llvm-project/clang-tools-extra/clangd/TUScheduler.cpp

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//===--- TUScheduler.cpp -----------------------------------------*-C++-*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
// For each file, managed by TUScheduler, we create a single ASTWorker that
// manages an AST for that file. All operations that modify or read the AST are
// run on a separate dedicated thread asynchronously in FIFO order.
//
// We start processing each update immediately after we receive it. If two or
// more updates come subsequently without reads in-between, we attempt to drop
// an older one to not waste time building the ASTs we don't need.
//
// The processing thread of the ASTWorker is also responsible for building the
// preamble. However, unlike AST, the same preamble can be read concurrently, so
// we run each of async preamble reads on its own thread.
//
// To limit the concurrent load that clangd produces we maintain a semaphore
// that keeps more than a fixed number of threads from running concurrently.
//
// Rationale for cancelling updates.
// LSP clients can send updates to clangd on each keystroke. Some files take
// significant time to parse (e.g. a few seconds) and clangd can get starved by
// the updates to those files. Therefore we try to process only the last update,
// if possible.
// Our current strategy to do that is the following:
// - For each update we immediately schedule rebuild of the AST.
// - Rebuild of the AST checks if it was cancelled before doing any actual work.
// If it was, it does not do an actual rebuild, only reports llvm::None to the
// callback
// - When adding an update, we cancel the last update in the queue if it didn't
// have any reads.
// There is probably a optimal ways to do that. One approach we might take is
// the following:
// - For each update we remember the pending inputs, but delay rebuild of the
// AST for some timeout.
// - If subsequent updates come before rebuild was started, we replace the
// pending inputs and reset the timer.
// - If any reads of the AST are scheduled, we start building the AST
// immediately.
#include "TUScheduler.h"
#include "Cancellation.h"
#include "Compiler.h"
#include "Context.h"
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
#include "Diagnostics.h"
#include "GlobalCompilationDatabase.h"
#include "Logger.h"
#include "ParsedAST.h"
#include "Preamble.h"
#include "Trace.h"
#include "index/CanonicalIncludes.h"
#include "clang/Frontend/CompilerInvocation.h"
#include "clang/Tooling/CompilationDatabase.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/ScopeExit.h"
#include "llvm/Support/Errc.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/Threading.h"
#include <algorithm>
#include <memory>
#include <queue>
#include <thread>
namespace clang {
namespace clangd {
using std::chrono::steady_clock;
namespace {
class ASTWorker;
} // namespace
static clang::clangd::Key<std::string> kFileBeingProcessed;
llvm::Optional<llvm::StringRef> TUScheduler::getFileBeingProcessedInContext() {
if (auto *File = Context::current().get(kFileBeingProcessed))
return llvm::StringRef(*File);
return None;
}
/// An LRU cache of idle ASTs.
/// Because we want to limit the overall number of these we retain, the cache
/// owns ASTs (and may evict them) while their workers are idle.
/// Workers borrow ASTs when active, and return them when done.
class TUScheduler::ASTCache {
public:
using Key = const ASTWorker *;
ASTCache(unsigned MaxRetainedASTs) : MaxRetainedASTs(MaxRetainedASTs) {}
/// Returns result of getUsedBytes() for the AST cached by \p K.
/// If no AST is cached, 0 is returned.
std::size_t getUsedBytes(Key K) {
std::lock_guard<std::mutex> Lock(Mut);
auto It = findByKey(K);
if (It == LRU.end() || !It->second)
return 0;
return It->second->getUsedBytes();
}
/// Store the value in the pool, possibly removing the last used AST.
/// The value should not be in the pool when this function is called.
void put(Key K, std::unique_ptr<ParsedAST> V) {
std::unique_lock<std::mutex> Lock(Mut);
assert(findByKey(K) == LRU.end());
LRU.insert(LRU.begin(), {K, std::move(V)});
if (LRU.size() <= MaxRetainedASTs)
return;
// We're past the limit, remove the last element.
std::unique_ptr<ParsedAST> ForCleanup = std::move(LRU.back().second);
LRU.pop_back();
// Run the expensive destructor outside the lock.
Lock.unlock();
ForCleanup.reset();
}
/// Returns the cached value for \p K, or llvm::None if the value is not in
/// the cache anymore. If nullptr was cached for \p K, this function will
/// return a null unique_ptr wrapped into an optional.
llvm::Optional<std::unique_ptr<ParsedAST>> take(Key K) {
std::unique_lock<std::mutex> Lock(Mut);
auto Existing = findByKey(K);
if (Existing == LRU.end())
return None;
std::unique_ptr<ParsedAST> V = std::move(Existing->second);
LRU.erase(Existing);
// GCC 4.8 fails to compile `return V;`, as it tries to call the copy
// constructor of unique_ptr, so we call the move ctor explicitly to avoid
// this miscompile.
return llvm::Optional<std::unique_ptr<ParsedAST>>(std::move(V));
}
private:
using KVPair = std::pair<Key, std::unique_ptr<ParsedAST>>;
std::vector<KVPair>::iterator findByKey(Key K) {
return llvm::find_if(LRU, [K](const KVPair &P) { return P.first == K; });
}
std::mutex Mut;
unsigned MaxRetainedASTs;
/// Items sorted in LRU order, i.e. first item is the most recently accessed
/// one.
std::vector<KVPair> LRU; /* GUARDED_BY(Mut) */
};
namespace {
class ASTWorkerHandle;
/// Owns one instance of the AST, schedules updates and reads of it.
/// Also responsible for building and providing access to the preamble.
/// Each ASTWorker processes the async requests sent to it on a separate
/// dedicated thread.
/// The ASTWorker that manages the AST is shared by both the processing thread
/// and the TUScheduler. The TUScheduler should discard an ASTWorker when
/// remove() is called, but its thread may be busy and we don't want to block.
/// So the workers are accessed via an ASTWorkerHandle. Destroying the handle
/// signals the worker to exit its run loop and gives up shared ownership of the
/// worker.
class ASTWorker {
friend class ASTWorkerHandle;
ASTWorker(PathRef FileName, const GlobalCompilationDatabase &CDB,
TUScheduler::ASTCache &LRUCache, Semaphore &Barrier, bool RunSync,
steady_clock::duration UpdateDebounce, bool StorePreamblesInMemory,
ParsingCallbacks &Callbacks);
public:
/// Create a new ASTWorker and return a handle to it.
/// The processing thread is spawned using \p Tasks. However, when \p Tasks
/// is null, all requests will be processed on the calling thread
/// synchronously instead. \p Barrier is acquired when processing each
/// request, it is used to limit the number of actively running threads.
static ASTWorkerHandle
create(PathRef FileName, const GlobalCompilationDatabase &CDB,
TUScheduler::ASTCache &IdleASTs, AsyncTaskRunner *Tasks,
Semaphore &Barrier, steady_clock::duration UpdateDebounce,
bool StorePreamblesInMemory, ParsingCallbacks &Callbacks);
~ASTWorker();
void update(ParseInputs Inputs, WantDiagnostics);
void
runWithAST(llvm::StringRef Name,
llvm::unique_function<void(llvm::Expected<InputsAndAST>)> Action);
bool blockUntilIdle(Deadline Timeout) const;
std::shared_ptr<const PreambleData> getPossiblyStalePreamble() const;
/// Obtain a preamble reflecting all updates so far. Threadsafe.
/// It may be delivered immediately, or later on the worker thread.
void getCurrentPreamble(
llvm::unique_function<void(std::shared_ptr<const PreambleData>)>);
/// Returns compile command from the current file inputs.
tooling::CompileCommand getCurrentCompileCommand() const;
/// Wait for the first build of preamble to finish. Preamble itself can be
/// accessed via getPossiblyStalePreamble(). Note that this function will
/// return after an unsuccessful build of the preamble too, i.e. result of
/// getPossiblyStalePreamble() can be null even after this function returns.
void waitForFirstPreamble() const;
std::size_t getUsedBytes() const;
bool isASTCached() const;
private:
// Must be called exactly once on processing thread. Will return after
// stop() is called on a separate thread and all pending requests are
// processed.
void run();
/// Signal that run() should finish processing pending requests and exit.
void stop();
/// Adds a new task to the end of the request queue.
void startTask(llvm::StringRef Name, llvm::unique_function<void()> Task,
llvm::Optional<WantDiagnostics> UpdateType);
/// Updates the TUStatus and emits it. Only called in the worker thread.
void emitTUStatus(TUAction FAction,
const TUStatus::BuildDetails *Detail = nullptr);
/// Determines the next action to perform.
/// All actions that should never run are discarded.
/// Returns a deadline for the next action. If it's expired, run now.
/// scheduleLocked() is called again at the deadline, or if requests arrive.
Deadline scheduleLocked();
/// Should the first task in the queue be skipped instead of run?
bool shouldSkipHeadLocked() const;
/// This is private because `FileInputs.FS` is not thread-safe and thus not
/// safe to share. Callers should make sure not to expose `FS` via a public
/// interface.
std::shared_ptr<const ParseInputs> getCurrentFileInputs() const;
struct Request {
llvm::unique_function<void()> Action;
std::string Name;
steady_clock::time_point AddTime;
Context Ctx;
llvm::Optional<WantDiagnostics> UpdateType;
};
/// Handles retention of ASTs.
TUScheduler::ASTCache &IdleASTs;
const bool RunSync;
/// Time to wait after an update to see whether another update obsoletes it.
const steady_clock::duration UpdateDebounce;
/// File that ASTWorker is responsible for.
const Path FileName;
const GlobalCompilationDatabase &CDB;
/// Whether to keep the built preambles in memory or on disk.
const bool StorePreambleInMemory;
/// Callback invoked when preamble or main file AST is built.
ParsingCallbacks &Callbacks;
/// Only accessed by the worker thread.
TUStatus Status;
Semaphore &Barrier;
/// Whether the 'onMainAST' callback ran for the current FileInputs.
bool RanASTCallback = false;
/// Guards members used by both TUScheduler and the worker thread.
mutable std::mutex Mutex;
/// File inputs, currently being used by the worker.
/// Inputs are written and read by the worker thread, compile command can also
/// be consumed by clients of ASTWorker.
std::shared_ptr<const ParseInputs> FileInputs; /* GUARDED_BY(Mutex) */
std::shared_ptr<const PreambleData> LastBuiltPreamble; /* GUARDED_BY(Mutex) */
/// Becomes ready when the first preamble build finishes.
Notification PreambleWasBuilt;
/// Set to true to signal run() to finish processing.
bool Done; /* GUARDED_BY(Mutex) */
std::deque<Request> Requests; /* GUARDED_BY(Mutex) */
mutable std::condition_variable RequestsCV;
/// Guards the callback that publishes results of AST-related computations
/// (diagnostics, highlightings) and file statuses.
std::mutex PublishMu;
// Used to prevent remove document + add document races that lead to
// out-of-order callbacks for publishing results of onMainAST callback.
//
// The lifetime of the old/new ASTWorkers will overlap, but their handles
// don't. When the old handle is destroyed, the old worker will stop reporting
// any results to the user.
bool CanPublishResults = true; /* GUARDED_BY(PublishMu) */
};
/// A smart-pointer-like class that points to an active ASTWorker.
/// In destructor, signals to the underlying ASTWorker that no new requests will
/// be sent and the processing loop may exit (after running all pending
/// requests).
class ASTWorkerHandle {
friend class ASTWorker;
ASTWorkerHandle(std::shared_ptr<ASTWorker> Worker)
: Worker(std::move(Worker)) {
assert(this->Worker);
}
public:
ASTWorkerHandle(const ASTWorkerHandle &) = delete;
ASTWorkerHandle &operator=(const ASTWorkerHandle &) = delete;
ASTWorkerHandle(ASTWorkerHandle &&) = default;
ASTWorkerHandle &operator=(ASTWorkerHandle &&) = default;
~ASTWorkerHandle() {
if (Worker)
Worker->stop();
}
ASTWorker &operator*() {
assert(Worker && "Handle was moved from");
return *Worker;
}
ASTWorker *operator->() {
assert(Worker && "Handle was moved from");
return Worker.get();
}
/// Returns an owning reference to the underlying ASTWorker that can outlive
/// the ASTWorkerHandle. However, no new requests to an active ASTWorker can
/// be schedule via the returned reference, i.e. only reads of the preamble
/// are possible.
std::shared_ptr<const ASTWorker> lock() { return Worker; }
private:
std::shared_ptr<ASTWorker> Worker;
};
ASTWorkerHandle
ASTWorker::create(PathRef FileName, const GlobalCompilationDatabase &CDB,
TUScheduler::ASTCache &IdleASTs, AsyncTaskRunner *Tasks,
Semaphore &Barrier, steady_clock::duration UpdateDebounce,
bool StorePreamblesInMemory, ParsingCallbacks &Callbacks) {
std::shared_ptr<ASTWorker> Worker(
new ASTWorker(FileName, CDB, IdleASTs, Barrier, /*RunSync=*/!Tasks,
UpdateDebounce, StorePreamblesInMemory, Callbacks));
if (Tasks)
Tasks->runAsync("worker:" + llvm::sys::path::filename(FileName),
[Worker]() { Worker->run(); });
return ASTWorkerHandle(std::move(Worker));
}
ASTWorker::ASTWorker(PathRef FileName, const GlobalCompilationDatabase &CDB,
TUScheduler::ASTCache &LRUCache, Semaphore &Barrier,
bool RunSync, steady_clock::duration UpdateDebounce,
bool StorePreamblesInMemory, ParsingCallbacks &Callbacks)
: IdleASTs(LRUCache), RunSync(RunSync), UpdateDebounce(UpdateDebounce),
FileName(FileName), CDB(CDB),
StorePreambleInMemory(StorePreamblesInMemory),
Callbacks(Callbacks), Status{TUAction(TUAction::Idle, ""),
TUStatus::BuildDetails()},
Barrier(Barrier), Done(false) {
auto Inputs = std::make_shared<ParseInputs>();
// Set a fallback command because compile command can be accessed before
// `Inputs` is initialized. Other fields are only used after initialization
// from client inputs.
Inputs->CompileCommand = CDB.getFallbackCommand(FileName);
FileInputs = std::move(Inputs);
}
ASTWorker::~ASTWorker() {
// Make sure we remove the cached AST, if any.
IdleASTs.take(this);
#ifndef NDEBUG
std::lock_guard<std::mutex> Lock(Mutex);
assert(Done && "handle was not destroyed");
assert(Requests.empty() && "unprocessed requests when destroying ASTWorker");
#endif
}
void ASTWorker::update(ParseInputs Inputs, WantDiagnostics WantDiags) {
llvm::StringRef TaskName = "Update";
auto Task = [=]() mutable {
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
auto RunPublish = [&](llvm::function_ref<void()> Publish) {
// Ensure we only publish results from the worker if the file was not
// removed, making sure there are not race conditions.
std::lock_guard<std::mutex> Lock(PublishMu);
if (CanPublishResults)
Publish();
};
// Get the actual command as `Inputs` does not have a command.
// FIXME: some build systems like Bazel will take time to preparing
// environment to build the file, it would be nice if we could emit a
// "PreparingBuild" status to inform users, it is non-trivial given the
// current implementation.
if (auto Cmd = CDB.getCompileCommand(FileName))
Inputs.CompileCommand = *Cmd;
else
// FIXME: consider using old command if it's not a fallback one.
Inputs.CompileCommand = CDB.getFallbackCommand(FileName);
auto PrevInputs = getCurrentFileInputs();
// Will be used to check if we can avoid rebuilding the AST.
bool InputsAreTheSame =
std::tie(PrevInputs->CompileCommand, PrevInputs->Contents) ==
std::tie(Inputs.CompileCommand, Inputs.Contents);
tooling::CompileCommand OldCommand = PrevInputs->CompileCommand;
bool RanCallbackForPrevInputs = RanASTCallback;
{
std::lock_guard<std::mutex> Lock(Mutex);
FileInputs = std::make_shared<ParseInputs>(Inputs);
}
RanASTCallback = false;
emitTUStatus({TUAction::BuildingPreamble, TaskName});
log("Updating file {0} with command {1}\n[{2}]\n{3}", FileName,
Inputs.CompileCommand.Heuristic,
Inputs.CompileCommand.Directory,
llvm::join(Inputs.CompileCommand.CommandLine, " "));
// Rebuild the preamble and the AST.
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
StoreDiags CompilerInvocationDiagConsumer;
std::vector<std::string> CC1Args;
std::unique_ptr<CompilerInvocation> Invocation = buildCompilerInvocation(
Inputs, CompilerInvocationDiagConsumer, &CC1Args);
// Log cc1 args even (especially!) if creating invocation failed.
if (!CC1Args.empty())
vlog("Driver produced command: cc1 {0}", llvm::join(CC1Args, " "));
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
std::vector<Diag> CompilerInvocationDiags =
CompilerInvocationDiagConsumer.take();
if (!Invocation) {
elog("Could not build CompilerInvocation for file {0}", FileName);
// Remove the old AST if it's still in cache.
IdleASTs.take(this);
TUStatus::BuildDetails Details;
Details.BuildFailed = true;
emitTUStatus({TUAction::BuildingPreamble, TaskName}, &Details);
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
// Report the diagnostics we collected when parsing the command line.
Callbacks.onFailedAST(FileName, std::move(CompilerInvocationDiags),
RunPublish);
// Make sure anyone waiting for the preamble gets notified it could not
// be built.
PreambleWasBuilt.notify();
return;
}
std::shared_ptr<const PreambleData> OldPreamble =
getPossiblyStalePreamble();
std::shared_ptr<const PreambleData> NewPreamble = buildPreamble(
FileName, *Invocation, OldPreamble, OldCommand, Inputs,
StorePreambleInMemory,
[this](ASTContext &Ctx, std::shared_ptr<clang::Preprocessor> PP,
const CanonicalIncludes &CanonIncludes) {
Callbacks.onPreambleAST(FileName, Ctx, std::move(PP), CanonIncludes);
});
bool CanReuseAST = InputsAreTheSame && (OldPreamble == NewPreamble);
{
std::lock_guard<std::mutex> Lock(Mutex);
LastBuiltPreamble = NewPreamble;
}
// Before doing the expensive AST reparse, we want to release our reference
// to the old preamble, so it can be freed if there are no other references
// to it.
OldPreamble.reset();
PreambleWasBuilt.notify();
emitTUStatus({TUAction::BuildingFile, TaskName});
if (!CanReuseAST) {
IdleASTs.take(this); // Remove the old AST if it's still in cache.
} else {
// We don't need to rebuild the AST, check if we need to run the callback.
if (RanCallbackForPrevInputs) {
RanASTCallback = true;
// Take a shortcut and don't report the diagnostics, since they should
// not changed. All the clients should handle the lack of OnUpdated()
// call anyway to handle empty result from buildAST.
// FIXME(ibiryukov): the AST could actually change if non-preamble
// includes changed, but we choose to ignore it.
// FIXME(ibiryukov): should we refresh the cache in IdleASTs for the
// current file at this point?
log("Skipping rebuild of the AST for {0}, inputs are the same.",
FileName);
TUStatus::BuildDetails Details;
Details.ReuseAST = true;
emitTUStatus({TUAction::BuildingFile, TaskName}, &Details);
return;
}
}
// We only need to build the AST if diagnostics were requested.
if (WantDiags == WantDiagnostics::No)
return;
{
std::lock_guard<std::mutex> Lock(PublishMu);
// No need to rebuild the AST if we won't send the diagnostics. However,
// note that we don't prevent preamble rebuilds.
if (!CanPublishResults)
return;
}
// Get the AST for diagnostics.
llvm::Optional<std::unique_ptr<ParsedAST>> AST = IdleASTs.take(this);
if (!AST) {
llvm::Optional<ParsedAST> NewAST =
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
buildAST(FileName, std::move(Invocation), CompilerInvocationDiags,
Inputs, NewPreamble);
AST = NewAST ? std::make_unique<ParsedAST>(std::move(*NewAST)) : nullptr;
if (!(*AST)) { // buildAST fails.
TUStatus::BuildDetails Details;
Details.BuildFailed = true;
emitTUStatus({TUAction::BuildingFile, TaskName}, &Details);
}
} else {
// We are reusing the AST.
TUStatus::BuildDetails Details;
Details.ReuseAST = true;
emitTUStatus({TUAction::BuildingFile, TaskName}, &Details);
}
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
// We want to report the diagnostics even if this update was cancelled.
// It seems more useful than making the clients wait indefinitely if they
// spam us with updates.
// Note *AST can still be null if buildAST fails.
if (*AST) {
trace::Span Span("Running main AST callback");
Callbacks.onMainAST(FileName, **AST, RunPublish);
RanASTCallback = true;
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
} else {
// Failed to build the AST, at least report diagnostics from the command
// line if there were any.
// FIXME: we might have got more errors while trying to build the AST,
// surface them too.
Callbacks.onFailedAST(FileName, CompilerInvocationDiags, RunPublish);
}
// Stash the AST in the cache for further use.
IdleASTs.put(this, std::move(*AST));
};
startTask(TaskName, std::move(Task), WantDiags);
}
void ASTWorker::runWithAST(
llvm::StringRef Name,
llvm::unique_function<void(llvm::Expected<InputsAndAST>)> Action) {
auto Task = [=, Action = std::move(Action)]() mutable {
if (isCancelled())
return Action(llvm::make_error<CancelledError>());
llvm::Optional<std::unique_ptr<ParsedAST>> AST = IdleASTs.take(this);
auto CurrentInputs = getCurrentFileInputs();
if (!AST) {
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
StoreDiags CompilerInvocationDiagConsumer;
std::unique_ptr<CompilerInvocation> Invocation = buildCompilerInvocation(
*CurrentInputs, CompilerInvocationDiagConsumer);
// Try rebuilding the AST.
llvm::Optional<ParsedAST> NewAST =
Invocation
? buildAST(FileName,
std::make_unique<CompilerInvocation>(*Invocation),
[clangd] Surface errors from command-line parsing Summary: Those errors are exposed at the first character of a file, for a lack of a better place. Previously, all errors were stored inside the AST and report accordingly. However, errors in command-line argument parsing could result in failure to produce the AST, so we need an alternative ways to report those errors. We take the following approach in this patch: - buildCompilerInvocation() now requires an explicit DiagnosticConsumer. - TUScheduler and TestTU now collect the diagnostics produced when parsing command line arguments. If pasing of the AST failed, diagnostics are reported via a new ParsingCallbacks::onFailedAST method. If parsing of the AST succeeded, any errors produced during command-line parsing are stored alongside the AST inside the ParsedAST instance and reported as previously by calling the ParsingCallbacks::onMainAST method; - The client code that uses ClangdServer's DiagnosticConsumer does not need to change, it will receive new diagnostics in the onDiagnosticsReady() callback Errors produced when parsing command-line arguments are collected using the same StoreDiags class that is used to collect all other errors. They are recognized by their location being invalid. IIUC, the location is invalid as there is no source manager at this point, it is created at a later stage. Although technically we might also get diagnostics that mention the command-line arguments FileID with after the source manager was created (and they have valid source locations), we choose to not handle those and they are dropped as not coming from the main file. AFAICT, those diagnostics should always be notes, therefore it's safe to drop them without loosing too much information. Reviewers: kadircet Reviewed By: kadircet Subscribers: nridge, javed.absar, MaskRay, jkorous, arphaman, cfe-commits, gribozavr Tags: #clang Differential Revision: https://reviews.llvm.org/D66759 llvm-svn: 370177
2019-08-28 17:24:55 +08:00
CompilerInvocationDiagConsumer.take(), *CurrentInputs,
getPossiblyStalePreamble())
: None;
AST = NewAST ? std::make_unique<ParsedAST>(std::move(*NewAST)) : nullptr;
}
// Make sure we put the AST back into the LRU cache.
auto _ = llvm::make_scope_exit(
[&AST, this]() { IdleASTs.put(this, std::move(*AST)); });
// Run the user-provided action.
if (!*AST)
return Action(llvm::make_error<llvm::StringError>(
"invalid AST", llvm::errc::invalid_argument));
Action(InputsAndAST{*CurrentInputs, **AST});
};
startTask(Name, std::move(Task), /*UpdateType=*/None);
}
std::shared_ptr<const PreambleData>
ASTWorker::getPossiblyStalePreamble() const {
std::lock_guard<std::mutex> Lock(Mutex);
return LastBuiltPreamble;
}
void ASTWorker::getCurrentPreamble(
llvm::unique_function<void(std::shared_ptr<const PreambleData>)> Callback) {
// We could just call startTask() to throw the read on the queue, knowing
// it will run after any updates. But we know this task is cheap, so to
// improve latency we cheat: insert it on the queue after the last update.
std::unique_lock<std::mutex> Lock(Mutex);
auto LastUpdate =
std::find_if(Requests.rbegin(), Requests.rend(),
[](const Request &R) { return R.UpdateType.hasValue(); });
// If there were no writes in the queue, the preamble is ready now.
if (LastUpdate == Requests.rend()) {
Lock.unlock();
return Callback(getPossiblyStalePreamble());
}
assert(!RunSync && "Running synchronously, but queue is non-empty!");
Requests.insert(LastUpdate.base(),
Request{[Callback = std::move(Callback), this]() mutable {
Callback(getPossiblyStalePreamble());
},
"GetPreamble", steady_clock::now(),
Context::current().clone(),
/*UpdateType=*/None});
Lock.unlock();
RequestsCV.notify_all();
}
void ASTWorker::waitForFirstPreamble() const { PreambleWasBuilt.wait(); }
std::shared_ptr<const ParseInputs> ASTWorker::getCurrentFileInputs() const {
std::unique_lock<std::mutex> Lock(Mutex);
return FileInputs;
}
tooling::CompileCommand ASTWorker::getCurrentCompileCommand() const {
std::unique_lock<std::mutex> Lock(Mutex);
return FileInputs->CompileCommand;
}
std::size_t ASTWorker::getUsedBytes() const {
// Note that we don't report the size of ASTs currently used for processing
// the in-flight requests. We used this information for debugging purposes
// only, so this should be fine.
std::size_t Result = IdleASTs.getUsedBytes(this);
if (auto Preamble = getPossiblyStalePreamble())
Result += Preamble->Preamble.getSize();
return Result;
}
bool ASTWorker::isASTCached() const { return IdleASTs.getUsedBytes(this) != 0; }
void ASTWorker::stop() {
{
std::lock_guard<std::mutex> Lock(PublishMu);
CanPublishResults = false;
}
{
std::lock_guard<std::mutex> Lock(Mutex);
assert(!Done && "stop() called twice");
Done = true;
}
RequestsCV.notify_all();
}
void ASTWorker::startTask(llvm::StringRef Name,
llvm::unique_function<void()> Task,
llvm::Optional<WantDiagnostics> UpdateType) {
if (RunSync) {
assert(!Done && "running a task after stop()");
trace::Span Tracer(Name + ":" + llvm::sys::path::filename(FileName));
Task();
return;
}
{
std::lock_guard<std::mutex> Lock(Mutex);
assert(!Done && "running a task after stop()");
Requests.push_back(
{std::move(Task), std::string(Name), steady_clock::now(),
Context::current().derive(kFileBeingProcessed, FileName), UpdateType});
}
RequestsCV.notify_all();
}
void ASTWorker::emitTUStatus(TUAction Action,
const TUStatus::BuildDetails *Details) {
Status.Action = std::move(Action);
if (Details)
Status.Details = *Details;
std::lock_guard<std::mutex> Lock(PublishMu);
// Do not emit TU statuses when the ASTWorker is shutting down.
if (CanPublishResults) {
Callbacks.onFileUpdated(FileName, Status);
}
}
void ASTWorker::run() {
while (true) {
Request Req;
{
std::unique_lock<std::mutex> Lock(Mutex);
for (auto Wait = scheduleLocked(); !Wait.expired();
Wait = scheduleLocked()) {
if (Done) {
if (Requests.empty())
return;
else // Even though Done is set, finish pending requests.
break; // However, skip delays to shutdown fast.
}
// Tracing: we have a next request, attribute this sleep to it.
llvm::Optional<WithContext> Ctx;
llvm::Optional<trace::Span> Tracer;
if (!Requests.empty()) {
Ctx.emplace(Requests.front().Ctx.clone());
Tracer.emplace("Debounce");
SPAN_ATTACH(*Tracer, "next_request", Requests.front().Name);
if (!(Wait == Deadline::infinity())) {
emitTUStatus({TUAction::Queued, Req.Name});
SPAN_ATTACH(*Tracer, "sleep_ms",
std::chrono::duration_cast<std::chrono::milliseconds>(
Wait.time() - steady_clock::now())
.count());
}
}
wait(Lock, RequestsCV, Wait);
}
Req = std::move(Requests.front());
// Leave it on the queue for now, so waiters don't see an empty queue.
} // unlock Mutex
{
std::unique_lock<Semaphore> Lock(Barrier, std::try_to_lock);
if (!Lock.owns_lock()) {
emitTUStatus({TUAction::Queued, Req.Name});
Lock.lock();
}
WithContext Guard(std::move(Req.Ctx));
trace::Span Tracer(Req.Name);
emitTUStatus({TUAction::RunningAction, Req.Name});
Req.Action();
}
bool IsEmpty = false;
{
std::lock_guard<std::mutex> Lock(Mutex);
Requests.pop_front();
IsEmpty = Requests.empty();
}
if (IsEmpty)
emitTUStatus({TUAction::Idle, /*Name*/ ""});
RequestsCV.notify_all();
}
}
Deadline ASTWorker::scheduleLocked() {
if (Requests.empty())
return Deadline::infinity(); // Wait for new requests.
// Handle cancelled requests first so the rest of the scheduler doesn't.
for (auto I = Requests.begin(), E = Requests.end(); I != E; ++I) {
if (!isCancelled(I->Ctx)) {
// Cancellations after the first read don't affect current scheduling.
if (I->UpdateType == None)
break;
continue;
}
// Cancelled reads are moved to the front of the queue and run immediately.
if (I->UpdateType == None) {
Request R = std::move(*I);
Requests.erase(I);
Requests.push_front(std::move(R));
return Deadline::zero();
}
// Cancelled updates are downgraded to auto-diagnostics, and may be elided.
if (I->UpdateType == WantDiagnostics::Yes)
I->UpdateType = WantDiagnostics::Auto;
}
while (shouldSkipHeadLocked())
Requests.pop_front();
assert(!Requests.empty() && "skipped the whole queue");
// Some updates aren't dead yet, but never end up being used.
// e.g. the first keystroke is live until obsoleted by the second.
// We debounce "maybe-unused" writes, sleeping 500ms in case they become dead.
// But don't delay reads (including updates where diagnostics are needed).
for (const auto &R : Requests)
if (R.UpdateType == None || R.UpdateType == WantDiagnostics::Yes)
return Deadline::zero();
// Front request needs to be debounced, so determine when we're ready.
Deadline D(Requests.front().AddTime + UpdateDebounce);
return D;
}
// Returns true if Requests.front() is a dead update that can be skipped.
bool ASTWorker::shouldSkipHeadLocked() const {
assert(!Requests.empty());
auto Next = Requests.begin();
auto UpdateType = Next->UpdateType;
if (!UpdateType) // Only skip updates.
return false;
++Next;
// An update is live if its AST might still be read.
// That is, if it's not immediately followed by another update.
if (Next == Requests.end() || !Next->UpdateType)
return false;
// The other way an update can be live is if its diagnostics might be used.
switch (*UpdateType) {
case WantDiagnostics::Yes:
return false; // Always used.
case WantDiagnostics::No:
return true; // Always dead.
case WantDiagnostics::Auto:
// Used unless followed by an update that generates diagnostics.
for (; Next != Requests.end(); ++Next)
if (Next->UpdateType == WantDiagnostics::Yes ||
Next->UpdateType == WantDiagnostics::Auto)
return true; // Prefer later diagnostics.
return false;
}
llvm_unreachable("Unknown WantDiagnostics");
}
bool ASTWorker::blockUntilIdle(Deadline Timeout) const {
std::unique_lock<std::mutex> Lock(Mutex);
return wait(Lock, RequestsCV, Timeout, [&] { return Requests.empty(); });
}
// Render a TUAction to a user-facing string representation.
// TUAction represents clangd-internal states, we don't intend to expose them
// to users (say C++ programmers) directly to avoid confusion, we use terms that
// are familiar by C++ programmers.
std::string renderTUAction(const TUAction &Action) {
std::string Result;
llvm::raw_string_ostream OS(Result);
switch (Action.S) {
case TUAction::Queued:
OS << "file is queued";
break;
case TUAction::RunningAction:
OS << "running " << Action.Name;
break;
case TUAction::BuildingPreamble:
OS << "parsing includes";
break;
case TUAction::BuildingFile:
OS << "parsing main file";
break;
case TUAction::Idle:
OS << "idle";
break;
}
return OS.str();
}
} // namespace
unsigned getDefaultAsyncThreadsCount() {
unsigned HardwareConcurrency = llvm::heavyweight_hardware_concurrency();
// heavyweight_hardware_concurrency may fall back to hardware_concurrency.
// C++ standard says that hardware_concurrency() may return 0; fallback to 1
// worker thread in that case.
if (HardwareConcurrency == 0)
return 1;
return HardwareConcurrency;
}
FileStatus TUStatus::render(PathRef File) const {
FileStatus FStatus;
FStatus.uri = URIForFile::canonicalize(File, /*TUPath=*/File);
FStatus.state = renderTUAction(Action);
return FStatus;
}
struct TUScheduler::FileData {
/// Latest inputs, passed to TUScheduler::update().
std::string Contents;
ASTWorkerHandle Worker;
};
TUScheduler::TUScheduler(const GlobalCompilationDatabase &CDB,
const Options &Opts,
std::unique_ptr<ParsingCallbacks> Callbacks)
: CDB(CDB), StorePreamblesInMemory(Opts.StorePreamblesInMemory),
Callbacks(Callbacks ? move(Callbacks)
: std::make_unique<ParsingCallbacks>()),
Barrier(Opts.AsyncThreadsCount),
IdleASTs(
std::make_unique<ASTCache>(Opts.RetentionPolicy.MaxRetainedASTs)),
UpdateDebounce(Opts.UpdateDebounce) {
if (0 < Opts.AsyncThreadsCount) {
PreambleTasks.emplace();
WorkerThreads.emplace();
}
}
TUScheduler::~TUScheduler() {
// Notify all workers that they need to stop.
Files.clear();
// Wait for all in-flight tasks to finish.
if (PreambleTasks)
PreambleTasks->wait();
if (WorkerThreads)
WorkerThreads->wait();
}
bool TUScheduler::blockUntilIdle(Deadline D) const {
for (auto &File : Files)
if (!File.getValue()->Worker->blockUntilIdle(D))
return false;
if (PreambleTasks)
if (!PreambleTasks->wait(D))
return false;
return true;
}
bool TUScheduler::update(PathRef File, ParseInputs Inputs,
WantDiagnostics WantDiags) {
std::unique_ptr<FileData> &FD = Files[File];
bool NewFile = FD == nullptr;
if (!FD) {
// Create a new worker to process the AST-related tasks.
ASTWorkerHandle Worker = ASTWorker::create(
File, CDB, *IdleASTs,
WorkerThreads ? WorkerThreads.getPointer() : nullptr, Barrier,
UpdateDebounce, StorePreamblesInMemory, *Callbacks);
FD = std::unique_ptr<FileData>(
new FileData{Inputs.Contents, std::move(Worker)});
} else {
FD->Contents = Inputs.Contents;
}
FD->Worker->update(std::move(Inputs), WantDiags);
return NewFile;
}
void TUScheduler::remove(PathRef File) {
bool Removed = Files.erase(File);
if (!Removed)
elog("Trying to remove file from TUScheduler that is not tracked: {0}",
File);
}
llvm::StringRef TUScheduler::getContents(PathRef File) const {
auto It = Files.find(File);
if (It == Files.end()) {
elog("getContents() for untracked file: {0}", File);
return "";
}
return It->second->Contents;
}
llvm::StringMap<std::string> TUScheduler::getAllFileContents() const {
llvm::StringMap<std::string> Results;
for (auto &It : Files)
Results.try_emplace(It.getKey(), It.getValue()->Contents);
return Results;
}
void TUScheduler::run(llvm::StringRef Name,
llvm::unique_function<void()> Action) {
if (!PreambleTasks)
return Action();
PreambleTasks->runAsync(Name, [this, Ctx = Context::current().clone(),
Action = std::move(Action)]() mutable {
std::lock_guard<Semaphore> BarrierLock(Barrier);
WithContext WC(std::move(Ctx));
Action();
});
}
void TUScheduler::runWithAST(
llvm::StringRef Name, PathRef File,
llvm::unique_function<void(llvm::Expected<InputsAndAST>)> Action) {
auto It = Files.find(File);
if (It == Files.end()) {
Action(llvm::make_error<LSPError>(
"trying to get AST for non-added document", ErrorCode::InvalidParams));
return;
}
It->second->Worker->runWithAST(Name, std::move(Action));
}
void TUScheduler::runWithPreamble(llvm::StringRef Name, PathRef File,
PreambleConsistency Consistency,
Callback<InputsAndPreamble> Action) {
auto It = Files.find(File);
if (It == Files.end()) {
Action(llvm::make_error<LSPError>(
"trying to get preamble for non-added document",
ErrorCode::InvalidParams));
return;
}
if (!PreambleTasks) {
trace::Span Tracer(Name);
SPAN_ATTACH(Tracer, "file", File);
std::shared_ptr<const PreambleData> Preamble =
It->second->Worker->getPossiblyStalePreamble();
Action(InputsAndPreamble{It->second->Contents,
It->second->Worker->getCurrentCompileCommand(),
Preamble.get()});
return;
}
// Future is populated if the task needs a specific preamble.
std::future<std::shared_ptr<const PreambleData>> ConsistentPreamble;
if (Consistency == Consistent) {
std::promise<std::shared_ptr<const PreambleData>> Promise;
ConsistentPreamble = Promise.get_future();
It->second->Worker->getCurrentPreamble(
[Promise = std::move(Promise)](
std::shared_ptr<const PreambleData> Preamble) mutable {
Promise.set_value(std::move(Preamble));
});
}
std::shared_ptr<const ASTWorker> Worker = It->second->Worker.lock();
auto Task =
[Worker, Consistency, Name = Name.str(), File = File.str(),
Contents = It->second->Contents,
Command = Worker->getCurrentCompileCommand(),
Ctx = Context::current().derive(kFileBeingProcessed, std::string(File)),
ConsistentPreamble = std::move(ConsistentPreamble),
Action = std::move(Action), this]() mutable {
std::shared_ptr<const PreambleData> Preamble;
if (ConsistentPreamble.valid()) {
Preamble = ConsistentPreamble.get();
} else {
if (Consistency != PreambleConsistency::StaleOrAbsent) {
// Wait until the preamble is built for the first time, if preamble
// is required. This avoids extra work of processing the preamble
// headers in parallel multiple times.
Worker->waitForFirstPreamble();
}
Preamble = Worker->getPossiblyStalePreamble();
}
std::lock_guard<Semaphore> BarrierLock(Barrier);
WithContext Guard(std::move(Ctx));
trace::Span Tracer(Name);
SPAN_ATTACH(Tracer, "file", File);
Action(InputsAndPreamble{Contents, Command, Preamble.get()});
};
PreambleTasks->runAsync("task:" + llvm::sys::path::filename(File),
std::move(Task));
}
std::vector<std::pair<Path, std::size_t>>
TUScheduler::getUsedBytesPerFile() const {
std::vector<std::pair<Path, std::size_t>> Result;
Result.reserve(Files.size());
for (auto &&PathAndFile : Files)
Result.push_back({std::string(PathAndFile.first()),
PathAndFile.second->Worker->getUsedBytes()});
return Result;
}
std::vector<Path> TUScheduler::getFilesWithCachedAST() const {
std::vector<Path> Result;
for (auto &&PathAndFile : Files) {
if (!PathAndFile.second->Worker->isASTCached())
continue;
Result.push_back(std::string(PathAndFile.first()));
}
return Result;
}
} // namespace clangd
} // namespace clang