
A->getOption().matches(options::OPT_Xlinker)) &&
A->containsValue("--no-demangle")) {
// Add the rewritten no-demangle argument.
DAL->AddFlagArg(A, Opts->getOption(options::OPT_Z_Xlinker__no_demangle));
// Add the remaining values as Xlinker arguments.
for (unsigned i = 0, e = A->getNumValues(); i != e; ++i)
if (StringRef(A->getValue(i)) != "--no-demangle")
DAL->AddSeparateArg(A, Opts->getOption(options::OPT_Xlinker),
A->getValue(i));
continue;
}
// Rewrite preprocessor options, to replace -Wp,-MD,FOO which is used by
// some build systems. We don't try to be complete here because we don't
// care to encourage this usage model.
if (A->getOption().matches(options::OPT_Wp_COMMA) &&
(A->getValue(0) == StringRef("-MD") ||
A->getValue(0) == StringRef("-MMD"))) {
// Rewrite to -MD/-MMD along with -MF.
if (A->getValue(0) == StringRef("-MD"))
DAL->AddFlagArg(A, Opts->getOption(options::OPT_MD));
else
DAL->AddFlagArg(A, Opts->getOption(options::OPT_MMD));
if (A->getNumValues() == 2)
DAL->AddSeparateArg(A, Opts->getOption(options::OPT_MF),
A->getValue(1));
continue;
}
// Rewrite reserved library names.
if (A->getOption().matches(options::OPT_l)) {
StringRef Value = A->getValue();
// Rewrite unless -nostdlib is present.
if (!HasNostdlib && Value == "stdc++") {
DAL->AddFlagArg(A, Opts->getOption(
options::OPT_Z_reserved_lib_stdcxx));
continue;
}
// Rewrite unconditionally.
if (Value == "cc_kext") {
DAL->AddFlagArg(A, Opts->getOption(
options::OPT_Z_reserved_lib_cckext));
continue;
}
}
// Pick up inputs via the -- option.
if (A->getOption().matches(options::OPT__DASH_DASH)) {
A->claim();
for (unsigned i = 0, e = A->getNumValues(); i != e; ++i)
DAL->append(MakeInputArg(*DAL, Opts, A->getValue(i)));
continue;
}
DAL->append(*it);
}
// Add a default value of -mlinker-version=, if one was given and the user
// didn't specify one.
#if defined(HOST_LINK_VERSION)
if (!Args.hasArg(options::OPT_mlinker_version_EQ)) {
DAL->AddJoinedArg(0, Opts->getOption(options::OPT_mlinker_version_EQ),
HOST_LINK_VERSION);
DAL->getLastArg(options::OPT_mlinker_version_EQ)->claim();
}
#endif
return DAL;
}
Compilation *Driver::BuildCompilation(ArrayRef<const char *> ArgList) {
llvm::PrettyStackTraceString CrashInfo("Compilation construction");
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// FIXME: Handle environment options which affect driver behavior, somewhere
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// (client?). GCC_EXEC_PREFIX, LPATH, CC_PRINT_OPTIONS.
if (char *env = ::getenv("COMPILER_PATH")) {
StringRef CompilerPath = env;
while (!CompilerPath.empty()) {
std::pair<StringRef, StringRef> Split
= CompilerPath.split(llvm::sys::EnvPathSeparator);
PrefixDirs.push_back(Split.first);
CompilerPath = Split.second;
}
}
// We look for the driver mode option early, because the mode can affect
// how other options are parsed.
ParseDriverMode(ArgList.slice(1));
// FIXME: What are we going to do with -V and -b?
// FIXME: This stuff needs to go into the Compilation, not the driver.
bool CCCPrintActions;
InputArgList *Args = ParseArgStrings(ArgList.slice(1));
// -no-canonical-prefixes is used very early in main.
Args->ClaimAllArgs(options::OPT_no_canonical_prefixes);
// Ignore -pipe.
Args->ClaimAllArgs(options::OPT_pipe);
// Extract -ccc args.
//
// FIXME: We need to figure out where this behavior should live. Most of it
// should be outside in the client; the parts that aren't should have proper
// options, either by introducing new ones or by overloading gcc ones like -V
// or -b.
CCCPrintActions = Args->hasArg(options::OPT_ccc_print_phases);
CCCPrintBindings = Args->hasArg(options::OPT_ccc_print_bindings);
if (const Arg *A = Args->getLastArg(options::OPT_ccc_gcc_name))
CCCGenericGCCName = A->getValue();
CCCUsePCH = Args->hasFlag(options::OPT_ccc_pch_is_pch,
options::OPT_ccc_pch_is_pth);
// FIXME: DefaultTargetTriple is used by the target-prefixed calls to as/ld
// and getToolChain is const.
if (IsCLMode()) {
// clang-cl targets Win32.
llvm::Triple T(DefaultTargetTriple);
T.setOSName(llvm::Triple::getOSTypeName(llvm::Triple::Win32));
DefaultTargetTriple = T.str();
}
if (const Arg *A = Args->getLastArg(options::OPT_target))
DefaultTargetTriple = A->getValue();
if (const Arg *A = Args->getLastArg(options::OPT_ccc_install_dir))
Dir = InstalledDir = A->getValue();
for (arg_iterator it = Args->filtered_begin(options::OPT_B),
ie = Args->filtered_end(); it != ie; ++it) {
const Arg *A = *it;
A->claim();
PrefixDirs.push_back(A->getValue(0));
}
if (const Arg *A = Args->getLastArg(options::OPT__sysroot_EQ))
SysRoot = A->getValue();
if (const Arg *A = Args->getLastArg(options::OPT__dyld_prefix_EQ))
DyldPrefix = A->getValue();
if (Args->hasArg(options::OPT_nostdlib))
UseStdLib = false;
if (const Arg *A = Args->getLastArg(options::OPT_resource_dir))
ResourceDir = A->getValue();
// Perform the default argument translations.
DerivedArgList *TranslatedArgs = TranslateInputArgs(*Args);
// Owned by the host.
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
const ToolChain &TC = getToolChain(*Args);
// The compilation takes ownership of Args.
Compilation *C = new Compilation(*this, TC, Args, TranslatedArgs);
if (!HandleImmediateArgs(*C))
return C;
// Construct the list of inputs.
InputList Inputs;
BuildInputs(C->getDefaultToolChain(), *TranslatedArgs, Inputs);
// Construct the list of abstract actions to perform for this compilation. On
// MachO targets this uses the driver-driver and universal actions.
if (TC.getTriple().isOSBinFormatMachO())
BuildUniversalActions(C->getDefaultToolChain(), C->getArgs(),
Inputs, C->getActions());
else
BuildActions(C->getDefaultToolChain(), C->getArgs(), Inputs,
C->getActions());
if (CCCPrintActions) {
PrintActions(*C);
return C;
}
BuildJobs(*C);
return C;
}
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// When clang crashes, produce diagnostic information including the fully
// preprocessed source file(s). Request that the developer attach the
// diagnostic information to a bug report.
void Driver::generateCompilationDiagnostics(Compilation &C,
const Command *FailingCommand) {
if (C.getArgs().hasArg(options::OPT_fno_crash_diagnostics))
return;
// Don't try to generate diagnostics for link or dsymutil jobs.
if (FailingCommand && (FailingCommand->getCreator().isLinkJob() ||
FailingCommand->getCreator().isDsymutilJob()))
return;
// Print the version of the compiler.
PrintVersion(C, llvm::errs());
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "PLEASE submit a bug report to " BUG_REPORT_URL " and include the "
"crash backtrace, preprocessed source, and associated run script.";
// Suppress driver output and emit preprocessor output to temp file.
Mode = CPPMode;
CCGenDiagnostics = true;
C.getArgs().AddFlagArg(0, Opts->getOption(options::OPT_frewrite_includes));
// Save the original job command(s).
std::string Cmd;
llvm::raw_string_ostream OS(Cmd);
if (FailingCommand)
FailingCommand->Print(OS, "\n", /*Quote*/ false, /*CrashReport*/ true);
else
// Crash triggered by FORCE_CLANG_DIAGNOSTICS_CRASH, which doesn't have an
// associated FailingCommand, so just pass all jobs.
C.getJobs().Print(OS, "\n", /*Quote*/ false, /*CrashReport*/ true);
OS.flush();
// Keep track of whether we produce any errors while trying to produce
// preprocessed sources.
DiagnosticErrorTrap Trap(Diags);
// Suppress tool output.
C.initCompilationForDiagnostics();
// Construct the list of inputs.
InputList Inputs;
BuildInputs(C.getDefaultToolChain(), C.getArgs(), Inputs);
for (InputList::iterator it = Inputs.begin(), ie = Inputs.end(); it != ie;) {
bool IgnoreInput = false;
// Ignore input from stdin or any inputs that cannot be preprocessed.
if (!strcmp(it->second->getValue(), "-")) {
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "Error generating preprocessed source(s) - ignoring input from stdin"
".";
IgnoreInput = true;
} else if (types::getPreprocessedType(it->first) == types::TY_INVALID) {
IgnoreInput = true;
}
if (IgnoreInput) {
it = Inputs.erase(it);
ie = Inputs.end();
} else {
++it;
}
}
if (Inputs.empty()) {
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "Error generating preprocessed source(s) - no preprocessable inputs.";
return;
}
// Don't attempt to generate preprocessed files if multiple -arch options are
// used, unless they're all duplicates.
llvm::StringSet<> ArchNames;
for (ArgList::const_iterator it = C.getArgs().begin(), ie = C.getArgs().end();
it != ie; ++it) {
Arg *A = *it;
if (A->getOption().matches(options::OPT_arch)) {
StringRef ArchName = A->getValue();
ArchNames.insert(ArchName);
}
}
if (ArchNames.size() > 1) {
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "Error generating preprocessed source(s) - cannot generate "
"preprocessed source with multiple -arch options.";
return;
}
// Construct the list of abstract actions to perform for this compilation. On
// Darwin OSes this uses the driver-driver and builds universal actions.
const ToolChain &TC = C.getDefaultToolChain();
if (TC.getTriple().isOSBinFormatMachO())
BuildUniversalActions(TC, C.getArgs(), Inputs, C.getActions());
else
BuildActions(TC, C.getArgs(), Inputs, C.getActions());
BuildJobs(C);
// If there were errors building the compilation, quit now.
if (Trap.hasErrorOccurred()) {
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "Error generating preprocessed source(s).";
return;
}
// Generate preprocessed output.
SmallVector<std::pair<int, const Command *>, 4> FailingCommands;
C.ExecuteJob(C.getJobs(), FailingCommands);
// If the command succeeded, we are done.
if (FailingCommands.empty()) {
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "\n********************\n\n"
"PLEASE ATTACH THE FOLLOWING FILES TO THE BUG REPORT:\n"
"Preprocessed source(s) and associated run script(s) are located at:";
ArgStringList Files = C.getTempFiles();
2011-08-18 06:59:59 +08:00
for (ArgStringList::const_iterator it = Files.begin(), ie = Files.end();
it != ie; ++it) {
Diag(clang::diag::note_drv_command_failed_diag_msg) << *it;
std::string Err;
std::string Script = StringRef(*it).rsplit('.').first;
Script += ".sh";
llvm::raw_fd_ostream ScriptOS(Script.c_str(), Err, llvm::sys::fs::F_Excl);
if (!Err.empty()) {
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "Error generating run script: " + Script + " " + Err;
} else {
// Append the new filename with correct preprocessed suffix.
size_t I, E;
I = Cmd.find("-main-file-name ");
assert (I != std::string::npos && "Expected to find -main-file-name");
I += 16;
E = Cmd.find(" ", I);
assert (E != std::string::npos && "-main-file-name missing argument?");
StringRef OldFilename = StringRef(Cmd).slice(I, E);
StringRef NewFilename = llvm::sys::path::filename(*it);
I = StringRef(Cmd).rfind(OldFilename);
E = I + OldFilename.size();
I = Cmd.rfind(" ", I) + 1;
Cmd.replace(I, E - I, NewFilename.data(), NewFilename.size());
ScriptOS << Cmd;
Diag(clang::diag::note_drv_command_failed_diag_msg) << Script;
}
}
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "\n\n********************";
} else {
// Failure, remove preprocessed files.
if (!C.getArgs().hasArg(options::OPT_save_temps))
C.CleanupFileList(C.getTempFiles(), true);
Diag(clang::diag::note_drv_command_failed_diag_msg)
<< "Error generating preprocessed source(s).";
}
}
int Driver::ExecuteCompilation(const Compilation &C,
SmallVectorImpl< std::pair<int, const Command *> > &FailingCommands) const {
// Just print if -### was present.
if (C.getArgs().hasArg(options::OPT__HASH_HASH_HASH)) {
C.getJobs().Print(llvm::errs(), "\n", true);
return 0;
}
// If there were errors building the compilation, quit now.
if (Diags.hasErrorOccurred())
return 1;
C.ExecuteJob(C.getJobs(), FailingCommands);
// Remove temp files.
C.CleanupFileList(C.getTempFiles());
// If the command succeeded, we are done.
if (FailingCommands.empty())
return 0;
// Otherwise, remove result files and print extra information about abnormal
// failures.
for (SmallVectorImpl< std::pair<int, const Command *> >::iterator it =
FailingCommands.begin(), ie = FailingCommands.end(); it != ie; ++it) {
int Res = it->first;
const Command *FailingCommand = it->second;
// Remove result files if we're not saving temps.
if (!C.getArgs().hasArg(options::OPT_save_temps)) {
const JobAction *JA = cast<JobAction>(&FailingCommand->getSource());
C.CleanupFileMap(C.getResultFiles(), JA, true);
// Failure result files are valid unless we crashed.
if (Res < 0)
C.CleanupFileMap(C.getFailureResultFiles(), JA, true);
}
// Print extra information about abnormal failures, if possible.
//
// This is ad-hoc, but we don't want to be excessively noisy. If the result
// status was 1, assume the command failed normally. In particular, if it
// was the compiler then assume it gave a reasonable error code. Failures
// in other tools are less common, and they generally have worse
// diagnostics, so always print the diagnostic there.
const Tool &FailingTool = FailingCommand->getCreator();
if (!FailingCommand->getCreator().hasGoodDiagnostics() || Res != 1) {
// FIXME: See FIXME above regarding result code interpretation.
if (Res < 0)
Diag(clang::diag::err_drv_command_signalled)
<< FailingTool.getShortName();
else
Diag(clang::diag::err_drv_command_failed)
<< FailingTool.getShortName() << Res;
}
}
return 0;
}
void Driver::PrintHelp(bool ShowHidden) const {
unsigned IncludedFlagsBitmask;
unsigned ExcludedFlagsBitmask;
std::tie(IncludedFlagsBitmask, ExcludedFlagsBitmask) =
getIncludeExcludeOptionFlagMasks();
ExcludedFlagsBitmask |= options::NoDriverOption;
if (!ShowHidden)
ExcludedFlagsBitmask |= HelpHidden;
getOpts().PrintHelp(llvm::outs(), Name.c_str(), DriverTitle.c_str(),
IncludedFlagsBitmask, ExcludedFlagsBitmask);
}
void Driver::PrintVersion(const Compilation &C, raw_ostream &OS) const {
// FIXME: The following handlers should use a callback mechanism, we don't
// know what the client would like to do.
OS << getClangFullVersion() << '\n';
const ToolChain &TC = C.getDefaultToolChain();
OS << "Target: " << TC.getTripleString() << '\n';
// Print the threading model.
//
// FIXME: Implement correctly.
OS << "Thread model: " << "posix" << '\n';
}
/// PrintDiagnosticCategories - Implement the --print-diagnostic-categories
/// option.
static void PrintDiagnosticCategories(raw_ostream &OS) {
// Skip the empty category.
for (unsigned i = 1, max = DiagnosticIDs::getNumberOfCategories();
i != max; ++i)
OS << i << ',' << DiagnosticIDs::getCategoryNameFromID(i) << '\n';
}
bool Driver::HandleImmediateArgs(const Compilation &C) {
// The order these options are handled in gcc is all over the place, but we
// don't expect inconsistencies w.r.t. that to matter in practice.
if (C.getArgs().hasArg(options::OPT_dumpmachine)) {
llvm::outs() << C.getDefaultToolChain().getTripleString() << '\n';
return false;
}
if (C.getArgs().hasArg(options::OPT_dumpversion)) {
// Since -dumpversion is only implemented for pedantic GCC compatibility, we
// return an answer which matches our definition of __VERSION__.
//
// If we want to return a more correct answer some day, then we should
// introduce a non-pedantically GCC compatible mode to Clang in which we
// provide sensible definitions for -dumpversion, __VERSION__, etc.
llvm::outs() << "4.2.1\n";
return false;
}
if (C.getArgs().hasArg(options::OPT__print_diagnostic_categories)) {
PrintDiagnosticCategories(llvm::outs());
return false;
}
if (C.getArgs().hasArg(options::OPT_help) ||
C.getArgs().hasArg(options::OPT__help_hidden)) {
PrintHelp(C.getArgs().hasArg(options::OPT__help_hidden));
return false;
}
if (C.getArgs().hasArg(options::OPT__version)) {
// Follow gcc behavior and use stdout for --version and stderr for -v.
PrintVersion(C, llvm::outs());
return false;
}
if (C.getArgs().hasArg(options::OPT_v) ||
C.getArgs().hasArg(options::OPT__HASH_HASH_HASH)) {
PrintVersion(C, llvm::errs());
SuppressMissingInputWarning = true;
}
const ToolChain &TC = C.getDefaultToolChain();
if (C.getArgs().hasArg(options::OPT_v))
TC.printVerboseInfo(llvm::errs());
if (C.getArgs().hasArg(options::OPT_print_search_dirs)) {
llvm::outs() << "programs: =";
for (ToolChain::path_list::const_iterator it = TC.getProgramPaths().begin(),
ie = TC.getProgramPaths().end(); it != ie; ++it) {
if (it != TC.getProgramPaths().begin())
llvm::outs() << ':';
llvm::outs() << *it;
}
llvm::outs() << "\n";
llvm::outs() << "libraries: =" << ResourceDir;
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StringRef sysroot = C.getSysRoot();
for (ToolChain::path_list::const_iterator it = TC.getFilePaths().begin(),
ie = TC.getFilePaths().end(); it != ie; ++it) {
llvm::outs() << ':';
const char *path = it->c_str();
if (path[0] == '=')
llvm::outs() << sysroot << path + 1;
else
llvm::outs() << path;
}
llvm::outs() << "\n";
return false;
}
// FIXME: The following handlers should use a callback mechanism, we don't
// know what the client would like to do.
if (Arg *A = C.getArgs().getLastArg(options::OPT_print_file_name_EQ)) {
llvm::outs() << GetFilePath(A->getValue(), TC) << "\n";
return false;
}
if (Arg *A = C.getArgs().getLastArg(options::OPT_print_prog_name_EQ)) {
llvm::outs() << GetProgramPath(A->getValue(), TC) << "\n";
return false;
}
if (C.getArgs().hasArg(options::OPT_print_libgcc_file_name)) {
llvm::outs() << GetFilePath("libgcc.a", TC) << "\n";
return false;
}
if (C.getArgs().hasArg(options::OPT_print_multi_lib)) {
const MultilibSet &Multilibs = TC.getMultilibs();
for (MultilibSet::const_iterator I = Multilibs.begin(), E = Multilibs.end();
I != E; ++I) {
llvm::outs() << *I << "\n";
}
return false;
}
if (C.getArgs().hasArg(options::OPT_print_multi_directory)) {
const MultilibSet &Multilibs = TC.getMultilibs();
for (MultilibSet::const_iterator I = Multilibs.begin(), E = Multilibs.end();
I != E; ++I) {
if (I->gccSuffix().empty())
llvm::outs() << ".\n";
else {
StringRef Suffix(I->gccSuffix());
assert(Suffix.front() == '/');
llvm::outs() << Suffix.substr(1) << "\n";
}
}
return false;
}
if (C.getArgs().hasArg(options::OPT_print_multi_os_directory)) {
// FIXME: This should print out "lib/../lib", "lib/../lib64", or
// "lib/../lib32" as appropriate for the toolchain. For now, print
// nothing because it's not supported yet.
return false;
}
return true;
}
static unsigned PrintActions1(const Compilation &C, Action *A,
std::map<Action*, unsigned> &Ids) {
if (Ids.count(A))
return Ids[A];
std::string str;
llvm::raw_string_ostream os(str);
os << Action::getClassName(A->getKind()) << ", ";
if (InputAction *IA = dyn_cast<InputAction>(A)) {
os << "\"" << IA->getInputArg().getValue() << "\"";
} else if (BindArchAction *BIA = dyn_cast<BindArchAction>(A)) {
os << '"' << BIA->getArchName() << '"'
<< ", {" << PrintActions1(C, *BIA->begin(), Ids) << "}";
} else {
os << "{";
for (Action::iterator it = A->begin(), ie = A->end(); it != ie;) {
os << PrintActions1(C, *it, Ids);
++it;
if (it != ie)
os << ", ";
}
os << "}";
}
unsigned Id = Ids.size();
Ids[A] = Id;
llvm::errs() << Id << ": " << os.str() << ", "
<< types::getTypeName(A->getType()) << "\n";
return Id;
}
void Driver::PrintActions(const Compilation &C) const {
std::map<Action*, unsigned> Ids;
for (ActionList::const_iterator it = C.getActions().begin(),
ie = C.getActions().end(); it != ie; ++it)
PrintActions1(C, *it, Ids);
}
/// \brief Check whether the given input tree contains any compilation or
/// assembly actions.
static bool ContainsCompileOrAssembleAction(const Action *A) {
if (isa<CompileJobAction>(A) || isa<AssembleJobAction>(A))
return true;
for (Action::const_iterator it = A->begin(), ie = A->end(); it != ie; ++it)
if (ContainsCompileOrAssembleAction(*it))
return true;
return false;
}
void Driver::BuildUniversalActions(const ToolChain &TC,
DerivedArgList &Args,
const InputList &BAInputs,
ActionList &Actions) const {
llvm::PrettyStackTraceString CrashInfo("Building universal build actions");
// Collect the list of architectures. Duplicates are allowed, but should only
// be handled once (in the order seen).
llvm::StringSet<> ArchNames;
SmallVector<const char *, 4> Archs;
for (ArgList::const_iterator it = Args.begin(), ie = Args.end();
it != ie; ++it) {
Arg *A = *it;
if (A->getOption().matches(options::OPT_arch)) {
// Validate the option here; we don't save the type here because its
// particular spelling may participate in other driver choices.
llvm::Triple::ArchType Arch =
tools::darwin::getArchTypeForMachOArchName(A->getValue());
if (Arch == llvm::Triple::UnknownArch) {
Diag(clang::diag::err_drv_invalid_arch_name)
<< A->getAsString(Args);
continue;
}
A->claim();
if (ArchNames.insert(A->getValue()))
Archs.push_back(A->getValue());
}
}
// When there is no explicit arch for this platform, make sure we still bind
// the architecture (to the default) so that -Xarch_ is handled correctly.
if (!Archs.size())
Archs.push_back(Args.MakeArgString(TC.getDefaultUniversalArchName()));
ActionList SingleActions;
BuildActions(TC, Args, BAInputs, SingleActions);
// Add in arch bindings for every top level action, as well as lipo and
// dsymutil steps if needed.
for (unsigned i = 0, e = SingleActions.size(); i != e; ++i) {
Action *Act = SingleActions[i];
// Make sure we can lipo this kind of output. If not (and it is an actual
// output) then we disallow, since we can't create an output file with the
// right name without overwriting it. We could remove this oddity by just
// changing the output names to include the arch, which would also fix
// -save-temps. Compatibility wins for now.
if (Archs.size() > 1 && !types::canLipoType(Act->getType()))
Diag(clang::diag::err_drv_invalid_output_with_multiple_archs)
<< types::getTypeName(Act->getType());
ActionList Inputs;
for (unsigned i = 0, e = Archs.size(); i != e; ++i) {
Inputs.push_back(new BindArchAction(Act, Archs[i]));
if (i != 0)
Inputs.back()->setOwnsInputs(false);
}
// Lipo if necessary, we do it this way because we need to set the arch flag
// so that -Xarch_ gets overwritten.
if (Inputs.size() == 1 || Act->getType() == types::TY_Nothing)
Actions.append(Inputs.begin(), Inputs.end());
else
Actions.push_back(new LipoJobAction(Inputs, Act->getType()));
// Handle debug info queries.
Arg *A = Args.getLastArg(options::OPT_g_Group);
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if (A && !A->getOption().matches(options::OPT_g0) &&
!A->getOption().matches(options::OPT_gstabs) &&
ContainsCompileOrAssembleAction(Actions.back())) {
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// Add a 'dsymutil' step if necessary, when debug info is enabled and we
// have a compile input. We need to run 'dsymutil' ourselves in such cases
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// because the debug info will refer to a temporary object file which
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// will be removed at the end of the compilation process.
if (Act->getType() == types::TY_Image) {
ActionList Inputs;
Inputs.push_back(Actions.back());
Actions.pop_back();
Actions.push_back(new DsymutilJobAction(Inputs, types::TY_dSYM));
}
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// Verify the debug info output.
if (Args.hasArg(options::OPT_verify_debug_info)) {
Action *VerifyInput = Actions.back();
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Actions.pop_back();
Actions.push_back(new VerifyDebugInfoJobAction(VerifyInput,
types::TY_Nothing));
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}
}
}
}
/// \brief Check that the file referenced by Value exists. If it doesn't,
/// issue a diagnostic and return false.
static bool DiagnoseInputExistence(const Driver &D, const DerivedArgList &Args,
StringRef Value) {
if (!D.getCheckInputsExist())
return true;
// stdin always exists.
if (Value == "-")
return true;
SmallString<64> Path(Value);
if (Arg *WorkDir = Args.getLastArg(options::OPT_working_directory)) {
if (!llvm::sys::path::is_absolute(Path.str())) {
SmallString<64> Directory(WorkDir->getValue());
llvm::sys::path::append(Directory, Value);
Path.assign(Directory);
}
}
if (llvm::sys::fs::exists(Twine(Path)))
return true;
D.Diag(clang::diag::err_drv_no_such_file) << Path.str();
return false;
}
// Construct a the list of inputs and their types.
void Driver::BuildInputs(const ToolChain &TC, const DerivedArgList &Args,
InputList &Inputs) const {
// Track the current user specified (-x) input. We also explicitly track the
// argument used to set the type; we only want to claim the type when we
// actually use it, so we warn about unused -x arguments.
types::ID InputType = types::TY_Nothing;
Arg *InputTypeArg = 0;
// The last /TC or /TP option sets the input type to C or C++ globally.
if (Arg *TCTP = Args.getLastArg(options::OPT__SLASH_TC,
options::OPT__SLASH_TP)) {
InputTypeArg = TCTP;
InputType = TCTP->getOption().matches(options::OPT__SLASH_TC)
? types::TY_C : types::TY_CXX;
arg_iterator it = Args.filtered_begin(options::OPT__SLASH_TC,
options::OPT__SLASH_TP);
const arg_iterator ie = Args.filtered_end();
Arg *Previous = *it++;
bool ShowNote = false;
while (it != ie) {
Diag(clang::diag::warn_drv_overriding_flag_option)
<< Previous->getSpelling() << (*it)->getSpelling();
Previous = *it++;
ShowNote = true;
}
if (ShowNote)
Diag(clang::diag::note_drv_t_option_is_global);
// No driver mode exposes -x and /TC or /TP; we don't support mixing them.
assert(!Args.hasArg(options::OPT_x) && "-x and /TC or /TP is not allowed");
}
for (ArgList::const_iterator it = Args.begin(), ie = Args.end();
it != ie; ++it) {
Arg *A = *it;
if (A->getOption().getKind() == Option::InputClass) {
const char *Value = A->getValue();
types::ID Ty = types::TY_INVALID;
// Infer the input type if necessary.
if (InputType == types::TY_Nothing) {
// If there was an explicit arg for this, claim it.
if (InputTypeArg)
InputTypeArg->claim();
// stdin must be handled specially.
if (memcmp(Value, "-", 2) == 0) {
// If running with -E, treat as a C input (this changes the builtin
// macros, for example). This may be overridden by -ObjC below.
//
// Otherwise emit an error but still use a valid type to avoid
// spurious errors (e.g., no inputs).
if (!Args.hasArgNoClaim(options::OPT_E) && !CCCIsCPP())
Diag(IsCLMode() ? clang::diag::err_drv_unknown_stdin_type_clang_cl
: clang::diag::err_drv_unknown_stdin_type);
Ty = types::TY_C;
} else {
// Otherwise lookup by extension.
// Fallback is C if invoked as C preprocessor or Object otherwise.
// We use a host hook here because Darwin at least has its own
// idea of what .s is.
if (const char *Ext = strrchr(Value, '.'))
Ty = TC.LookupTypeForExtension(Ext + 1);
if (Ty == types::TY_INVALID) {
if (CCCIsCPP())
Ty = types::TY_C;
else
Ty = types::TY_Object;
}
// If the driver is invoked as C++ compiler (like clang++ or c++) it
// should autodetect some input files as C++ for g++ compatibility.
if (CCCIsCXX()) {
types::ID OldTy = Ty;
Ty = types::lookupCXXTypeForCType(Ty);
if (Ty != OldTy)
Diag(clang::diag::warn_drv_treating_input_as_cxx)
<< getTypeName(OldTy) << getTypeName(Ty);
}
}
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// -ObjC and -ObjC++ override the default language, but only for "source
// files". We just treat everything that isn't a linker input as a
// source file.
//
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// FIXME: Clean this up if we move the phase sequence into the type.
if (Ty != types::TY_Object) {
if (Args.hasArg(options::OPT_ObjC))
Ty = types::TY_ObjC;
else if (Args.hasArg(options::OPT_ObjCXX))
Ty = types::TY_ObjCXX;
}
} else {
assert(InputTypeArg && "InputType set w/o InputTypeArg");
InputTypeArg->claim();
Ty = InputType;
}
if (DiagnoseInputExistence(*this, Args, Value))
Inputs.push_back(std::make_pair(Ty, A));
} else if (A->getOption().matches(options::OPT__SLASH_Tc)) {
StringRef Value = A->getValue();
if (DiagnoseInputExistence(*this, Args, Value)) {
Arg *InputArg = MakeInputArg(Args, Opts, A->getValue());
Inputs.push_back(std::make_pair(types::TY_C, InputArg));
}
A->claim();
} else if (A->getOption().matches(options::OPT__SLASH_Tp)) {
StringRef Value = A->getValue();
if (DiagnoseInputExistence(*this, Args, Value)) {
Arg *InputArg = MakeInputArg(Args, Opts, A->getValue());
Inputs.push_back(std::make_pair(types::TY_CXX, InputArg));
}
A->claim();
} else if (A->getOption().hasFlag(options::LinkerInput)) {
// Just treat as object type, we could make a special type for this if
// necessary.
Inputs.push_back(std::make_pair(types::TY_Object, A));
} else if (A->getOption().matches(options::OPT_x)) {
InputTypeArg = A;
InputType = types::lookupTypeForTypeSpecifier(A->getValue());
A->claim();
// Follow gcc behavior and treat as linker input for invalid -x
// options. Its not clear why we shouldn't just revert to unknown; but
2010-12-18 05:22:33 +08:00
// this isn't very important, we might as well be bug compatible.
if (!InputType) {
Diag(clang::diag::err_drv_unknown_language) << A->getValue();
InputType = types::TY_Object;
}
}
}
if (CCCIsCPP() && Inputs.empty()) {
// If called as standalone preprocessor, stdin is processed
// if no other input is present.
Arg *A = MakeInputArg(Args, Opts, "-");
Inputs.push_back(std::make_pair(types::TY_C, A));
}
}
void Driver::BuildActions(const ToolChain &TC, DerivedArgList &Args,
const InputList &Inputs, ActionList &Actions) const {
llvm::PrettyStackTraceString CrashInfo("Building compilation actions");
if (!SuppressMissingInputWarning && Inputs.empty()) {
Diag(clang::diag::err_drv_no_input_files);
return;
}
Arg *FinalPhaseArg;
phases::ID FinalPhase = getFinalPhase(Args, &FinalPhaseArg);
if (FinalPhase == phases::Link && Args.hasArg(options::OPT_emit_llvm)) {
Diag(clang::diag::err_drv_emit_llvm_link);
}
// Reject -Z* at the top level, these options should never have been exposed
// by gcc.
if (Arg *A = Args.getLastArg(options::OPT_Z_Joined))
Diag(clang::diag::err_drv_use_of_Z_option) << A->getAsString(Args);
// Diagnose misuse of /Fo.
if (Arg *A = Args.getLastArg(options::OPT__SLASH_Fo)) {
StringRef V = A->getValue();
if (V.empty()) {
// It has to have a value.
Diag(clang::diag::err_drv_missing_argument) << A->getSpelling() << 1;
Args.eraseArg(options::OPT__SLASH_Fo);
} else if (Inputs.size() > 1 && !llvm::sys::path::is_separator(V.back())) {
// Check whether /Fo tries to name an output file for multiple inputs.
Diag(clang::diag::err_drv_out_file_argument_with_multiple_sources)
<< A->getSpelling() << V;
Args.eraseArg(options::OPT__SLASH_Fo);
}
}
// Diagnose misuse of /Fa.
if (Arg *A = Args.getLastArg(options::OPT__SLASH_Fa)) {
StringRef V = A->getValue();
if (Inputs.size() > 1 && !llvm::sys::path::is_separator(V.back())) {
// Check whether /Fa tries to name an asm file for multiple inputs.
Diag(clang::diag::err_drv_out_file_argument_with_multiple_sources)
<< A->getSpelling() << V;
Args.eraseArg(options::OPT__SLASH_Fa);
}
}
// Diagnose misuse of /Fe.
if (Arg *A = Args.getLastArg(options::OPT__SLASH_Fe)) {
if (A->getValue()[0] == '\0') {
// It has to have a value.
Diag(clang::diag::err_drv_missing_argument) << A->getSpelling() << 1;
Args.eraseArg(options::OPT__SLASH_Fe);
}
}
// Construct the actions to perform.
ActionList LinkerInputs;
llvm::SmallVector<phases::ID, phases::MaxNumberOfPhases> PL;
for (unsigned i = 0, e = Inputs.size(); i != e; ++i) {
types::ID InputType = Inputs[i].first;
const Arg *InputArg = Inputs[i].second;
PL.clear();
types::getCompilationPhases(InputType, PL);
// If the first step comes after the final phase we are doing as part of
// this compilation, warn the user about it.
phases::ID InitialPhase = PL[0];
if (InitialPhase > FinalPhase) {
// Claim here to avoid the more general unused warning.
InputArg->claim();
// Suppress all unused style warnings with -Qunused-arguments
if (Args.hasArg(options::OPT_Qunused_arguments))
continue;
// Special case when final phase determined by binary name, rather than
// by a command-line argument with a corresponding Arg.
if (CCCIsCPP())
Diag(clang::diag::warn_drv_input_file_unused_by_cpp)
<< InputArg->getAsString(Args)
<< getPhaseName(InitialPhase);
// Special case '-E' warning on a previously preprocessed file to make
// more sense.
else if (InitialPhase == phases::Compile &&
FinalPhase == phases::Preprocess &&
getPreprocessedType(InputType) == types::TY_INVALID)
Diag(clang::diag::warn_drv_preprocessed_input_file_unused)
<< InputArg->getAsString(Args)
<< !!FinalPhaseArg
<< FinalPhaseArg ? FinalPhaseArg->getOption().getName() : "";
else
Diag(clang::diag::warn_drv_input_file_unused)
<< InputArg->getAsString(Args)
<< getPhaseName(InitialPhase)
<< !!FinalPhaseArg
<< FinalPhaseArg ? FinalPhaseArg->getOption().getName() : "";
continue;
}
// Build the pipeline for this file.
OwningPtr<Action> Current(new InputAction(*InputArg, InputType));
for (SmallVectorImpl<phases::ID>::iterator
i = PL.begin(), e = PL.end(); i != e; ++i) {
phases::ID Phase = *i;
// We are done if this step is past what the user requested.
if (Phase > FinalPhase)
break;
// Queue linker inputs.
if (Phase == phases::Link) {
assert((i + 1) == e && "linking must be final compilation step.");
LinkerInputs.push_back(Current.take());
break;
}
// Some types skip the assembler phase (e.g., llvm-bc), but we can't
// encode this in the steps because the intermediate type depends on
// arguments. Just special case here.
if (Phase == phases::Assemble && Current->getType() != types::TY_PP_Asm)
continue;
// Otherwise construct the appropriate action.
Current.reset(ConstructPhaseAction(Args, Phase, Current.take()));
if (Current->getType() == types::TY_Nothing)
break;
}
// If we ended with something, add to the output list.
if (Current)
Actions.push_back(Current.take());
}
// Add a link action if necessary.
if (!LinkerInputs.empty())
Actions.push_back(new LinkJobAction(LinkerInputs, types::TY_Image));
// If we are linking, claim any options which are obviously only used for
// compilation.
if (FinalPhase == phases::Link && PL.size() == 1) {
Args.ClaimAllArgs(options::OPT_CompileOnly_Group);
Args.ClaimAllArgs(options::OPT_cl_compile_Group);
}
// Claim ignored clang-cl options.
Args.ClaimAllArgs(options::OPT_cl_ignored_Group);
}
Action *Driver::ConstructPhaseAction(const ArgList &Args, phases::ID Phase,
Action *Input) const {
llvm::PrettyStackTraceString CrashInfo("Constructing phase actions");
// Build the appropriate action.
switch (Phase) {
case phases::Link: llvm_unreachable("link action invalid here.");
case phases::Preprocess: {
types::ID OutputTy;
// -{M, MM} alter the output type.
if (Args.hasArg(options::OPT_M, options::OPT_MM)) {
OutputTy = types::TY_Dependencies;
} else {
OutputTy = Input->getType();
if (!Args.hasFlag(options::OPT_frewrite_includes,
options::OPT_fno_rewrite_includes, false))
OutputTy = types::getPreprocessedType(OutputTy);
assert(OutputTy != types::TY_INVALID &&
"Cannot preprocess this input type!");
}
return new PreprocessJobAction(Input, OutputTy);
}
case phases::Precompile: {
types::ID OutputTy = types::TY_PCH;
if (Args.hasArg(options::OPT_fsyntax_only)) {
// Syntax checks should not emit a PCH file
OutputTy = types::TY_Nothing;
}
return new PrecompileJobAction(Input, OutputTy);
}
case phases::Compile: {
if (Args.hasArg(options::OPT_fsyntax_only)) {
return new CompileJobAction(Input, types::TY_Nothing);
} else if (Args.hasArg(options::OPT_rewrite_objc)) {
return new CompileJobAction(Input, types::TY_RewrittenObjC);
} else if (Args.hasArg(options::OPT_rewrite_legacy_objc)) {
return new CompileJobAction(Input, types::TY_RewrittenLegacyObjC);
} else if (Args.hasArg(options::OPT__analyze, options::OPT__analyze_auto)) {
return new AnalyzeJobAction(Input, types::TY_Plist);
} else if (Args.hasArg(options::OPT__migrate)) {
return new MigrateJobAction(Input, types::TY_Remap);
} else if (Args.hasArg(options::OPT_emit_ast)) {
return new CompileJobAction(Input, types::TY_AST);
} else if (Args.hasArg(options::OPT_module_file_info)) {
return new CompileJobAction(Input, types::TY_ModuleFile);
} else if (Args.hasArg(options::OPT_verify_pch)) {
return new VerifyPCHJobAction(Input, types::TY_Nothing);
} else if (IsUsingLTO(Args)) {
types::ID Output =
Args.hasArg(options::OPT_S) ? types::TY_LTO_IR : types::TY_LTO_BC;
return new CompileJobAction(Input, Output);
} else if (Args.hasArg(options::OPT_emit_llvm)) {
types::ID Output =
Args.hasArg(options::OPT_S) ? types::TY_LLVM_IR : types::TY_LLVM_BC;
return new CompileJobAction(Input, Output);
} else {
return new CompileJobAction(Input, types::TY_PP_Asm);
}
}
case phases::Assemble:
return new AssembleJobAction(Input, types::TY_Object);
}
llvm_unreachable("invalid phase in ConstructPhaseAction");
}
bool Driver::IsUsingLTO(const ArgList &Args) const {
if (Args.hasFlag(options::OPT_flto, options::OPT_fno_lto, false))
return true;
return false;
}
void Driver::BuildJobs(Compilation &C) const {
llvm::PrettyStackTraceString CrashInfo("Building compilation jobs");
Arg *FinalOutput = C.getArgs().getLastArg(options::OPT_o);
// It is an error to provide a -o option if we are making multiple output
// files.
if (FinalOutput) {
unsigned NumOutputs = 0;
for (ActionList::const_iterator it = C.getActions().begin(),
ie = C.getActions().end(); it != ie; ++it)
if ((*it)->getType() != types::TY_Nothing)
++NumOutputs;
if (NumOutputs > 1) {
Diag(clang::diag::err_drv_output_argument_with_multiple_files);
FinalOutput = 0;
}
}
// Collect the list of architectures.
llvm::StringSet<> ArchNames;
if (C.getDefaultToolChain().getTriple().isOSBinFormatMachO()) {
for (ArgList::const_iterator it = C.getArgs().begin(), ie = C.getArgs().end();
it != ie; ++it) {
Arg *A = *it;
if (A->getOption().matches(options::OPT_arch))
ArchNames.insert(A->getValue());
}
}
for (ActionList::const_iterator it = C.getActions().begin(),
ie = C.getActions().end(); it != ie; ++it) {
Action *A = *it;
// If we are linking an image for multiple archs then the linker wants
// -arch_multiple and -final_output <final image name>. Unfortunately, this
// doesn't fit in cleanly because we have to pass this information down.
//
// FIXME: This is a hack; find a cleaner way to integrate this into the
// process.
const char *LinkingOutput = 0;
if (isa<LipoJobAction>(A)) {
if (FinalOutput)
LinkingOutput = FinalOutput->getValue();
else
LinkingOutput = DefaultImageName.c_str();
}
InputInfo II;
BuildJobsForAction(C, A, &C.getDefaultToolChain(),
/*BoundArch*/0,
/*AtTopLevel*/ true,
/*MultipleArchs*/ ArchNames.size() > 1,
/*LinkingOutput*/ LinkingOutput,
II);
}
// If the user passed -Qunused-arguments or there were errors, don't warn
// about any unused arguments.
if (Diags.hasErrorOccurred() ||
C.getArgs().hasArg(options::OPT_Qunused_arguments))
return;
// Claim -### here.
(void) C.getArgs().hasArg(options::OPT__HASH_HASH_HASH);
// Claim --driver-mode, it was handled earlier.
(void) C.getArgs().hasArg(options::OPT_driver_mode);
for (ArgList::const_iterator it = C.getArgs().begin(), ie = C.getArgs().end();
it != ie; ++it) {
Arg *A = *it;
// FIXME: It would be nice to be able to send the argument to the
// DiagnosticsEngine, so that extra values, position, and so on could be
// printed.
if (!A->isClaimed()) {
if (A->getOption().hasFlag(options::NoArgumentUnused))
continue;
// Suppress the warning automatically if this is just a flag, and it is an
// instance of an argument we already claimed.
const Option &Opt = A->getOption();
if (Opt.getKind() == Option::FlagClass) {
bool DuplicateClaimed = false;
for (arg_iterator it = C.getArgs().filtered_begin(&Opt),
ie = C.getArgs().filtered_end(); it != ie; ++it) {
if ((*it)->isClaimed()) {
DuplicateClaimed = true;
break;
}
}
if (DuplicateClaimed)
continue;
}
Diag(clang::diag::warn_drv_unused_argument)
<< A->getAsString(C.getArgs());
}
}
}
static const Tool *SelectToolForJob(Compilation &C, const ToolChain *TC,
const JobAction *JA,
const ActionList *&Inputs) {
const Tool *ToolForJob = 0;
// See if we should look for a compiler with an integrated assembler. We match
// bottom up, so what we are actually looking for is an assembler job with a
// compiler input.
if (TC->useIntegratedAs() &&
!C.getArgs().hasArg(options::OPT_save_temps) &&
!C.getArgs().hasArg(options::OPT_via_file_asm) &&
!C.getArgs().hasArg(options::OPT__SLASH_FA) &&
!C.getArgs().hasArg(options::OPT__SLASH_Fa) &&
isa<AssembleJobAction>(JA) &&
Inputs->size() == 1 && isa<CompileJobAction>(*Inputs->begin())) {
const Tool *Compiler =
TC->SelectTool(cast<JobAction>(**Inputs->begin()));
if (!Compiler)
return NULL;
if (Compiler->hasIntegratedAssembler()) {
Inputs = &(*Inputs)[0]->getInputs();
ToolForJob = Compiler;
}
}
// Otherwise use the tool for the current job.
if (!ToolForJob)
ToolForJob = TC->SelectTool(*JA);
// See if we should use an integrated preprocessor. We do so when we have
// exactly one input, since this is the only use case we care about
// (irrelevant since we don't support combine yet).
if (Inputs->size() == 1 && isa<PreprocessJobAction>(*Inputs->begin()) &&
!C.getArgs().hasArg(options::OPT_no_integrated_cpp) &&
!C.getArgs().hasArg(options::OPT_traditional_cpp) &&
!C.getArgs().hasArg(options::OPT_save_temps) &&
!C.getArgs().hasArg(options::OPT_rewrite_objc) &&
ToolForJob->hasIntegratedCPP())
Inputs = &(*Inputs)[0]->getInputs();
return ToolForJob;
}
void Driver::BuildJobsForAction(Compilation &C,
const Action *A,
const ToolChain *TC,
const char *BoundArch,
bool AtTopLevel,
bool MultipleArchs,
const char *LinkingOutput,
InputInfo &Result) const {
llvm::PrettyStackTraceString CrashInfo("Building compilation jobs");
if (const InputAction *IA = dyn_cast<InputAction>(A)) {
// FIXME: It would be nice to not claim this here; maybe the old scheme of
// just using Args was better?
const Arg &Input = IA->getInputArg();
Input.claim();
if (Input.getOption().matches(options::OPT_INPUT)) {
const char *Name = Input.getValue();
Result = InputInfo(Name, A->getType(), Name);
} else
Result = InputInfo(&Input, A->getType(), "");
return;
}
if (const BindArchAction *BAA = dyn_cast<BindArchAction>(A)) {
const ToolChain *TC;
const char *ArchName = BAA->getArchName();
if (ArchName)
TC = &getToolChain(C.getArgs(), ArchName);
else
TC = &C.getDefaultToolChain();
BuildJobsForAction(C, *BAA->begin(), TC, BAA->getArchName(),
AtTopLevel, MultipleArchs, LinkingOutput, Result);
return;
}
const ActionList *Inputs = &A->getInputs();
const JobAction *JA = cast<JobAction>(A);
const Tool *T = SelectToolForJob(C, TC, JA, Inputs);
if (!T)
return;
// Only use pipes when there is exactly one input.
InputInfoList InputInfos;
for (ActionList::const_iterator it = Inputs->begin(), ie = Inputs->end();
it != ie; ++it) {
// Treat dsymutil and verify sub-jobs as being at the top-level too, they
// shouldn't get temporary output names.
// FIXME: Clean this up.
bool SubJobAtTopLevel = false;
if (AtTopLevel && (isa<DsymutilJobAction>(A) || isa<VerifyJobAction>(A)))
SubJobAtTopLevel = true;
InputInfo II;
BuildJobsForAction(C, *it, TC, BoundArch, SubJobAtTopLevel, MultipleArchs,
LinkingOutput, II);
InputInfos.push_back(II);
}
// Always use the first input as the base input.
const char *BaseInput = InputInfos[0].getBaseInput();
// ... except dsymutil actions, which use their actual input as the base
// input.
if (JA->getType() == types::TY_dSYM)
BaseInput = InputInfos[0].getFilename();
2010-08-02 10:38:15 +08:00
// Determine the place to write output to, if any.
if (JA->getType() == types::TY_Nothing)
Result = InputInfo(A->getType(), BaseInput);
else
Result = InputInfo(GetNamedOutputPath(C, *JA, BaseInput, BoundArch,
AtTopLevel, MultipleArchs),
A->getType(), BaseInput);
if (CCCPrintBindings && !CCGenDiagnostics) {
llvm::errs() << "# \"" << T->getToolChain().getTripleString() << '"'
<< " - \"" << T->getName() << "\", inputs: [";
for (unsigned i = 0, e = InputInfos.size(); i != e; ++i) {
llvm::errs() << InputInfos[i].getAsString();
if (i + 1 != e)
llvm::errs() << ", ";
}
llvm::errs() << "], output: " << Result.getAsString() << "\n";
} else {
T->ConstructJob(C, *JA, Result, InputInfos,
C.getArgsForToolChain(TC, BoundArch), LinkingOutput);
}
}
/// \brief Create output filename based on ArgValue, which could either be a
/// full filename, filename without extension, or a directory. If ArgValue
/// does not provide a filename, then use BaseName, and use the extension
/// suitable for FileType.
static const char *MakeCLOutputFilename(const ArgList &Args, StringRef ArgValue,
StringRef BaseName, types::ID FileType) {
SmallString<128> Filename = ArgValue;
if (ArgValue.empty()) {
// If the argument is empty, output to BaseName in the current dir.
Filename = BaseName;
} else if (llvm::sys::path::is_separator(Filename.back())) {
// If the argument is a directory, output to BaseName in that dir.
llvm::sys::path::append(Filename, BaseName);
}
if (!llvm::sys::path::has_extension(ArgValue)) {
// If the argument didn't provide an extension, then set it.
const char *Extension = types::getTypeTempSuffix(FileType, true);
if (FileType == types::TY_Image &&
Args.hasArg(options::OPT__SLASH_LD, options::OPT__SLASH_LDd)) {
// The output file is a dll.
Extension = "dll";
}
llvm::sys::path::replace_extension(Filename, Extension);
}
return Args.MakeArgString(Filename.c_str());
}
const char *Driver::GetNamedOutputPath(Compilation &C,
const JobAction &JA,
const char *BaseInput,
const char *BoundArch,
bool AtTopLevel,
bool MultipleArchs) const {
llvm::PrettyStackTraceString CrashInfo("Computing output path");
// Output to a user requested destination?
if (AtTopLevel && !isa<DsymutilJobAction>(JA) &&
!isa<VerifyJobAction>(JA)) {
if (Arg *FinalOutput = C.getArgs().getLastArg(options::OPT_o))
return C.addResultFile(FinalOutput->getValue(), &JA);
}
// For /P, preprocess to file named after BaseInput.
if (C.getArgs().hasArg(options::OPT__SLASH_P)) {
assert(AtTopLevel && isa<PreprocessJobAction>(JA));
StringRef BaseName = llvm::sys::path::filename(BaseInput);
return C.addResultFile(MakeCLOutputFilename(C.getArgs(), "", BaseName,
types::TY_PP_C), &JA);
}
// Default to writing to stdout?
if (AtTopLevel && !CCGenDiagnostics &&
(isa<PreprocessJobAction>(JA) || JA.getType() == types::TY_ModuleFile))
return "-";
// Is this the assembly listing for /FA?
if (JA.getType() == types::TY_PP_Asm &&
(C.getArgs().hasArg(options::OPT__SLASH_FA) ||
C.getArgs().hasArg(options::OPT__SLASH_Fa))) {
// Use /Fa and the input filename to determine the asm file name.
StringRef BaseName = llvm::sys::path::filename(BaseInput);
StringRef FaValue = C.getArgs().getLastArgValue(options::OPT__SLASH_Fa);
return C.addResultFile(MakeCLOutputFilename(C.getArgs(), FaValue, BaseName,
JA.getType()), &JA);
}
// Output to a temporary file?
if ((!AtTopLevel && !C.getArgs().hasArg(options::OPT_save_temps) &&
!C.getArgs().hasArg(options::OPT__SLASH_Fo)) ||
CCGenDiagnostics) {
StringRef Name = llvm::sys::path::filename(BaseInput);
std::pair<StringRef, StringRef> Split = Name.split('.');
std::string TmpName =
GetTemporaryPath(Split.first,
types::getTypeTempSuffix(JA.getType(), IsCLMode()));
return C.addTempFile(C.getArgs().MakeArgString(TmpName.c_str()));
}
SmallString<128> BasePath(BaseInput);
StringRef BaseName;
// Dsymutil actions should use the full path.
if (isa<DsymutilJobAction>(JA) || isa<VerifyJobAction>(JA))
BaseName = BasePath;
else
BaseName = llvm::sys::path::filename(BasePath);
// Determine what the derived output name should be.
const char *NamedOutput;
if (JA.getType() == types::TY_Object &&
C.getArgs().hasArg(options::OPT__SLASH_Fo)) {
// The /Fo flag decides the object filename.
StringRef Val = C.getArgs().getLastArg(options::OPT__SLASH_Fo)->getValue();
NamedOutput = MakeCLOutputFilename(C.getArgs(), Val, BaseName,
types::TY_Object);
} else if (JA.getType() == types::TY_Image &&
C.getArgs().hasArg(options::OPT__SLASH_Fe)) {
// The /Fe flag names the linked file.
StringRef Val = C.getArgs().getLastArg(options::OPT__SLASH_Fe)->getValue();
NamedOutput = MakeCLOutputFilename(C.getArgs(), Val, BaseName,
types::TY_Image);
} else if (JA.getType() == types::TY_Image) {
if (IsCLMode()) {
// clang-cl uses BaseName for the executable name.
NamedOutput = MakeCLOutputFilename(C.getArgs(), "", BaseName,
types::TY_Image);
} else if (MultipleArchs && BoundArch) {
SmallString<128> Output(DefaultImageName.c_str());
Output += "-";
Output.append(BoundArch);
NamedOutput = C.getArgs().MakeArgString(Output.c_str());
} else
NamedOutput = DefaultImageName.c_str();
} else {
const char *Suffix = types::getTypeTempSuffix(JA.getType(), IsCLMode());
assert(Suffix && "All types used for output should have a suffix.");
std::string::size_type End = std::string::npos;
if (!types::appendSuffixForType(JA.getType()))
End = BaseName.rfind('.');
SmallString<128> Suffixed(BaseName.substr(0, End));
if (MultipleArchs && BoundArch) {
Suffixed += "-";
Suffixed.append(BoundArch);
}
Suffixed += '.';
Suffixed += Suffix;
NamedOutput = C.getArgs().MakeArgString(Suffixed.c_str());
}
// If we're saving temps and the temp file conflicts with the input file,
// then avoid overwriting input file.
if (!AtTopLevel && C.getArgs().hasArg(options::OPT_save_temps) &&
NamedOutput == BaseName) {
bool SameFile = false;
SmallString<256> Result;
llvm::sys::fs::current_path(Result);
llvm::sys::path::append(Result, BaseName);
llvm::sys::fs::equivalent(BaseInput, Result.c_str(), SameFile);
// Must share the same path to conflict.
if (SameFile) {
StringRef Name = llvm::sys::path::filename(BaseInput);
std::pair<StringRef, StringRef> Split = Name.split('.');
std::string TmpName =
GetTemporaryPath(Split.first,
types::getTypeTempSuffix(JA.getType(), IsCLMode()));
return C.addTempFile(C.getArgs().MakeArgString(TmpName.c_str()));
}
}
// As an annoying special case, PCH generation doesn't strip the pathname.
if (JA.getType() == types::TY_PCH) {
llvm::sys::path::remove_filename(BasePath);
if (BasePath.empty())
BasePath = NamedOutput;
else
llvm::sys::path::append(BasePath, NamedOutput);
return C.addResultFile(C.getArgs().MakeArgString(BasePath.c_str()), &JA);
} else {
return C.addResultFile(NamedOutput, &JA);
}
}
std::string Driver::GetFilePath(const char *Name, const ToolChain &TC) const {
// Respect a limited subset of the '-Bprefix' functionality in GCC by
2012-10-04 16:08:56 +08:00
// attempting to use this prefix when looking for file paths.
for (Driver::prefix_list::const_iterator it = PrefixDirs.begin(),
ie = PrefixDirs.end(); it != ie; ++it) {
std::string Dir(*it);
if (Dir.empty())
continue;
if (Dir[0] == '=')
Dir = SysRoot + Dir.substr(1);
SmallString<128> P(Dir);
llvm::sys::path::append(P, Name);
if (llvm::sys::fs::exists(Twine(P)))
return P.str();
}
SmallString<128> P(ResourceDir);
llvm::sys::path::append(P, Name);
if (llvm::sys::fs::exists(Twine(P)))
return P.str();
const ToolChain::path_list &List = TC.getFilePaths();
for (ToolChain::path_list::const_iterator
it = List.begin(), ie = List.end(); it != ie; ++it) {
std::string Dir(*it);
if (Dir.empty())
continue;
if (Dir[0] == '=')
Dir = SysRoot + Dir.substr(1);
SmallString<128> P(Dir);
llvm::sys::path::append(P, Name);
if (llvm::sys::fs::exists(Twine(P)))
return P.str();
}
return Name;
}
std::string Driver::GetProgramPath(const char *Name,
const ToolChain &TC) const {
// FIXME: Needs a better variable than DefaultTargetTriple
Revert r149083 which is not the direction we're going in the Clang driver based on discussions with Doug Gregor. There are several issues: 1) The patch was not reviewed prior to commit and there were review comments. 2) The design of the functionality (triple-prefixed tool invocation) isn't the design we want for Clang going forward: it focuses on the "user triple" rather than on the "toolchain triple", and forces that bit of state into the API of every single toolchain instead of handling it automatically in the common base classes. 3) The tests provided are not stable. They fail on a few Linux variants (Gentoo among them) and on mingw32 and some other environments. I *am* interested in the Clang driver being able to invoke triple-prefixed tools, but we need to design that feature the right way. This patch just extends the previous hack without fixing the underlying problems with it. I'm working on a new design for this that I will mail for review by tomorrow. I am aware that this removes functionality that NetBSD relies on, but this is ToT, not a release. This functionality hasn't been properly designed, implemented, and tested yet. We can't "regress" until we get something that really works, both with the immediate use cases and with long term maintenance of the Clang driver. For reference, the original commit log: Keep track of the original target the user specified before normalization. This used to be captured in DefaultTargetTriple and is used for the (optional) $triple-$tool lookup for cross-compilation. Do this properly by making it an attribute of the toolchain and use it in combination with the computed triple as index for the toolchain lookup. llvm-svn: 149337
2012-01-31 10:21:20 +08:00
std::string TargetSpecificExecutable(DefaultTargetTriple + "-" + Name);
// Respect a limited subset of the '-Bprefix' functionality in GCC by
2012-10-04 16:08:56 +08:00
// attempting to use this prefix when looking for program paths.
for (Driver::prefix_list::const_iterator it = PrefixDirs.begin(),
ie = PrefixDirs.end(); it != ie; ++it) {
if (llvm::sys::fs::is_directory(*it)) {
SmallString<128> P(*it);
llvm::sys::path::append(P, TargetSpecificExecutable);
if (llvm::sys::fs::can_execute(Twine(P)))
return P.str();
llvm::sys::path::remove_filename(P);
llvm::sys::path::append(P, Name);
if (llvm::sys::fs::can_execute(Twine(P)))
return P.str();
} else {
SmallString<128> P(*it + Name);
if (llvm::sys::fs::can_execute(Twine(P)))
return P.str();
}
}
const ToolChain::path_list &List = TC.getProgramPaths();
for (ToolChain::path_list::const_iterator
it = List.begin(), ie = List.end(); it != ie; ++it) {
SmallString<128> P(*it);
llvm::sys::path::append(P, TargetSpecificExecutable);
if (llvm::sys::fs::can_execute(Twine(P)))
return P.str();
llvm::sys::path::remove_filename(P);
llvm::sys::path::append(P, Name);
if (llvm::sys::fs::can_execute(Twine(P)))
return P.str();
}
// If all else failed, search the path.
std::string P(llvm::sys::FindProgramByName(TargetSpecificExecutable));
if (!P.empty())
return P;
P = llvm::sys::FindProgramByName(Name);
if (!P.empty())
return P;
return Name;
}
std::string Driver::GetTemporaryPath(StringRef Prefix, const char *Suffix)
const {
SmallString<128> Path;
llvm::error_code EC =
llvm::sys::fs::createTemporaryFile(Prefix, Suffix, Path);
if (EC) {
Diag(clang::diag::err_unable_to_make_temp) << EC.message();
return "";
}
return Path.str();
}
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
/// \brief Compute target triple from args.
///
/// This routine provides the logic to compute a target triple from various
/// args passed to the driver and the default triple string.
Revert r149083 which is not the direction we're going in the Clang driver based on discussions with Doug Gregor. There are several issues: 1) The patch was not reviewed prior to commit and there were review comments. 2) The design of the functionality (triple-prefixed tool invocation) isn't the design we want for Clang going forward: it focuses on the "user triple" rather than on the "toolchain triple", and forces that bit of state into the API of every single toolchain instead of handling it automatically in the common base classes. 3) The tests provided are not stable. They fail on a few Linux variants (Gentoo among them) and on mingw32 and some other environments. I *am* interested in the Clang driver being able to invoke triple-prefixed tools, but we need to design that feature the right way. This patch just extends the previous hack without fixing the underlying problems with it. I'm working on a new design for this that I will mail for review by tomorrow. I am aware that this removes functionality that NetBSD relies on, but this is ToT, not a release. This functionality hasn't been properly designed, implemented, and tested yet. We can't "regress" until we get something that really works, both with the immediate use cases and with long term maintenance of the Clang driver. For reference, the original commit log: Keep track of the original target the user specified before normalization. This used to be captured in DefaultTargetTriple and is used for the (optional) $triple-$tool lookup for cross-compilation. Do this properly by making it an attribute of the toolchain and use it in combination with the computed triple as index for the toolchain lookup. llvm-svn: 149337
2012-01-31 10:21:20 +08:00
static llvm::Triple computeTargetTriple(StringRef DefaultTargetTriple,
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
const ArgList &Args,
StringRef DarwinArchName) {
// FIXME: Already done in Compilation *Driver::BuildCompilation
Revert r149083 which is not the direction we're going in the Clang driver based on discussions with Doug Gregor. There are several issues: 1) The patch was not reviewed prior to commit and there were review comments. 2) The design of the functionality (triple-prefixed tool invocation) isn't the design we want for Clang going forward: it focuses on the "user triple" rather than on the "toolchain triple", and forces that bit of state into the API of every single toolchain instead of handling it automatically in the common base classes. 3) The tests provided are not stable. They fail on a few Linux variants (Gentoo among them) and on mingw32 and some other environments. I *am* interested in the Clang driver being able to invoke triple-prefixed tools, but we need to design that feature the right way. This patch just extends the previous hack without fixing the underlying problems with it. I'm working on a new design for this that I will mail for review by tomorrow. I am aware that this removes functionality that NetBSD relies on, but this is ToT, not a release. This functionality hasn't been properly designed, implemented, and tested yet. We can't "regress" until we get something that really works, both with the immediate use cases and with long term maintenance of the Clang driver. For reference, the original commit log: Keep track of the original target the user specified before normalization. This used to be captured in DefaultTargetTriple and is used for the (optional) $triple-$tool lookup for cross-compilation. Do this properly by making it an attribute of the toolchain and use it in combination with the computed triple as index for the toolchain lookup. llvm-svn: 149337
2012-01-31 10:21:20 +08:00
if (const Arg *A = Args.getLastArg(options::OPT_target))
DefaultTargetTriple = A->getValue();
Revert r149083 which is not the direction we're going in the Clang driver based on discussions with Doug Gregor. There are several issues: 1) The patch was not reviewed prior to commit and there were review comments. 2) The design of the functionality (triple-prefixed tool invocation) isn't the design we want for Clang going forward: it focuses on the "user triple" rather than on the "toolchain triple", and forces that bit of state into the API of every single toolchain instead of handling it automatically in the common base classes. 3) The tests provided are not stable. They fail on a few Linux variants (Gentoo among them) and on mingw32 and some other environments. I *am* interested in the Clang driver being able to invoke triple-prefixed tools, but we need to design that feature the right way. This patch just extends the previous hack without fixing the underlying problems with it. I'm working on a new design for this that I will mail for review by tomorrow. I am aware that this removes functionality that NetBSD relies on, but this is ToT, not a release. This functionality hasn't been properly designed, implemented, and tested yet. We can't "regress" until we get something that really works, both with the immediate use cases and with long term maintenance of the Clang driver. For reference, the original commit log: Keep track of the original target the user specified before normalization. This used to be captured in DefaultTargetTriple and is used for the (optional) $triple-$tool lookup for cross-compilation. Do this properly by making it an attribute of the toolchain and use it in combination with the computed triple as index for the toolchain lookup. llvm-svn: 149337
2012-01-31 10:21:20 +08:00
llvm::Triple Target(llvm::Triple::normalize(DefaultTargetTriple));
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
// Handle Apple-specific options available here.
if (Target.isOSBinFormatMachO()) {
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
// If an explict Darwin arch name is given, that trumps all.
if (!DarwinArchName.empty()) {
tools::darwin::setTripleTypeForMachOArchName(Target, DarwinArchName);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
return Target;
}
// Handle the Darwin '-arch' flag.
if (Arg *A = Args.getLastArg(options::OPT_arch)) {
StringRef ArchName = A->getValue();
tools::darwin::setTripleTypeForMachOArchName(Target, ArchName);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
}
}
// Handle pseudo-target flags '-EL' and '-EB'.
if (Arg *A = Args.getLastArg(options::OPT_EL, options::OPT_EB)) {
if (A->getOption().matches(options::OPT_EL)) {
if (Target.getArch() == llvm::Triple::mips)
Target.setArch(llvm::Triple::mipsel);
else if (Target.getArch() == llvm::Triple::mips64)
Target.setArch(llvm::Triple::mips64el);
} else {
if (Target.getArch() == llvm::Triple::mipsel)
Target.setArch(llvm::Triple::mips);
else if (Target.getArch() == llvm::Triple::mips64el)
Target.setArch(llvm::Triple::mips64);
}
}
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
// Skip further flag support on OSes which don't support '-m32' or '-m64'.
if (Target.getArchName() == "tce" ||
Target.getOS() == llvm::Triple::AuroraUX ||
Target.getOS() == llvm::Triple::Minix)
return Target;
// Handle pseudo-target flags '-m64', '-m32' and '-m16'.
if (Arg *A = Args.getLastArg(options::OPT_m64, options::OPT_m32,
options::OPT_m16)) {
llvm::Triple::ArchType AT = llvm::Triple::UnknownArch;
if (A->getOption().matches(options::OPT_m64))
AT = Target.get64BitArchVariant().getArch();
else if (A->getOption().matches(options::OPT_m32))
AT = Target.get32BitArchVariant().getArch();
else if (A->getOption().matches(options::OPT_m16) &&
Target.get32BitArchVariant().getArch() == llvm::Triple::x86) {
AT = llvm::Triple::x86;
Target.setEnvironment(llvm::Triple::CODE16);
}
if (AT != llvm::Triple::UnknownArch)
Target.setArch(AT);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
}
return Target;
}
const ToolChain &Driver::getToolChain(const ArgList &Args,
StringRef DarwinArchName) const {
Revert r149083 which is not the direction we're going in the Clang driver based on discussions with Doug Gregor. There are several issues: 1) The patch was not reviewed prior to commit and there were review comments. 2) The design of the functionality (triple-prefixed tool invocation) isn't the design we want for Clang going forward: it focuses on the "user triple" rather than on the "toolchain triple", and forces that bit of state into the API of every single toolchain instead of handling it automatically in the common base classes. 3) The tests provided are not stable. They fail on a few Linux variants (Gentoo among them) and on mingw32 and some other environments. I *am* interested in the Clang driver being able to invoke triple-prefixed tools, but we need to design that feature the right way. This patch just extends the previous hack without fixing the underlying problems with it. I'm working on a new design for this that I will mail for review by tomorrow. I am aware that this removes functionality that NetBSD relies on, but this is ToT, not a release. This functionality hasn't been properly designed, implemented, and tested yet. We can't "regress" until we get something that really works, both with the immediate use cases and with long term maintenance of the Clang driver. For reference, the original commit log: Keep track of the original target the user specified before normalization. This used to be captured in DefaultTargetTriple and is used for the (optional) $triple-$tool lookup for cross-compilation. Do this properly by making it an attribute of the toolchain and use it in combination with the computed triple as index for the toolchain lookup. llvm-svn: 149337
2012-01-31 10:21:20 +08:00
llvm::Triple Target = computeTargetTriple(DefaultTargetTriple, Args,
DarwinArchName);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
Revert r149083 which is not the direction we're going in the Clang driver based on discussions with Doug Gregor. There are several issues: 1) The patch was not reviewed prior to commit and there were review comments. 2) The design of the functionality (triple-prefixed tool invocation) isn't the design we want for Clang going forward: it focuses on the "user triple" rather than on the "toolchain triple", and forces that bit of state into the API of every single toolchain instead of handling it automatically in the common base classes. 3) The tests provided are not stable. They fail on a few Linux variants (Gentoo among them) and on mingw32 and some other environments. I *am* interested in the Clang driver being able to invoke triple-prefixed tools, but we need to design that feature the right way. This patch just extends the previous hack without fixing the underlying problems with it. I'm working on a new design for this that I will mail for review by tomorrow. I am aware that this removes functionality that NetBSD relies on, but this is ToT, not a release. This functionality hasn't been properly designed, implemented, and tested yet. We can't "regress" until we get something that really works, both with the immediate use cases and with long term maintenance of the Clang driver. For reference, the original commit log: Keep track of the original target the user specified before normalization. This used to be captured in DefaultTargetTriple and is used for the (optional) $triple-$tool lookup for cross-compilation. Do this properly by making it an attribute of the toolchain and use it in combination with the computed triple as index for the toolchain lookup. llvm-svn: 149337
2012-01-31 10:21:20 +08:00
ToolChain *&TC = ToolChains[Target.str()];
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
if (!TC) {
switch (Target.getOS()) {
case llvm::Triple::AuroraUX:
TC = new toolchains::AuroraUX(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::Darwin:
case llvm::Triple::MacOSX:
case llvm::Triple::IOS:
TC = new toolchains::DarwinClang(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::DragonFly:
TC = new toolchains::DragonFly(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::OpenBSD:
TC = new toolchains::OpenBSD(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::Bitrig:
TC = new toolchains::Bitrig(*this, Target, Args);
break;
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
case llvm::Triple::NetBSD:
TC = new toolchains::NetBSD(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::FreeBSD:
TC = new toolchains::FreeBSD(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::Minix:
TC = new toolchains::Minix(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::Linux:
if (Target.getArch() == llvm::Triple::hexagon)
TC = new toolchains::Hexagon_TC(*this, Target, Args);
else
TC = new toolchains::Linux(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::Solaris:
TC = new toolchains::Solaris(*this, Target, Args);
break;
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
case llvm::Triple::Win32:
TC = new toolchains::Windows(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
case llvm::Triple::MinGW32:
// FIXME: We need a MinGW toolchain. Fallthrough for now.
default:
// TCE is an OSless target
if (Target.getArchName() == "tce") {
TC = new toolchains::TCEToolChain(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
}
// If Hexagon is configured as an OSless target
if (Target.getArch() == llvm::Triple::hexagon) {
TC = new toolchains::Hexagon_TC(*this, Target, Args);
break;
}
if (Target.getArch() == llvm::Triple::xcore) {
TC = new toolchains::XCore(*this, Target, Args);
break;
}
if (Target.isOSBinFormatELF()) {
TC = new toolchains::Generic_ELF(*this, Target, Args);
break;
}
if (Target.getObjectFormat() == llvm::Triple::MachO) {
TC = new toolchains::MachO(*this, Target, Args);
break;
}
TC = new toolchains::Generic_GCC(*this, Target, Args);
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
break;
}
}
Delete the driver's HostInfo class. This abstraction just never really did anything. The two big pieces of functionality it tried to provide was to cache the ToolChain objects for each target, and to figure out the exact target based on the flag set coming in to an invocation. However, it had a lot of flaws even with those goals: - Neither of these have anything to do with the host, or its info. - The HostInfo class was setup as a full blown class *hierarchy* with a separate implementation for each "host" OS. This required dispatching just to create the objects in the first place. - The hierarchy claimed to represent the host, when in fact it was based on the target OS. - Each leaf in the hierarchy was responsible for implementing the flag processing and caching, resulting in a *lot* of copy-paste code and quite a few bugs. - The caching was consistently done based on architecture alone, even though *any* aspect of the targeted triple might change the behavior of the configured toolchain. - Flag processing was already being done in the Driver proper, separating the flag handling even more than it already is. Instead of this, we can simply have the dispatch logic in the Driver which previously created a HostInfo object create the ToolChain objects. Adding caching in the Driver layer is a tiny amount of code. Finally, pulling the flag processing into the Driver puts it where it belongs and consolidates it in one location. The result is that two functions, and maybe 100 lines of new code replace over 10 classes and 800 lines of code. Woot. This also paves the way to introduce more detailed ToolChain objects for various OSes without threading through a new HostInfo type as well, and the accompanying boiler plate. That, of course, was the yak I started to shave that began this entire refactoring escapade. Wheee! llvm-svn: 148950
2012-01-25 19:01:57 +08:00
return *TC;
}
bool Driver::ShouldUseClangCompiler(const JobAction &JA) const {
// Check if user requested no clang, or clang doesn't understand this type (we
// only handle single inputs for now).
if (JA.size() != 1 ||
!types::isAcceptedByClang((*JA.begin())->getType()))
return false;
// Otherwise make sure this is an action clang understands.
if (!isa<PreprocessJobAction>(JA) && !isa<PrecompileJobAction>(JA) &&
!isa<CompileJobAction>(JA))
return false;
return true;
}
/// GetReleaseVersion - Parse (([0-9]+)(.([0-9]+)(.([0-9]+)?))?)? and return the
/// grouped values as integers. Numbers which are not provided are set to 0.
///
/// \return True if the entire string was parsed (9.2), or all groups were
/// parsed (10.3.5extrastuff).
bool Driver::GetReleaseVersion(const char *Str, unsigned &Major,
unsigned &Minor, unsigned &Micro,
bool &HadExtra) {
HadExtra = false;
Major = Minor = Micro = 0;
if (*Str == '\0')
return true;
char *End;
Major = (unsigned) strtol(Str, &End, 10);
if (*Str != '\0' && *End == '\0')
return true;
if (*End != '.')
return false;
Str = End+1;
Minor = (unsigned) strtol(Str, &End, 10);
if (*Str != '\0' && *End == '\0')
return true;
if (*End != '.')
return false;
Str = End+1;
Micro = (unsigned) strtol(Str, &End, 10);
if (*Str != '\0' && *End == '\0')
return true;
if (Str == End)
return false;
HadExtra = true;
return true;
}
std::pair<unsigned, unsigned> Driver::getIncludeExcludeOptionFlagMasks() const {
unsigned IncludedFlagsBitmask = 0;
unsigned ExcludedFlagsBitmask = options::NoDriverOption;
if (Mode == CLMode) {
// Include CL and Core options.
IncludedFlagsBitmask |= options::CLOption;
IncludedFlagsBitmask |= options::CoreOption;
} else {
ExcludedFlagsBitmask |= options::CLOption;
}
return std::make_pair(IncludedFlagsBitmask, ExcludedFlagsBitmask);
}