lib/Frontend/FrontendActions.cpp - llvm-project/flang - Git at Google

 //===--- FrontendActions.cpp ----------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "flang/Frontend/FrontendActions.h"
 #include "flang/Common/default-kinds.h"
 #include "flang/Frontend/CompilerInstance.h"
 #include "flang/Frontend/FrontendOptions.h"
 #include "flang/Frontend/PreprocessorOptions.h"
 #include "flang/Lower/PFTBuilder.h"
 #include "flang/Parser/dump-parse-tree.h"
 #include "flang/Parser/parsing.h"
 #include "flang/Parser/provenance.h"
 #include "flang/Parser/source.h"
 #include "flang/Parser/unparse.h"
 #include "flang/Semantics/runtime-type-info.h"
 #include "flang/Semantics/semantics.h"
 #include "flang/Semantics/unparse-with-symbols.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/ErrorHandling.h"
 #include <clang/Basic/Diagnostic.h>
 #include <memory>

 using namespace Fortran::frontend;

 //===----------------------------------------------------------------------===//
 // Custom BeginSourceFileAction
 //===----------------------------------------------------------------------===//
 bool PrescanAction::BeginSourceFileAction() { return RunPrescan(); }

 bool PrescanAndParseAction::BeginSourceFileAction() {
   return RunPrescan() && RunParse();
 }

 bool PrescanAndSemaAction::BeginSourceFileAction() {
   return RunPrescan() & RunParse() && RunSemanticChecks();
 }

 //===----------------------------------------------------------------------===//
 // Custom ExecuteAction
 //===----------------------------------------------------------------------===//
 void InputOutputTestAction::ExecuteAction() {
   CompilerInstance &ci = instance();

   // Create a stream for errors
   std::string buf;
   llvm::raw_string_ostream error_stream{buf};

   // Read the input file
   Fortran::parser::AllSources &allSources{ci.allSources()};
   std::string path{GetCurrentFileOrBufferName()};
   const Fortran::parser::SourceFile *sf;
   if (path == "-")
     sf = allSources.ReadStandardInput(error_stream);
   else
     sf = allSources.Open(path, error_stream, std::optional<std::string>{"."s});
   llvm::ArrayRef<char> fileContent = sf->content();

   // Output file descriptor to receive the contents of the input file.
   std::unique_ptr<llvm::raw_ostream> os;

   // Copy the contents from the input file to the output file
   if (!ci.IsOutputStreamNull()) {
     // An output stream (outputStream_) was set earlier
     ci.WriteOutputStream(fileContent.data());
   } else {
     // No pre-set output stream - create an output file
     os = ci.CreateDefaultOutputFile(
         /*binary=*/true, GetCurrentFileOrBufferName(), "txt");
     if (!os)
       return;
     (*os) << fileContent.data();
   }
 }

 void PrintPreprocessedAction::ExecuteAction() {
   std::string buf;
   llvm::raw_string_ostream outForPP{buf};

   // Format or dump the prescanner's output
   CompilerInstance &ci = this->instance();
   if (ci.invocation().preprocessorOpts().noReformat) {
     ci.parsing().DumpCookedChars(outForPP);
   } else {
     ci.parsing().EmitPreprocessedSource(
         outForPP, !ci.invocation().preprocessorOpts().noLineDirectives);
   }

   // Print diagnostics from the prescanner
   ci.parsing().messages().Emit(llvm::errs(), ci.allCookedSources());

   // If a pre-defined output stream exists, dump the preprocessed content there
   if (!ci.IsOutputStreamNull()) {
     // Send the output to the pre-defined output buffer.
     ci.WriteOutputStream(outForPP.str());
     return;
   }

   // Create a file and save the preprocessed output there
   std::unique_ptr<llvm::raw_pwrite_stream> os{ci.CreateDefaultOutputFile(
       /*Binary=*/true, /*InFile=*/GetCurrentFileOrBufferName())};
   if (!os) {
     return;
   }

   (*os) << outForPP.str();
 }

 void DebugDumpProvenanceAction::ExecuteAction() {
   this->instance().parsing().DumpProvenance(llvm::outs());
 }

 void ParseSyntaxOnlyAction::ExecuteAction() {
 }

 void DebugUnparseNoSemaAction::ExecuteAction() {
   auto &invoc = this->instance().invocation();
   auto &parseTree{instance().parsing().parseTree()};

   // TODO: Options should come from CompilerInvocation
   Unparse(llvm::outs(), *parseTree,
       /*encoding=*/Fortran::parser::Encoding::UTF_8,
       /*capitalizeKeywords=*/true, /*backslashEscapes=*/false,
       /*preStatement=*/nullptr,
       invoc.useAnalyzedObjectsForUnparse() ? &invoc.asFortran() : nullptr);
 }

 void DebugUnparseAction::ExecuteAction() {
   auto &invoc = this->instance().invocation();
   auto &parseTree{instance().parsing().parseTree()};

   CompilerInstance &ci = this->instance();
   auto os{ci.CreateDefaultOutputFile(
       /*Binary=*/false, /*InFile=*/GetCurrentFileOrBufferName())};

   // TODO: Options should come from CompilerInvocation
   Unparse(*os, *parseTree,
       /*encoding=*/Fortran::parser::Encoding::UTF_8,
       /*capitalizeKeywords=*/true, /*backslashEscapes=*/false,
       /*preStatement=*/nullptr,
       invoc.useAnalyzedObjectsForUnparse() ? &invoc.asFortran() : nullptr);

   // Report fatal semantic errors
   reportFatalSemanticErrors();
 }

 void DebugUnparseWithSymbolsAction::ExecuteAction() {
   auto &parseTree{*instance().parsing().parseTree()};

   Fortran::semantics::UnparseWithSymbols(
       llvm::outs(), parseTree, /*encoding=*/Fortran::parser::Encoding::UTF_8);

   // Report fatal semantic errors
   reportFatalSemanticErrors();
 }

 void DebugDumpSymbolsAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();
   auto &semantics = ci.semantics();

   auto tables{Fortran::semantics::BuildRuntimeDerivedTypeTables(
       instance().invocation().semanticsContext())};
   // The runtime derived type information table builder may find and report
   // semantic errors. So it is important that we report them _after_
   // BuildRuntimeDerivedTypeTables is run.
   reportFatalSemanticErrors();

   if (!tables.schemata) {
     unsigned DiagID =
         ci.diagnostics().getCustomDiagID(clang::DiagnosticsEngine::Error,
             "could not find module file for __fortran_type_info");
     ci.diagnostics().Report(DiagID);
     llvm::errs() << "\n";
   }

   // Dump symbols
   semantics.DumpSymbols(llvm::outs());
 }

 void DebugDumpAllAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();

   // Dump parse tree
   auto &parseTree{instance().parsing().parseTree()};
   llvm::outs() << "========================";
   llvm::outs() << " Flang: parse tree dump ";
   llvm::outs() << "========================\n";
   Fortran::parser::DumpTree(
       llvm::outs(), parseTree, &ci.invocation().asFortran());

   auto &semantics = ci.semantics();
   auto tables{Fortran::semantics::BuildRuntimeDerivedTypeTables(
       instance().invocation().semanticsContext())};
   // The runtime derived type information table builder may find and report
   // semantic errors. So it is important that we report them _after_
   // BuildRuntimeDerivedTypeTables is run.
   reportFatalSemanticErrors();

   if (!tables.schemata) {
     unsigned DiagID =
         ci.diagnostics().getCustomDiagID(clang::DiagnosticsEngine::Error,
             "could not find module file for __fortran_type_info");
     ci.diagnostics().Report(DiagID);
     llvm::errs() << "\n";
   }

   // Dump symbols
   llvm::outs() << "=====================";
   llvm::outs() << " Flang: symbols dump ";
   llvm::outs() << "=====================\n";
   semantics.DumpSymbols(llvm::outs());
 }

 void DebugDumpParseTreeNoSemaAction::ExecuteAction() {
   auto &parseTree{instance().parsing().parseTree()};

   // Dump parse tree
   Fortran::parser::DumpTree(
       llvm::outs(), parseTree, &this->instance().invocation().asFortran());
 }

 void DebugDumpParseTreeAction::ExecuteAction() {
   auto &parseTree{instance().parsing().parseTree()};

   // Dump parse tree
   Fortran::parser::DumpTree(
       llvm::outs(), parseTree, &this->instance().invocation().asFortran());

   // Report fatal semantic errors
   reportFatalSemanticErrors();
 }

 void DebugMeasureParseTreeAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();

   // Parse. In case of failure, report and return.
   ci.parsing().Parse(llvm::outs());

   if (!ci.parsing().messages().empty() &&
       (ci.invocation().warnAsErr() ||
           ci.parsing().messages().AnyFatalError())) {
     unsigned diagID = ci.diagnostics().getCustomDiagID(
         clang::DiagnosticsEngine::Error, "Could not parse %0");
     ci.diagnostics().Report(diagID) << GetCurrentFileOrBufferName();

     ci.parsing().messages().Emit(
         llvm::errs(), this->instance().allCookedSources());
     return;
   }

   // Report the diagnostics from parsing
   ci.parsing().messages().Emit(llvm::errs(), ci.allCookedSources());

   auto &parseTree{*ci.parsing().parseTree()};

   // Measure the parse tree
   MeasurementVisitor visitor;
   Fortran::parser::Walk(parseTree, visitor);
   llvm::outs() << "Parse tree comprises " << visitor.objects
                << " objects and occupies " << visitor.bytes
                << " total bytes.\n";
 }

 void DebugPreFIRTreeAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();
   // Report and exit if fatal semantic errors are present
   if (reportFatalSemanticErrors()) {
     return;
   }

   auto &parseTree{*ci.parsing().parseTree()};

   // Dump pre-FIR tree
   if (auto ast{Fortran::lower::createPFT(
           parseTree, ci.invocation().semanticsContext())}) {
     Fortran::lower::dumpPFT(llvm::outs(), *ast);
   } else {
     unsigned diagID = ci.diagnostics().getCustomDiagID(
         clang::DiagnosticsEngine::Error, "Pre FIR Tree is NULL.");
     ci.diagnostics().Report(diagID);
   }
 }

 void DebugDumpParsingLogAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();

   ci.parsing().Parse(llvm::errs());
   ci.parsing().DumpParsingLog(llvm::outs());
 }

 void GetDefinitionAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();

   // Report and exit if fatal semantic errors are present
   if (reportFatalSemanticErrors()) {
     return;
   }

   parser::AllCookedSources &cs = ci.allCookedSources();
   unsigned diagID = ci.diagnostics().getCustomDiagID(
       clang::DiagnosticsEngine::Error, "Symbol not found");

   auto gdv = ci.invocation().frontendOpts().getDefVals;
   auto charBlock{cs.GetCharBlockFromLineAndColumns(
       gdv.line, gdv.startColumn, gdv.endColumn)};
   if (!charBlock) {
     ci.diagnostics().Report(diagID);
     return;
   }

   llvm::outs() << "String range: >" << charBlock->ToString() << "<\n";

   auto *symbol{ci.invocation()
                    .semanticsContext()
                    .FindScope(*charBlock)
                    .FindSymbol(*charBlock)};
   if (!symbol) {
     ci.diagnostics().Report(diagID);
     return;
   }

   llvm::outs() << "Found symbol name: " << symbol->name().ToString() << "\n";

   auto sourceInfo{cs.GetSourcePositionRange(symbol->name())};
   if (!sourceInfo) {
     llvm_unreachable(
         "Failed to obtain SourcePosition."
         "TODO: Please, write a test and replace this with a diagnostic!");
     return;
   }

   llvm::outs() << "Found symbol name: " << symbol->name().ToString() << "\n";
   llvm::outs() << symbol->name().ToString() << ": "
                << sourceInfo->first.file.path() << ", "
                << sourceInfo->first.line << ", " << sourceInfo->first.column
                << "-" << sourceInfo->second.column << "\n";
 }

 void GetSymbolsSourcesAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();

   // Report and exit if fatal semantic errors are present
   if (reportFatalSemanticErrors()) {
     return;
   }

   ci.semantics().DumpSymbolsSources(llvm::outs());
 }

 void EmitObjAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();
   unsigned DiagID = ci.diagnostics().getCustomDiagID(
       clang::DiagnosticsEngine::Error, "code-generation is not available yet");
   ci.diagnostics().Report(DiagID);
 }

 void InitOnlyAction::ExecuteAction() {
   CompilerInstance &ci = this->instance();
   unsigned DiagID =
       ci.diagnostics().getCustomDiagID(clang::DiagnosticsEngine::Warning,
           "Use `-init-only` for testing purposes only");
   ci.diagnostics().Report(DiagID);
 }

 void PluginParseTreeAction::ExecuteAction() {}
	//===--- FrontendActions.cpp ----------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "flang/Frontend/FrontendActions.h"
	#include "flang/Common/default-kinds.h"
	#include "flang/Frontend/CompilerInstance.h"
	#include "flang/Frontend/FrontendOptions.h"
	#include "flang/Frontend/PreprocessorOptions.h"
	#include "flang/Lower/PFTBuilder.h"
	#include "flang/Parser/dump-parse-tree.h"
	#include "flang/Parser/parsing.h"
	#include "flang/Parser/provenance.h"
	#include "flang/Parser/source.h"
	#include "flang/Parser/unparse.h"
	#include "flang/Semantics/runtime-type-info.h"
	#include "flang/Semantics/semantics.h"
	#include "flang/Semantics/unparse-with-symbols.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/ErrorHandling.h"
	#include <clang/Basic/Diagnostic.h>
	#include <memory>

	using namespace Fortran::frontend;

	//===----------------------------------------------------------------------===//
	// Custom BeginSourceFileAction
	//===----------------------------------------------------------------------===//
	bool PrescanAction::BeginSourceFileAction() { return RunPrescan(); }

	bool PrescanAndParseAction::BeginSourceFileAction() {
	return RunPrescan() && RunParse();
	}

	bool PrescanAndSemaAction::BeginSourceFileAction() {
	return RunPrescan() & RunParse() && RunSemanticChecks();
	}

	//===----------------------------------------------------------------------===//
	// Custom ExecuteAction
	//===----------------------------------------------------------------------===//
	void InputOutputTestAction::ExecuteAction() {
	CompilerInstance &ci = instance();

	// Create a stream for errors
	std::string buf;
	llvm::raw_string_ostream error_stream{buf};

	// Read the input file
	Fortran::parser::AllSources &allSources{ci.allSources()};
	std::string path{GetCurrentFileOrBufferName()};
	const Fortran::parser::SourceFile *sf;
	if (path == "-")
	sf = allSources.ReadStandardInput(error_stream);
	else
	sf = allSources.Open(path, error_stream, std::optional<std::string>{"."s});
	llvm::ArrayRef<char> fileContent = sf->content();

	// Output file descriptor to receive the contents of the input file.
	std::unique_ptr<llvm::raw_ostream> os;

	// Copy the contents from the input file to the output file
	if (!ci.IsOutputStreamNull()) {
	// An output stream (outputStream_) was set earlier
	ci.WriteOutputStream(fileContent.data());
	} else {
	// No pre-set output stream - create an output file
	os = ci.CreateDefaultOutputFile(
	/binary=/true, GetCurrentFileOrBufferName(), "txt");
	if (!os)
	return;
	(*os) << fileContent.data();
	}
	}

	void PrintPreprocessedAction::ExecuteAction() {
	std::string buf;
	llvm::raw_string_ostream outForPP{buf};

	// Format or dump the prescanner's output
	CompilerInstance &ci = this->instance();
	if (ci.invocation().preprocessorOpts().noReformat) {
	ci.parsing().DumpCookedChars(outForPP);
	} else {
	ci.parsing().EmitPreprocessedSource(
	outForPP, !ci.invocation().preprocessorOpts().noLineDirectives);
	}

	// Print diagnostics from the prescanner
	ci.parsing().messages().Emit(llvm::errs(), ci.allCookedSources());

	// If a pre-defined output stream exists, dump the preprocessed content there
	if (!ci.IsOutputStreamNull()) {
	// Send the output to the pre-defined output buffer.
	ci.WriteOutputStream(outForPP.str());
	return;
	}

	// Create a file and save the preprocessed output there
	std::unique_ptr<llvm::raw_pwrite_stream> os{ci.CreateDefaultOutputFile(
	/Binary=/true, /InFile=/GetCurrentFileOrBufferName())};
	if (!os) {
	return;
	}

	(*os) << outForPP.str();
	}

	void DebugDumpProvenanceAction::ExecuteAction() {
	this->instance().parsing().DumpProvenance(llvm::outs());
	}

	void ParseSyntaxOnlyAction::ExecuteAction() {
	}

	void DebugUnparseNoSemaAction::ExecuteAction() {
	auto &invoc = this->instance().invocation();
	auto &parseTree{instance().parsing().parseTree()};

	// TODO: Options should come from CompilerInvocation
	Unparse(llvm::outs(), *parseTree,
	/encoding=/Fortran::parser::Encoding::UTF_8,
	/capitalizeKeywords=/true, /backslashEscapes=/false,
	/preStatement=/nullptr,
	invoc.useAnalyzedObjectsForUnparse() ? &invoc.asFortran() : nullptr);
	}

	void DebugUnparseAction::ExecuteAction() {
	auto &invoc = this->instance().invocation();
	auto &parseTree{instance().parsing().parseTree()};

	CompilerInstance &ci = this->instance();
	auto os{ci.CreateDefaultOutputFile(
	/Binary=/false, /InFile=/GetCurrentFileOrBufferName())};

	// TODO: Options should come from CompilerInvocation
	Unparse(os, parseTree,
	/encoding=/Fortran::parser::Encoding::UTF_8,
	/capitalizeKeywords=/true, /backslashEscapes=/false,
	/preStatement=/nullptr,
	invoc.useAnalyzedObjectsForUnparse() ? &invoc.asFortran() : nullptr);

	// Report fatal semantic errors
	reportFatalSemanticErrors();
	}

	void DebugUnparseWithSymbolsAction::ExecuteAction() {
	auto &parseTree{*instance().parsing().parseTree()};

	Fortran::semantics::UnparseWithSymbols(
	llvm::outs(), parseTree, /encoding=/Fortran::parser::Encoding::UTF_8);

	// Report fatal semantic errors
	reportFatalSemanticErrors();
	}

	void DebugDumpSymbolsAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();
	auto &semantics = ci.semantics();

	auto tables{Fortran::semantics::BuildRuntimeDerivedTypeTables(
	instance().invocation().semanticsContext())};
	// The runtime derived type information table builder may find and report
	// semantic errors. So it is important that we report them _after_
	// BuildRuntimeDerivedTypeTables is run.
	reportFatalSemanticErrors();

	if (!tables.schemata) {
	unsigned DiagID =
	ci.diagnostics().getCustomDiagID(clang::DiagnosticsEngine::Error,
	"could not find module file for __fortran_type_info");
	ci.diagnostics().Report(DiagID);
	llvm::errs() << "\n";
	}

	// Dump symbols
	semantics.DumpSymbols(llvm::outs());
	}

	void DebugDumpAllAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();

	// Dump parse tree
	auto &parseTree{instance().parsing().parseTree()};
	llvm::outs() << "========================";
	llvm::outs() << " Flang: parse tree dump ";
	llvm::outs() << "========================\n";
	Fortran::parser::DumpTree(
	llvm::outs(), parseTree, &ci.invocation().asFortran());

	auto &semantics = ci.semantics();
	auto tables{Fortran::semantics::BuildRuntimeDerivedTypeTables(
	instance().invocation().semanticsContext())};
	// The runtime derived type information table builder may find and report
	// semantic errors. So it is important that we report them _after_
	// BuildRuntimeDerivedTypeTables is run.
	reportFatalSemanticErrors();

	if (!tables.schemata) {
	unsigned DiagID =
	ci.diagnostics().getCustomDiagID(clang::DiagnosticsEngine::Error,
	"could not find module file for __fortran_type_info");
	ci.diagnostics().Report(DiagID);
	llvm::errs() << "\n";
	}

	// Dump symbols
	llvm::outs() << "=====================";
	llvm::outs() << " Flang: symbols dump ";
	llvm::outs() << "=====================\n";
	semantics.DumpSymbols(llvm::outs());
	}

	void DebugDumpParseTreeNoSemaAction::ExecuteAction() {
	auto &parseTree{instance().parsing().parseTree()};

	// Dump parse tree
	Fortran::parser::DumpTree(
	llvm::outs(), parseTree, &this->instance().invocation().asFortran());
	}

	void DebugDumpParseTreeAction::ExecuteAction() {
	auto &parseTree{instance().parsing().parseTree()};

	// Dump parse tree
	Fortran::parser::DumpTree(
	llvm::outs(), parseTree, &this->instance().invocation().asFortran());

	// Report fatal semantic errors
	reportFatalSemanticErrors();
	}

	void DebugMeasureParseTreeAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();

	// Parse. In case of failure, report and return.
	ci.parsing().Parse(llvm::outs());

	if (!ci.parsing().messages().empty() &&
	(ci.invocation().warnAsErr() \|\|
	ci.parsing().messages().AnyFatalError())) {
	unsigned diagID = ci.diagnostics().getCustomDiagID(
	clang::DiagnosticsEngine::Error, "Could not parse %0");
	ci.diagnostics().Report(diagID) << GetCurrentFileOrBufferName();

	ci.parsing().messages().Emit(
	llvm::errs(), this->instance().allCookedSources());
	return;
	}

	// Report the diagnostics from parsing
	ci.parsing().messages().Emit(llvm::errs(), ci.allCookedSources());

	auto &parseTree{*ci.parsing().parseTree()};

	// Measure the parse tree
	MeasurementVisitor visitor;
	Fortran::parser::Walk(parseTree, visitor);
	llvm::outs() << "Parse tree comprises " << visitor.objects
	<< " objects and occupies " << visitor.bytes
	<< " total bytes.\n";
	}

	void DebugPreFIRTreeAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();
	// Report and exit if fatal semantic errors are present
	if (reportFatalSemanticErrors()) {
	return;
	}

	auto &parseTree{*ci.parsing().parseTree()};

	// Dump pre-FIR tree
	if (auto ast{Fortran::lower::createPFT(
	parseTree, ci.invocation().semanticsContext())}) {
	Fortran::lower::dumpPFT(llvm::outs(), *ast);
	} else {
	unsigned diagID = ci.diagnostics().getCustomDiagID(
	clang::DiagnosticsEngine::Error, "Pre FIR Tree is NULL.");
	ci.diagnostics().Report(diagID);
	}
	}

	void DebugDumpParsingLogAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();

	ci.parsing().Parse(llvm::errs());
	ci.parsing().DumpParsingLog(llvm::outs());
	}

	void GetDefinitionAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();

	// Report and exit if fatal semantic errors are present
	if (reportFatalSemanticErrors()) {
	return;
	}

	parser::AllCookedSources &cs = ci.allCookedSources();
	unsigned diagID = ci.diagnostics().getCustomDiagID(
	clang::DiagnosticsEngine::Error, "Symbol not found");

	auto gdv = ci.invocation().frontendOpts().getDefVals;
	auto charBlock{cs.GetCharBlockFromLineAndColumns(
	gdv.line, gdv.startColumn, gdv.endColumn)};
	if (!charBlock) {
	ci.diagnostics().Report(diagID);
	return;
	}

	llvm::outs() << "String range: >" << charBlock->ToString() << "<\n";

	auto *symbol{ci.invocation()
	.semanticsContext()
	.FindScope(*charBlock)
	.FindSymbol(*charBlock)};
	if (!symbol) {
	ci.diagnostics().Report(diagID);
	return;
	}

	llvm::outs() << "Found symbol name: " << symbol->name().ToString() << "\n";

	auto sourceInfo{cs.GetSourcePositionRange(symbol->name())};
	if (!sourceInfo) {
	llvm_unreachable(
	"Failed to obtain SourcePosition."
	"TODO: Please, write a test and replace this with a diagnostic!");
	return;
	}

	llvm::outs() << "Found symbol name: " << symbol->name().ToString() << "\n";
	llvm::outs() << symbol->name().ToString() << ": "
	<< sourceInfo->first.file.path() << ", "
	<< sourceInfo->first.line << ", " << sourceInfo->first.column
	<< "-" << sourceInfo->second.column << "\n";
	}

	void GetSymbolsSourcesAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();

	// Report and exit if fatal semantic errors are present
	if (reportFatalSemanticErrors()) {
	return;
	}

	ci.semantics().DumpSymbolsSources(llvm::outs());
	}

	void EmitObjAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();
	unsigned DiagID = ci.diagnostics().getCustomDiagID(
	clang::DiagnosticsEngine::Error, "code-generation is not available yet");
	ci.diagnostics().Report(DiagID);
	}

	void InitOnlyAction::ExecuteAction() {
	CompilerInstance &ci = this->instance();
	unsigned DiagID =
	ci.diagnostics().getCustomDiagID(clang::DiagnosticsEngine::Warning,
	"Use `-init-only` for testing purposes only");
	ci.diagnostics().Report(DiagID);
	}

	void PluginParseTreeAction::ExecuteAction() {}