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

325 lines
10 KiB
C++

//===--- JSONRPCDispatcher.cpp - Main JSON parser entry point -------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "JSONRPCDispatcher.h"
#include "JSONExpr.h"
#include "ProtocolHandlers.h"
#include "Trace.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/Support/Chrono.h"
#include "llvm/Support/SourceMgr.h"
#include <istream>
using namespace clang;
using namespace clangd;
namespace {
static Key<json::Expr> RequestID;
static Key<JSONOutput *> RequestOut;
// When tracing, we trace a request and attach the repsonse in reply().
// Because the Span isn't available, we find the current request using Context.
class RequestSpan {
RequestSpan(json::obj *Args) : Args(Args) {}
std::mutex Mu;
json::obj *Args;
static Key<std::unique_ptr<RequestSpan>> RSKey;
public:
// Return a context that's aware of the enclosing request, identified by Span.
static Context stash(const trace::Span &Span) {
return Context::current().derive(
RSKey, std::unique_ptr<RequestSpan>(new RequestSpan(Span.Args)));
}
// If there's an enclosing request and the tracer is interested, calls \p F
// with a json::obj where request info can be added.
template <typename Func> static void attach(Func &&F) {
auto *RequestArgs = Context::current().get(RSKey);
if (!RequestArgs || !*RequestArgs || !(*RequestArgs)->Args)
return;
std::lock_guard<std::mutex> Lock((*RequestArgs)->Mu);
F(*(*RequestArgs)->Args);
}
};
Key<std::unique_ptr<RequestSpan>> RequestSpan::RSKey;
} // namespace
void JSONOutput::writeMessage(const json::Expr &Message) {
std::string S;
llvm::raw_string_ostream OS(S);
if (Pretty)
OS << llvm::formatv("{0:2}", Message);
else
OS << Message;
OS.flush();
{
std::lock_guard<std::mutex> Guard(StreamMutex);
Outs << "Content-Length: " << S.size() << "\r\n\r\n" << S;
Outs.flush();
}
log(llvm::Twine("--> ") + S);
}
void JSONOutput::log(const Twine &Message) {
llvm::sys::TimePoint<> Timestamp = std::chrono::system_clock::now();
trace::log(Message);
std::lock_guard<std::mutex> Guard(StreamMutex);
Logs << llvm::formatv("[{0:%H:%M:%S.%L}] {1}\n", Timestamp, Message);
Logs.flush();
}
void JSONOutput::mirrorInput(const Twine &Message) {
if (!InputMirror)
return;
*InputMirror << Message;
InputMirror->flush();
}
void clangd::reply(json::Expr &&Result) {
auto ID = Context::current().get(RequestID);
if (!ID) {
log("Attempted to reply to a notification!");
return;
}
RequestSpan::attach([&](json::obj &Args) { Args["Reply"] = Result; });
Context::current()
.getExisting(RequestOut)
->writeMessage(json::obj{
{"jsonrpc", "2.0"},
{"id", *ID},
{"result", std::move(Result)},
});
}
void clangd::replyError(ErrorCode code, const llvm::StringRef &Message) {
log("Error " + Twine(static_cast<int>(code)) + ": " + Message);
RequestSpan::attach([&](json::obj &Args) {
Args["Error"] =
json::obj{{"code", static_cast<int>(code)}, {"message", Message.str()}};
});
if (auto ID = Context::current().get(RequestID)) {
Context::current()
.getExisting(RequestOut)
->writeMessage(json::obj{
{"jsonrpc", "2.0"},
{"id", *ID},
{"error",
json::obj{{"code", static_cast<int>(code)}, {"message", Message}}},
});
}
}
void clangd::call(StringRef Method, json::Expr &&Params) {
// FIXME: Generate/Increment IDs for every request so that we can get proper
// replies once we need to.
RequestSpan::attach([&](json::obj &Args) {
Args["Call"] = json::obj{{"method", Method.str()}, {"params", Params}};
});
Context::current()
.getExisting(RequestOut)
->writeMessage(json::obj{
{"jsonrpc", "2.0"},
{"id", 1},
{"method", Method},
{"params", std::move(Params)},
});
}
void JSONRPCDispatcher::registerHandler(StringRef Method, Handler H) {
assert(!Handlers.count(Method) && "Handler already registered!");
Handlers[Method] = std::move(H);
}
bool JSONRPCDispatcher::call(const json::Expr &Message, JSONOutput &Out) const {
// Message must be an object with "jsonrpc":"2.0".
auto *Object = Message.asObject();
if (!Object || Object->getString("jsonrpc") != Optional<StringRef>("2.0"))
return false;
// ID may be any JSON value. If absent, this is a notification.
llvm::Optional<json::Expr> ID;
if (auto *I = Object->get("id"))
ID = std::move(*I);
// Method must be given.
auto Method = Object->getString("method");
if (!Method)
return false;
// Params should be given, use null if not.
json::Expr Params = nullptr;
if (auto *P = Object->get("params"))
Params = std::move(*P);
auto I = Handlers.find(*Method);
auto &Handler = I != Handlers.end() ? I->second : UnknownHandler;
// Create a Context that contains request information.
WithContextValue WithRequestOut(RequestOut, &Out);
llvm::Optional<WithContextValue> WithID;
if (ID)
WithID.emplace(RequestID, *ID);
// Create a tracing Span covering the whole request lifetime.
trace::Span Tracer(*Method);
if (ID)
SPAN_ATTACH(Tracer, "ID", *ID);
SPAN_ATTACH(Tracer, "Params", Params);
// Stash a reference to the span args, so later calls can add metadata.
WithContext WithRequestSpan(RequestSpan::stash(Tracer));
Handler(std::move(Params));
return true;
}
static llvm::Optional<std::string> readStandardMessage(std::istream &In,
JSONOutput &Out) {
// A Language Server Protocol message starts with a set of HTTP headers,
// delimited by \r\n, and terminated by an empty line (\r\n).
unsigned long long ContentLength = 0;
while (In.good()) {
std::string Line;
std::getline(In, Line);
if (!In.good() && errno == EINTR) {
In.clear();
continue;
}
Out.mirrorInput(Line);
// Mirror '\n' that gets consumed by std::getline, but is not included in
// the resulting Line.
// Note that '\r' is part of Line, so we don't need to mirror it
// separately.
if (!In.eof())
Out.mirrorInput("\n");
llvm::StringRef LineRef(Line);
// We allow comments in headers. Technically this isn't part
// of the LSP specification, but makes writing tests easier.
if (LineRef.startswith("#"))
continue;
// Content-Type is a specified header, but does nothing.
// Content-Length is a mandatory header. It specifies the length of the
// following JSON.
// It is unspecified what sequence headers must be supplied in, so we
// allow any sequence.
// The end of headers is signified by an empty line.
if (LineRef.consume_front("Content-Length: ")) {
if (ContentLength != 0) {
log("Warning: Duplicate Content-Length header received. "
"The previous value for this message (" +
llvm::Twine(ContentLength) + ") was ignored.\n");
}
llvm::getAsUnsignedInteger(LineRef.trim(), 0, ContentLength);
continue;
} else if (!LineRef.trim().empty()) {
// It's another header, ignore it.
continue;
} else {
// An empty line indicates the end of headers.
// Go ahead and read the JSON.
break;
}
}
// Guard against large messages. This is usually a bug in the client code
// and we don't want to crash downstream because of it.
if (ContentLength > 1 << 30) { // 1024M
In.ignore(ContentLength);
log("Skipped overly large message of " + Twine(ContentLength) +
" bytes.\n");
return llvm::None;
}
if (ContentLength > 0) {
std::string JSON(ContentLength, '\0');
In.read(&JSON[0], ContentLength);
Out.mirrorInput(StringRef(JSON.data(), In.gcount()));
// If the stream is aborted before we read ContentLength bytes, In
// will have eofbit and failbit set.
if (!In) {
log("Input was aborted. Read only " + llvm::Twine(In.gcount()) +
" bytes of expected " + llvm::Twine(ContentLength) + ".\n");
return llvm::None;
}
return std::move(JSON);
} else {
log("Warning: Missing Content-Length header, or message has zero "
"length.\n");
return llvm::None;
}
}
// For lit tests we support a simplified syntax:
// - messages are delimited by '---' on a line by itself
// - lines starting with # are ignored.
// This is a testing path, so favor simplicity over performance here.
static llvm::Optional<std::string> readDelimitedMessage(std::istream &In,
JSONOutput &Out) {
std::string JSON;
std::string Line;
while (std::getline(In, Line)) {
if (!In.eof()) // getline() consumed the newline.
Line.push_back('\n');
auto LineRef = llvm::StringRef(Line).trim();
if (LineRef.startswith("#")) // comment
continue;
bool IsDelim = LineRef.find_first_not_of('-') == llvm::StringRef::npos;
if (!IsDelim) // Line is part of a JSON message.
JSON += Line;
if (IsDelim || In.eof()) {
Out.mirrorInput(
llvm::formatv("Content-Length: {0}\r\n\r\n{1}", JSON.size(), JSON));
return std::move(JSON);
}
}
if (In.bad()) {
log("Input error while reading message!");
return llvm::None;
} else {
log("Input message terminated by EOF");
return std::move(JSON);
}
}
void clangd::runLanguageServerLoop(std::istream &In, JSONOutput &Out,
JSONStreamStyle InputStyle,
JSONRPCDispatcher &Dispatcher,
bool &IsDone) {
auto &ReadMessage =
(InputStyle == Delimited) ? readDelimitedMessage : readStandardMessage;
while (In.good()) {
if (auto JSON = ReadMessage(In, Out)) {
if (auto Doc = json::parse(*JSON)) {
// Log the formatted message.
log(llvm::formatv(Out.Pretty ? "<-- {0:2}\n" : "<-- {0}\n", *Doc));
// Finally, execute the action for this JSON message.
if (!Dispatcher.call(*Doc, Out))
log("JSON dispatch failed!\n");
} else {
// Parse error. Log the raw message.
log(llvm::formatv("<-- {0}\n" , *JSON));
log(llvm::Twine("JSON parse error: ") +
llvm::toString(Doc.takeError()) + "\n");
}
}
// If we're done, exit the loop.
if (IsDone)
break;
}
}