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| author | jpayne |
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| date | Tue, 18 Mar 2025 17:55:14 -0400 |
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// Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors // Licensed under the MIT License: // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. #pragma once #include "async.h" #include <kj/function.h> #include <kj/thread.h> #include <kj/timer.h> KJ_BEGIN_HEADER struct sockaddr; namespace kj { #if _WIN32 class Win32EventPort; class AutoCloseHandle; #else class UnixEventPort; #endif class AutoCloseFd; class NetworkAddress; class AsyncOutputStream; class AsyncIoStream; class AncillaryMessage; class ReadableFile; class File; // ======================================================================================= // Streaming I/O class AsyncInputStream: private AsyncObject { // Asynchronous equivalent of InputStream (from io.h). public: virtual Promise<size_t> read(void* buffer, size_t minBytes, size_t maxBytes); virtual Promise<size_t> tryRead(void* buffer, size_t minBytes, size_t maxBytes) = 0; Promise<void> read(void* buffer, size_t bytes); virtual Maybe<uint64_t> tryGetLength(); // Get the remaining number of bytes that will be produced by this stream, if known. // // This is used e.g. to fill in the Content-Length header of an HTTP message. If unknown, the // HTTP implementation may need to fall back to Transfer-Encoding: chunked. // // The default implementation always returns null. virtual Promise<uint64_t> pumpTo( AsyncOutputStream& output, uint64_t amount = kj::maxValue); // Read `amount` bytes from this stream (or to EOF) and write them to `output`, returning the // total bytes actually pumped (which is only less than `amount` if EOF was reached). // // Override this if your stream type knows how to pump itself to certain kinds of output // streams more efficiently than via the naive approach. You can use // kj::dynamicDowncastIfAvailable() to test for stream types you recognize, and if none match, // delegate to the default implementation. // // The default implementation first tries calling output.tryPumpFrom(), but if that fails, it // performs a naive pump by allocating a buffer and reading to it / writing from it in a loop. Promise<Array<byte>> readAllBytes(uint64_t limit = kj::maxValue); Promise<String> readAllText(uint64_t limit = kj::maxValue); // Read until EOF and return as one big byte array or string. Throw an exception if EOF is not // seen before reading `limit` bytes. // // To prevent runaway memory allocation, consider using a more conservative value for `limit` than // the default, particularly on untrusted data streams which may never see EOF. virtual void registerAncillaryMessageHandler(Function<void(ArrayPtr<AncillaryMessage>)> fn); // Register interest in checking for ancillary messages (aka control messages) when reading. // The provided callback will be called whenever any are encountered. The messages passed to // the function do not live beyond when function returns. // Only supported on Unix (the default impl throws UNIMPLEMENTED). Most apps will not use this. virtual Maybe<Own<AsyncInputStream>> tryTee(uint64_t limit = kj::maxValue); // Primarily intended as an optimization for the `tee` call. Returns an input stream whose state // is independent from this one but which will return the exact same set of bytes read going // forward. limit is a total limit on the amount of memory, in bytes, which a tee implementation // may use to buffer stream data. An implementation must throw an exception if a read operation // would cause the limit to be exceeded. If tryTee() can see that the new limit is impossible to // satisfy, it should return nullptr so that the pessimized path is taken in newTee. This is // likely to arise if tryTee() is called twice with different limits on the same stream. }; class AsyncOutputStream: private AsyncObject { // Asynchronous equivalent of OutputStream (from io.h). public: virtual Promise<void> write(const void* buffer, size_t size) KJ_WARN_UNUSED_RESULT = 0; virtual Promise<void> write(ArrayPtr<const ArrayPtr<const byte>> pieces) KJ_WARN_UNUSED_RESULT = 0; virtual Maybe<Promise<uint64_t>> tryPumpFrom( AsyncInputStream& input, uint64_t amount = kj::maxValue); // Implements double-dispatch for AsyncInputStream::pumpTo(). // // This method should only be called from within an implementation of pumpTo(). // // This method examines the type of `input` to find optimized ways to pump data from it to this // output stream. If it finds one, it performs the pump. Otherwise, it returns null. // // The default implementation always returns null. virtual Promise<void> whenWriteDisconnected() = 0; // Returns a promise that resolves when the stream has become disconnected such that new write()s // will fail with a DISCONNECTED exception. This is particularly useful, for example, to cancel // work early when it is detected that no one will receive the result. // // Note that not all streams are able to detect this condition without actually performing a // write(); such stream implementations may return a promise that never resolves. (In particular, // as of this writing, whenWriteDisconnected() is not implemented on Windows. Also, for TCP // streams, not all disconnects are detectable -- a power or network failure may lead the // connection to hang forever, or until configured socket options lead to a timeout.) // // Unlike most other asynchronous stream methods, it is safe to call whenWriteDisconnected() // multiple times without canceling the previous promises. }; class AsyncIoStream: public AsyncInputStream, public AsyncOutputStream { // A combination input and output stream. public: virtual void shutdownWrite() = 0; // Cleanly shut down just the write end of the stream, while keeping the read end open. virtual void abortRead() {} // Similar to shutdownWrite, but this will shut down the read end of the stream, and should only // be called when an error has occurred. virtual void getsockopt(int level, int option, void* value, uint* length); virtual void setsockopt(int level, int option, const void* value, uint length); // Corresponds to getsockopt() and setsockopt() syscalls. Will throw an "unimplemented" exception // if the stream is not a socket or the option is not appropriate for the socket type. The // default implementations always throw "unimplemented". virtual void getsockname(struct sockaddr* addr, uint* length); virtual void getpeername(struct sockaddr* addr, uint* length); // Corresponds to getsockname() and getpeername() syscalls. Will throw an "unimplemented" // exception if the stream is not a socket. The default implementations always throw // "unimplemented". // // Note that we don't provide methods that return NetworkAddress because it usually wouldn't // be useful. You can't connect() to or listen() on these addresses, obviously, because they are // ephemeral addresses for a single connection. virtual kj::Maybe<int> getFd() const { return nullptr; } // Get the underlying Unix file descriptor, if any. Returns nullptr if this object actually // isn't wrapping a file descriptor. }; Promise<uint64_t> unoptimizedPumpTo( AsyncInputStream& input, AsyncOutputStream& output, uint64_t amount, uint64_t completedSoFar = 0); // Performs a pump using read() and write(), without calling the stream's pumpTo() nor // tryPumpFrom() methods. This is intended to be used as a fallback by implementations of pumpTo() // and tryPumpFrom() when they want to give up on optimization, but can't just call pumpTo() again // because this would recursively retry the optimization. unoptimizedPumpTo() should only be called // inside implementations of streams, never by the caller of a stream -- use the pumpTo() method // instead. // // `completedSoFar` is the number of bytes out of `amount` that have already been pumped. This is // provided for convenience for cases where the caller has already done some pumping before they // give up. Otherwise, a `.then()` would need to be used to add the bytes to the final result. class AsyncCapabilityStream: public AsyncIoStream { // An AsyncIoStream that also allows transmitting new stream objects and file descriptors // (capabilities, in the object-capability model sense), in addition to bytes. // // Capabilities can be attached to bytes when they are written. On the receiving end, the read() // that receives the first byte of such a message will also receive the capabilities. // // Note that AsyncIoStream's regular byte-oriented methods can be used on AsyncCapabilityStream, // with the effect of silently dropping any capabilities attached to the respective bytes. E.g. // using `AsyncIoStream::tryRead()` to read bytes that had been sent with `writeWithFds()` will // silently drop the FDs (closing them if appropriate). Also note that pumping a stream with // `pumpTo()` always drops all capabilities attached to the pumped data. (TODO(someday): Do we // want a version of pumpTo() that preserves capabilities?) // // On Unix, KJ provides an implementation based on Unix domain sockets and file descriptor // passing via SCM_RIGHTS. Due to the nature of SCM_RIGHTS, if the application accidentally // read()s when it should have called receiveStream(), it will observe a NUL byte in the data // and the capability will be discarded. Of course, an application should not depend on this // behavior; it should avoid read()ing through a capability. // // KJ does not provide any inter-process implementation of this type on Windows, as there's no // obvious implementation there. Handle passing on Windows requires at least one of the processes // involved to have permission to modify the other's handle table, which is effectively full // control. Handle passing between mutually non-trusting processes would require a trusted // broker process to facilitate. One could possibly implement this type in terms of such a // broker, or in terms of direct handle passing if at least one process trusts the other. public: virtual Promise<void> writeWithFds(ArrayPtr<const byte> data, ArrayPtr<const ArrayPtr<const byte>> moreData, ArrayPtr<const int> fds) = 0; Promise<void> writeWithFds(ArrayPtr<const byte> data, ArrayPtr<const ArrayPtr<const byte>> moreData, ArrayPtr<const AutoCloseFd> fds); // Write some data to the stream with some file descriptors attached to it. // // The maximum number of FDs that can be sent at a time is usually subject to an OS-imposed // limit. On Linux, this is 253. In practice, sending more than a handful of FDs at once is // probably a bad idea. struct ReadResult { size_t byteCount; size_t capCount; }; virtual Promise<ReadResult> tryReadWithFds(void* buffer, size_t minBytes, size_t maxBytes, AutoCloseFd* fdBuffer, size_t maxFds) = 0; // Read data from the stream that may have file descriptors attached. Any attached descriptors // will be placed in `fdBuffer`. If multiple bundles of FDs are encountered in the course of // reading the amount of data requested by minBytes/maxBytes, then they will be concatenated. If // more FDs are received than fit in the buffer, then the excess will be discarded and closed -- // this behavior, while ugly, is important to defend against denial-of-service attacks that may // fill up the FD table with garbage. Applications must think carefully about how many FDs they // really need to receive at once and set a well-defined limit. virtual Promise<void> writeWithStreams(ArrayPtr<const byte> data, ArrayPtr<const ArrayPtr<const byte>> moreData, Array<Own<AsyncCapabilityStream>> streams) = 0; virtual Promise<ReadResult> tryReadWithStreams( void* buffer, size_t minBytes, size_t maxBytes, Own<AsyncCapabilityStream>* streamBuffer, size_t maxStreams) = 0; // Like above, but passes AsyncCapabilityStream objects. The stream implementations must be from // the same AsyncIoProvider. // --------------------------------------------------------------------------- // Helpers for sending individual capabilities. // // These are equivalent to the above methods with the constraint that only one FD is // sent/received at a time and the corresponding data is a single zero-valued byte. Promise<Own<AsyncCapabilityStream>> receiveStream(); Promise<Maybe<Own<AsyncCapabilityStream>>> tryReceiveStream(); Promise<void> sendStream(Own<AsyncCapabilityStream> stream); // Transfer a single stream. Promise<AutoCloseFd> receiveFd(); Promise<Maybe<AutoCloseFd>> tryReceiveFd(); Promise<void> sendFd(int fd); // Transfer a single raw file descriptor. }; struct OneWayPipe { // A data pipe with an input end and an output end. (Typically backed by pipe() system call.) Own<AsyncInputStream> in; Own<AsyncOutputStream> out; }; OneWayPipe newOneWayPipe(kj::Maybe<uint64_t> expectedLength = nullptr); // Constructs a OneWayPipe that operates in-process. The pipe does not do any buffering -- it waits // until both a read() and a write() call are pending, then resolves both. // // If `expectedLength` is non-null, then the pipe will be expected to transmit exactly that many // bytes. The input end's `tryGetLength()` will return the number of bytes left. struct TwoWayPipe { // A data pipe that supports sending in both directions. Each end's output sends data to the // other end's input. (Typically backed by socketpair() system call.) Own<AsyncIoStream> ends[2]; }; TwoWayPipe newTwoWayPipe(); // Constructs a TwoWayPipe that operates in-process. The pipe does not do any buffering -- it waits // until both a read() and a write() call are pending, then resolves both. struct CapabilityPipe { // Like TwoWayPipe but allowing capability-passing. Own<AsyncCapabilityStream> ends[2]; }; CapabilityPipe newCapabilityPipe(); // Like newTwoWayPipe() but creates a capability pipe. // // The requirement of `writeWithStreams()` that "The stream implementations must be from the same // AsyncIoProvider." does not apply to this pipe; any kind of AsyncCapabilityStream implementation // is supported. // // This implementation does not know how to convert streams to FDs or vice versa; if you write FDs // you must read FDs, and if you write streams you must read streams. struct Tee { // Two AsyncInputStreams which each read the same data from some wrapped inner AsyncInputStream. Own<AsyncInputStream> branches[2]; }; Tee newTee(Own<AsyncInputStream> input, uint64_t limit = kj::maxValue); // Constructs a Tee that operates in-process. The tee buffers data if any read or pump operations is // called on one of the two input ends. If a read or pump operation is subsequently called on the // other input end, the buffered data is consumed. // // `pumpTo()` operations on the input ends will proactively read from the inner stream and block // while writing to the output stream. While one branch has an active `pumpTo()` operation, any // `tryRead()` operation on the other branch will not be allowed to read faster than allowed by the // pump's backpressure. (In other words, it will never cause buffering on the pump.) Similarly, if // there are `pumpTo()` operations active on both branches, the greater of the two backpressures is // respected -- the two pumps progress in lockstep, and there is no buffering. // // At no point will a branch's buffer be allowed to grow beyond `limit` bytes. If the buffer would // grow beyond the limit, an exception is generated, which both branches see once they have // exhausted their buffers. // // It is recommended that you use a more conservative value for `limit` than the default. Own<AsyncOutputStream> newPromisedStream(Promise<Own<AsyncOutputStream>> promise); Own<AsyncIoStream> newPromisedStream(Promise<Own<AsyncIoStream>> promise); // Constructs an Async*Stream which waits for a promise to resolve, then forwards all calls to the // promised stream. // ======================================================================================= // Authenticated streams class PeerIdentity { // PeerIdentity provides information about a connecting client. Various subclasses exist to // address different network types. public: virtual kj::String toString() = 0; // Returns a human-readable string identifying the peer. Where possible, this string will be // in the same format as the addresses you could pass to `kj::Network::parseAddress()`. However, // only certain subclasses of `PeerIdentity` guarantee this property. }; struct AuthenticatedStream { // A pair of an `AsyncIoStream` and a `PeerIdentity`. This is used as the return type of // `NetworkAddress::connectAuthenticated()` and `ConnectionReceiver::acceptAuthenticated()`. Own<AsyncIoStream> stream; // The byte stream. Own<PeerIdentity> peerIdentity; // An object indicating who is at the other end of the stream. // // Different subclasses of `PeerIdentity` are used in different situations: // - TCP connections will use NetworkPeerIdentity, which gives the network address of the client. // - Local (unix) socket connections will use LocalPeerIdentity, which identifies the UID // and PID of the process that initiated the connection. // - TLS connections will use TlsPeerIdentity which provides details of the client certificate, // if any was provided. // - When no meaningful peer identity can be provided, `UnknownPeerIdentity` is returned. // // Implementations of `Network`, `ConnectionReceiver`, `NetworkAddress`, etc. should document the // specific assumptions the caller can make about the type of `PeerIdentity`s used, allowing for // identities to be statically downcast if the right conditions are met. In the absence of // documented promises, RTTI may be needed to query the type. }; class NetworkPeerIdentity: public PeerIdentity { // PeerIdentity used for network protocols like TCP/IP. This identifies the remote peer. // // This is only "authenticated" to the extent that we know data written to the stream will be // routed to the given address. This does not preclude the possibility of man-in-the-middle // attacks by attackers who are able to manipulate traffic along the route. public: virtual NetworkAddress& getAddress() = 0; // Obtain the peer's address as a NetworkAddress object. The returned reference's lifetime is the // same as the `NetworkPeerIdentity`, but you can always call `clone()` on it to get a copy that // lives longer. static kj::Own<NetworkPeerIdentity> newInstance(kj::Own<NetworkAddress> addr); // Construct an instance of this interface wrapping the given address. }; class LocalPeerIdentity: public PeerIdentity { // PeerIdentity used for connections between processes on the local machine -- in particular, // Unix sockets. // // (This interface probably isn't useful on Windows.) public: struct Credentials { kj::Maybe<int> pid; kj::Maybe<uint> uid; // We don't cover groups at present because some systems produce a list of groups while others // only provide the peer's main group, the latter being pretty useless. }; virtual Credentials getCredentials() = 0; // Get the PID and UID of the peer process, if possible. // // Either ID may be null if the peer could not be identified. Some operating systems do not // support retrieving these credentials, or can only provide one or the other. Some situations // (like user and PID namespaces on Linux) may also make it impossible to represent the peer's // credentials accurately. // // Note the meaning here can be subtle. Multiple processes can potentially have the socket in // their file descriptor tables. The identified process is the one who called `connect()` or // `listen()`. // // On Linux this is implemented with SO_PEERCRED. static kj::Own<LocalPeerIdentity> newInstance(Credentials creds); // Construct an instance of this interface wrapping the given credentials. }; class UnknownPeerIdentity: public PeerIdentity { public: static kj::Own<UnknownPeerIdentity> newInstance(); // Get an instance of this interface. This actually always returns the same instance with no // memory allocation. }; // ======================================================================================= // Accepting connections class ConnectionReceiver: private AsyncObject { // Represents a server socket listening on a port. public: virtual Promise<Own<AsyncIoStream>> accept() = 0; // Accept the next incoming connection. virtual Promise<AuthenticatedStream> acceptAuthenticated(); // Accept the next incoming connection, and also provide a PeerIdentity with any information // about the client. // // For backwards-compatibility, the default implementation of this method calls `accept()` and // then adds `UnknownPeerIdentity`. virtual uint getPort() = 0; // Gets the port number, if applicable (i.e. if listening on IP). This is useful if you didn't // specify a port when constructing the NetworkAddress -- one will have been assigned // automatically. virtual void getsockopt(int level, int option, void* value, uint* length); virtual void setsockopt(int level, int option, const void* value, uint length); virtual void getsockname(struct sockaddr* addr, uint* length); // Same as the methods of AsyncIoStream. }; Own<ConnectionReceiver> newAggregateConnectionReceiver(Array<Own<ConnectionReceiver>> receivers); // Create a ConnectionReceiver that listens on several other ConnectionReceivers and returns // sockets from any of them. // ======================================================================================= // Datagram I/O class AncillaryMessage { // Represents an ancillary message (aka control message) received using the recvmsg() system // call (or equivalent). Most apps will not use this. public: inline AncillaryMessage(int level, int type, ArrayPtr<const byte> data); AncillaryMessage() = default; inline int getLevel() const; // Originating protocol / socket level. inline int getType() const; // Protocol-specific message type. template <typename T> inline Maybe<const T&> as() const; // Interpret the ancillary message as the given struct type. Most ancillary messages are some // sort of struct, so this is a convenient way to access it. Returns nullptr if the message // is smaller than the struct -- this can happen if the message was truncated due to // insufficient ancillary buffer space. template <typename T> inline ArrayPtr<const T> asArray() const; // Interpret the ancillary message as an array of items. If the message size does not evenly // divide into elements of type T, the remainder is discarded -- this can happen if the message // was truncated due to insufficient ancillary buffer space. private: int level; int type; ArrayPtr<const byte> data; // Message data. In most cases you should use `as()` or `asArray()`. }; class DatagramReceiver { // Class encapsulating the recvmsg() system call. You must specify the DatagramReceiver's // capacity in advance; if a received packet is larger than the capacity, it will be truncated. public: virtual Promise<void> receive() = 0; // Receive a new message, overwriting this object's content. // // receive() may reuse the same buffers for content and ancillary data with each call. template <typename T> struct MaybeTruncated { T value; bool isTruncated; // True if the Receiver's capacity was insufficient to receive the value and therefore the // value is truncated. }; virtual MaybeTruncated<ArrayPtr<const byte>> getContent() = 0; // Get the content of the datagram. virtual MaybeTruncated<ArrayPtr<const AncillaryMessage>> getAncillary() = 0; // Ancillary messages received with the datagram. See the recvmsg() system call and the cmsghdr // struct. Most apps don't need this. // // If the returned value is truncated, then the last message in the array may itself be // truncated, meaning its as<T>() method will return nullptr or its asArray<T>() method will // return fewer elements than expected. Truncation can also mean that additional messages were // available but discarded. virtual NetworkAddress& getSource() = 0; // Get the datagram sender's address. struct Capacity { size_t content = 8192; // How much space to allocate for the datagram content. If a datagram is received that is // larger than this, it will be truncated, with no way to recover the tail. size_t ancillary = 0; // How much space to allocate for ancillary messages. As with content, if the ancillary data // is larger than this, it will be truncated. }; }; class DatagramPort { public: virtual Promise<size_t> send(const void* buffer, size_t size, NetworkAddress& destination) = 0; virtual Promise<size_t> send(ArrayPtr<const ArrayPtr<const byte>> pieces, NetworkAddress& destination) = 0; virtual Own<DatagramReceiver> makeReceiver( DatagramReceiver::Capacity capacity = DatagramReceiver::Capacity()) = 0; // Create a new `Receiver` that can be used to receive datagrams. `capacity` specifies how much // space to allocate for the received message. The `DatagramPort` must outlive the `Receiver`. virtual uint getPort() = 0; // Gets the port number, if applicable (i.e. if listening on IP). This is useful if you didn't // specify a port when constructing the NetworkAddress -- one will have been assigned // automatically. virtual void getsockopt(int level, int option, void* value, uint* length); virtual void setsockopt(int level, int option, const void* value, uint length); // Same as the methods of AsyncIoStream. }; // ======================================================================================= // Networks class NetworkAddress: private AsyncObject { // Represents a remote address to which the application can connect. public: virtual Promise<Own<AsyncIoStream>> connect() = 0; // Make a new connection to this address. // // The address must not be a wildcard ("*"). If it is an IP address, it must have a port number. virtual Promise<AuthenticatedStream> connectAuthenticated(); // Connect to the address and return both the connection and information about the peer identity. // This is especially useful when using TLS, to get certificate details. // // For backwards-compatibility, the default implementation of this method calls `connect()` and // then uses a `NetworkPeerIdentity` wrapping a clone of this `NetworkAddress` -- which is not // particularly useful. virtual Own<ConnectionReceiver> listen() = 0; // Listen for incoming connections on this address. // // The address must be local. virtual Own<DatagramPort> bindDatagramPort(); // Open this address as a datagram (e.g. UDP) port. // // The address must be local. virtual Own<NetworkAddress> clone() = 0; // Returns an equivalent copy of this NetworkAddress. virtual String toString() = 0; // Produce a human-readable string which hopefully can be passed to Network::parseAddress() // to reproduce this address, although whether or not that works of course depends on the Network // implementation. This should be called only to display the address to human users, who will // hopefully know what they are able to do with it. }; class Network { // Factory for NetworkAddress instances, representing the network services offered by the // operating system. // // This interface typically represents broad authority, and well-designed code should limit its // use to high-level startup code and user interaction. Low-level APIs should accept // NetworkAddress instances directly and work from there, if at all possible. public: virtual Promise<Own<NetworkAddress>> parseAddress(StringPtr addr, uint portHint = 0) = 0; // Construct a network address from a user-provided string. The format of the address // strings is not specified at the API level, and application code should make no assumptions // about them. These strings should always be provided by humans, and said humans will know // what format to use in their particular context. // // `portHint`, if provided, specifies the "standard" IP port number for the application-level // service in play. If the address turns out to be an IP address (v4 or v6), and it lacks a // port number, this port will be used. If `addr` lacks a port number *and* `portHint` is // omitted, then the returned address will only support listen() and bindDatagramPort() // (not connect()), and an unused port will be chosen each time one of those methods is called. virtual Own<NetworkAddress> getSockaddr(const void* sockaddr, uint len) = 0; // Construct a network address from a legacy struct sockaddr. virtual Own<Network> restrictPeers( kj::ArrayPtr<const kj::StringPtr> allow, kj::ArrayPtr<const kj::StringPtr> deny = nullptr) KJ_WARN_UNUSED_RESULT = 0; // Constructs a new Network instance wrapping this one which restricts which peer addresses are // permitted (both for outgoing and incoming connections). // // Communication will be allowed only with peers whose addresses match one of the patterns // specified in the `allow` array. If a `deny` array is specified, then any address which matches // a pattern in `deny` and *does not* match any more-specific pattern in `allow` will also be // denied. // // The syntax of address patterns depends on the network, except that three special patterns are // defined for all networks: // - "private": Matches network addresses that are reserved by standards for private networks, // such as "10.0.0.0/8" or "192.168.0.0/16". This is a superset of "local". // - "public": Opposite of "private". // - "local": Matches network addresses that are defined by standards to only be accessible from // the local machine, such as "127.0.0.0/8" or Unix domain addresses. // - "network": Opposite of "local". // // For the standard KJ network implementation, the following patterns are also recognized: // - Network blocks specified in CIDR notation (ipv4 and ipv6), such as "192.0.2.0/24" or // "2001:db8::/32". // - "unix" to match all Unix domain addresses. (In the future, we may support specifying a // glob.) // - "unix-abstract" to match Linux's "abstract unix domain" addresses. (In the future, we may // support specifying a glob.) // // Network restrictions apply *after* DNS resolution (otherwise they'd be useless). // // It is legal to parseAddress() a restricted address. An exception won't be thrown until // connect() is called. // // It's possible to listen() on a restricted address. However, connections will only be accepted // from non-restricted addresses; others will be dropped. If a particular listen address has no // valid peers (e.g. because it's a unix socket address and unix sockets are not allowed) then // listen() may throw (or may simply never receive any connections). // // Examples: // // auto restricted = network->restrictPeers({"public"}); // // Allows connections only to/from public internet addresses. Use this when connecting to an // address specified by a third party that is not trusted and is not themselves already on your // private network. // // auto restricted = network->restrictPeers({"private"}); // // Allows connections only to/from the private network. Use this on the server side to reject // connections from the public internet. // // auto restricted = network->restrictPeers({"192.0.2.0/24"}, {"192.0.2.3/32"}); // // Allows connections only to/from 192.0.2.*, except 192.0.2.3 which is blocked. // // auto restricted = network->restrictPeers({"10.0.0.0/8", "10.1.2.3/32"}, {"10.1.2.0/24"}); // // Allows connections to/from 10.*.*.*, with the exception of 10.1.2.* (which is denied), with an // exception to the exception of 10.1.2.3 (which is allowed, because it is matched by an allow // rule that is more specific than the deny rule). }; // ======================================================================================= // I/O Provider class AsyncIoProvider { // Class which constructs asynchronous wrappers around the operating system's I/O facilities. // // Generally, the implementation of this interface must integrate closely with a particular // `EventLoop` implementation. Typically, the EventLoop implementation itself will provide // an AsyncIoProvider. public: virtual OneWayPipe newOneWayPipe() = 0; // Creates an input/output stream pair representing the ends of a one-way pipe (e.g. created with // the pipe(2) system call). virtual TwoWayPipe newTwoWayPipe() = 0; // Creates two AsyncIoStreams representing the two ends of a two-way pipe (e.g. created with // socketpair(2) system call). Data written to one end can be read from the other. virtual CapabilityPipe newCapabilityPipe(); // Creates two AsyncCapabilityStreams representing the two ends of a two-way capability pipe. // // The default implementation throws an unimplemented exception. In particular this is not // implemented by the default AsyncIoProvider on Windows, since Windows lacks any sane way to // pass handles over a stream. virtual Network& getNetwork() = 0; // Creates a new `Network` instance representing the networks exposed by the operating system. // // DO NOT CALL THIS except at the highest levels of your code, ideally in the main() function. If // you call this from low-level code, then you are preventing higher-level code from injecting an // alternative implementation. Instead, if your code needs to use network functionality, it // should ask for a `Network` as a constructor or method parameter, so that higher-level code can // chose what implementation to use. The system network is essentially a singleton. See: // http://www.object-oriented-security.org/lets-argue/singletons // // Code that uses the system network should not make any assumptions about what kinds of // addresses it will parse, as this could differ across platforms. String addresses should come // strictly from the user, who will know how to write them correctly for their system. // // With that said, KJ currently supports the following string address formats: // - IPv4: "1.2.3.4", "1.2.3.4:80" // - IPv6: "1234:5678::abcd", "[1234:5678::abcd]:80" // - Local IP wildcard (covers both v4 and v6): "*", "*:80" // - Symbolic names: "example.com", "example.com:80", "example.com:http", "1.2.3.4:http" // - Unix domain: "unix:/path/to/socket" struct PipeThread { // A combination of a thread and a two-way pipe that communicates with that thread. // // The fields are intentionally ordered so that the pipe will be destroyed (and therefore // disconnected) before the thread is destroyed (and therefore joined). Thus if the thread // arranges to exit when it detects disconnect, destruction should be clean. Own<Thread> thread; Own<AsyncIoStream> pipe; }; virtual PipeThread newPipeThread( Function<void(AsyncIoProvider&, AsyncIoStream&, WaitScope&)> startFunc) = 0; // Create a new thread and set up a two-way pipe (socketpair) which can be used to communicate // with it. One end of the pipe is passed to the thread's start function and the other end of // the pipe is returned. The new thread also gets its own `AsyncIoProvider` instance and will // already have an active `EventLoop` when `startFunc` is called. // // TODO(someday): I'm not entirely comfortable with this interface. It seems to be doing too // much at once but I'm not sure how to cleanly break it down. virtual Timer& getTimer() = 0; // Returns a `Timer` based on real time. Time does not pass while event handlers are running -- // it only updates when the event loop polls for system events. This means that calling `now()` // on this timer does not require a system call. // // This timer is not affected by changes to the system date. It is unspecified whether the timer // continues to count while the system is suspended. }; class LowLevelAsyncIoProvider { // Similar to `AsyncIoProvider`, but represents a lower-level interface that may differ on // different operating systems. You should prefer to use `AsyncIoProvider` over this interface // whenever possible, as `AsyncIoProvider` is portable and friendlier to dependency-injection. // // On Unix, this interface can be used to import native file descriptors into the async framework. // Different implementations of this interface might work on top of different event handling // primitives, such as poll vs. epoll vs. kqueue vs. some higher-level event library. // // On Windows, this interface can be used to import native SOCKETs into the async framework. // Different implementations of this interface might work on top of different event handling // primitives, such as I/O completion ports vs. completion routines. public: enum Flags { // Flags controlling how to wrap a file descriptor. TAKE_OWNERSHIP = 1 << 0, // The returned object should own the file descriptor, automatically closing it when destroyed. // The close-on-exec flag will be set on the descriptor if it is not already. // // If this flag is not used, then the file descriptor is not automatically closed and the // close-on-exec flag is not modified. #if !_WIN32 ALREADY_CLOEXEC = 1 << 1, // Indicates that the close-on-exec flag is known already to be set, so need not be set again. // Only relevant when combined with TAKE_OWNERSHIP. // // On Linux, all system calls which yield new file descriptors have flags or variants which // set the close-on-exec flag immediately. Unfortunately, other OS's do not. ALREADY_NONBLOCK = 1 << 2 // Indicates that the file descriptor is known already to be in non-blocking mode, so the flag // need not be set again. Otherwise, all wrap*Fd() methods will enable non-blocking mode // automatically. // // On Linux, all system calls which yield new file descriptors have flags or variants which // enable non-blocking mode immediately. Unfortunately, other OS's do not. #endif }; #if _WIN32 typedef uintptr_t Fd; typedef AutoCloseHandle OwnFd; // On Windows, the `fd` parameter to each of these methods must be a SOCKET, and must have the // flag WSA_FLAG_OVERLAPPED (which socket() uses by default, but WSASocket() wants you to specify // explicitly). #else typedef int Fd; typedef AutoCloseFd OwnFd; // On Unix, any arbitrary file descriptor is supported. #endif virtual Own<AsyncInputStream> wrapInputFd(Fd fd, uint flags = 0) = 0; // Create an AsyncInputStream wrapping a file descriptor. // // `flags` is a bitwise-OR of the values of the `Flags` enum. virtual Own<AsyncOutputStream> wrapOutputFd(Fd fd, uint flags = 0) = 0; // Create an AsyncOutputStream wrapping a file descriptor. // // `flags` is a bitwise-OR of the values of the `Flags` enum. virtual Own<AsyncIoStream> wrapSocketFd(Fd fd, uint flags = 0) = 0; // Create an AsyncIoStream wrapping a socket file descriptor. // // `flags` is a bitwise-OR of the values of the `Flags` enum. #if !_WIN32 virtual Own<AsyncCapabilityStream> wrapUnixSocketFd(Fd fd, uint flags = 0); // Like wrapSocketFd() but also support capability passing via SCM_RIGHTS. The socket must be // a Unix domain socket. // // The default implementation throws UNIMPLEMENTED, for backwards-compatibility with // LowLevelAsyncIoProvider implementations written before this method was added. #endif virtual Promise<Own<AsyncIoStream>> wrapConnectingSocketFd( Fd fd, const struct sockaddr* addr, uint addrlen, uint flags = 0) = 0; // Create an AsyncIoStream wrapping a socket and initiate a connection to the given address. // The returned promise does not resolve until connection has completed. // // `flags` is a bitwise-OR of the values of the `Flags` enum. class NetworkFilter { public: virtual bool shouldAllow(const struct sockaddr* addr, uint addrlen) = 0; // Returns true if incoming connections or datagrams from the given peer should be accepted. // If false, they will be dropped. This is used to implement kj::Network::restrictPeers(). static NetworkFilter& getAllAllowed(); }; virtual Own<ConnectionReceiver> wrapListenSocketFd( Fd fd, NetworkFilter& filter, uint flags = 0) = 0; inline Own<ConnectionReceiver> wrapListenSocketFd(Fd fd, uint flags = 0) { return wrapListenSocketFd(fd, NetworkFilter::getAllAllowed(), flags); } // Create an AsyncIoStream wrapping a listen socket file descriptor. This socket should already // have had `bind()` and `listen()` called on it, so it's ready for `accept()`. // // `flags` is a bitwise-OR of the values of the `Flags` enum. virtual Own<DatagramPort> wrapDatagramSocketFd(Fd fd, NetworkFilter& filter, uint flags = 0); inline Own<DatagramPort> wrapDatagramSocketFd(Fd fd, uint flags = 0) { return wrapDatagramSocketFd(fd, NetworkFilter::getAllAllowed(), flags); } virtual Timer& getTimer() = 0; // Returns a `Timer` based on real time. Time does not pass while event handlers are running -- // it only updates when the event loop polls for system events. This means that calling `now()` // on this timer does not require a system call. // // This timer is not affected by changes to the system date. It is unspecified whether the timer // continues to count while the system is suspended. Own<AsyncInputStream> wrapInputFd(OwnFd&& fd, uint flags = 0); Own<AsyncOutputStream> wrapOutputFd(OwnFd&& fd, uint flags = 0); Own<AsyncIoStream> wrapSocketFd(OwnFd&& fd, uint flags = 0); #if !_WIN32 Own<AsyncCapabilityStream> wrapUnixSocketFd(OwnFd&& fd, uint flags = 0); #endif Promise<Own<AsyncIoStream>> wrapConnectingSocketFd( OwnFd&& fd, const struct sockaddr* addr, uint addrlen, uint flags = 0); Own<ConnectionReceiver> wrapListenSocketFd( OwnFd&& fd, NetworkFilter& filter, uint flags = 0); Own<ConnectionReceiver> wrapListenSocketFd(OwnFd&& fd, uint flags = 0); Own<DatagramPort> wrapDatagramSocketFd(OwnFd&& fd, NetworkFilter& filter, uint flags = 0); Own<DatagramPort> wrapDatagramSocketFd(OwnFd&& fd, uint flags = 0); // Convenience wrappers which transfer ownership via AutoCloseFd (Unix) or AutoCloseHandle // (Windows). TAKE_OWNERSHIP will be implicitly added to `flags`. }; Own<AsyncIoProvider> newAsyncIoProvider(LowLevelAsyncIoProvider& lowLevel); // Make a new AsyncIoProvider wrapping a `LowLevelAsyncIoProvider`. struct AsyncIoContext { Own<LowLevelAsyncIoProvider> lowLevelProvider; Own<AsyncIoProvider> provider; WaitScope& waitScope; #if _WIN32 Win32EventPort& win32EventPort; #else UnixEventPort& unixEventPort; // TEMPORARY: Direct access to underlying UnixEventPort, mainly for waiting on signals. This // field will go away at some point when we have a chance to improve these interfaces. #endif }; AsyncIoContext setupAsyncIo(); // Convenience method which sets up the current thread with everything it needs to do async I/O. // The returned objects contain an `EventLoop` which is wrapping an appropriate `EventPort` for // doing I/O on the host system, so everything is ready for the thread to start making async calls // and waiting on promises. // // You would typically call this in your main() loop or in the start function of a thread. // Example: // // int main() { // auto ioContext = kj::setupAsyncIo(); // // // Now we can call an async function. // Promise<String> textPromise = getHttp(*ioContext.provider, "http://example.com"); // // // And we can wait for the promise to complete. Note that you can only use `wait()` // // from the top level, not from inside a promise callback. // String text = textPromise.wait(ioContext.waitScope); // print(text); // return 0; // } // // WARNING: An AsyncIoContext can only be used in the thread and process that created it. In // particular, note that after a fork(), an AsyncIoContext created in the parent process will // not work correctly in the child, even if the parent ceases to use its copy. In particular // note that this means that server processes which daemonize themselves at startup must wait // until after daemonization to create an AsyncIoContext. // ======================================================================================= // Convenience adapters. class CapabilityStreamConnectionReceiver final: public ConnectionReceiver { // Trivial wrapper which allows an AsyncCapabilityStream to act as a ConnectionReceiver. accept() // calls receiveStream(). public: CapabilityStreamConnectionReceiver(AsyncCapabilityStream& inner) : inner(inner) {} Promise<Own<AsyncIoStream>> accept() override; uint getPort() override; Promise<AuthenticatedStream> acceptAuthenticated() override; // Always produces UnknownIdentity. Capability-based security patterns should not rely on // authenticating peers; the other end of the capability stream should only be given to // authorized parties in the first place. private: AsyncCapabilityStream& inner; }; class CapabilityStreamNetworkAddress final: public NetworkAddress { // Trivial wrapper which allows an AsyncCapabilityStream to act as a NetworkAddress. // // connect() is implemented by calling provider.newCapabilityPipe(), sending one end over the // original capability stream, and returning the other end. If `provider` is null, then the // global kj::newCapabilityPipe() will be used, but this ONLY works if `inner` itself is agnostic // to the type of streams it receives, e.g. because it was also created using // kj::NewCapabilityPipe(). // // listen().accept() is implemented by receiving new streams over the original stream. // // Note that clone() doesn't work (due to ownership issues) and toString() returns a static // string. public: CapabilityStreamNetworkAddress(kj::Maybe<AsyncIoProvider&> provider, AsyncCapabilityStream& inner) : provider(provider), inner(inner) {} Promise<Own<AsyncIoStream>> connect() override; Own<ConnectionReceiver> listen() override; Own<NetworkAddress> clone() override; String toString() override; Promise<AuthenticatedStream> connectAuthenticated() override; // Always produces UnknownIdentity. Capability-based security patterns should not rely on // authenticating peers; the other end of the capability stream should only be given to // authorized parties in the first place. private: kj::Maybe<AsyncIoProvider&> provider; AsyncCapabilityStream& inner; }; class FileInputStream: public AsyncInputStream { // InputStream that reads from a disk file -- and enables sendfile() optimization. // // Reads are performed synchronously -- no actual attempt is made to use asynchronous file I/O. // True asynchronous file I/O is complicated and is mostly unnecessary in the presence of // caching. Only certain niche programs can expect to benefit from it. For the rest, it's better // to use regular syrchronous disk I/O, so that's what this class does. // // The real purpose of this class, aside from general convenience, is to enable sendfile() // optimization. When you use this class's pumpTo() method, and the destination is a socket, // the system will detect this and optimize to sendfile(), so that the file data never needs to // be read into userspace. // // NOTE: As of this writing, sendfile() optimization is only implemented on Linux. public: FileInputStream(const ReadableFile& file, uint64_t offset = 0) : file(file), offset(offset) {} const ReadableFile& getUnderlyingFile() { return file; } uint64_t getOffset() { return offset; } void seek(uint64_t newOffset) { offset = newOffset; } Promise<size_t> tryRead(void* buffer, size_t minBytes, size_t maxBytes); Maybe<uint64_t> tryGetLength(); // (pumpTo() is not actually overridden here, but AsyncStreamFd's tryPumpFrom() will detect when // the source is a file.) private: const ReadableFile& file; uint64_t offset; }; class FileOutputStream: public AsyncOutputStream { // OutputStream that writes to a disk file. // // As with FileInputStream, calls are not actually async. Async would be even less useful here // because writes should usually land in cache anyway. // // sendfile() optimization does not apply when writing to a file, but on Linux, splice() can // be used to achieve a similar effect. // // NOTE: As of this writing, splice() optimization is not implemented. public: FileOutputStream(const File& file, uint64_t offset = 0) : file(file), offset(offset) {} const File& getUnderlyingFile() { return file; } uint64_t getOffset() { return offset; } void seek(uint64_t newOffset) { offset = newOffset; } Promise<void> write(const void* buffer, size_t size); Promise<void> write(ArrayPtr<const ArrayPtr<const byte>> pieces); Promise<void> whenWriteDisconnected(); private: const File& file; uint64_t offset; }; // ======================================================================================= // inline implementation details inline AncillaryMessage::AncillaryMessage( int level, int type, ArrayPtr<const byte> data) : level(level), type(type), data(data) {} inline int AncillaryMessage::getLevel() const { return level; } inline int AncillaryMessage::getType() const { return type; } template <typename T> inline Maybe<const T&> AncillaryMessage::as() const { if (data.size() >= sizeof(T)) { return *reinterpret_cast<const T*>(data.begin()); } else { return nullptr; } } template <typename T> inline ArrayPtr<const T> AncillaryMessage::asArray() const { return arrayPtr(reinterpret_cast<const T*>(data.begin()), data.size() / sizeof(T)); } class SecureNetworkWrapper { // Abstract interface for a class which implements a "secure" network as a wrapper around an // insecure one. "secure" means: // * Connections to a server will only succeed if it can be verified that the requested hostname // actually belongs to the responding server. // * No man-in-the-middle attacker can potentially see the bytes sent and received. // // The typical implementation uses TLS. The object in this case could be configured to use cerain // keys, certificates, etc. See kj/compat/tls.h for such an implementation. // // However, an implementation could use some other form of encryption, or might not need to use // encryption at all. For example, imagine a kj::Network that exists only on a single machine, // providing communications between various processes using unix sockets. Perhaps the "hostnames" // are actually PIDs in this case. An implementation of such a network could verify the other // side's identity using an `SCM_CREDENTIALS` auxiliary message, which cannot be forged. Once // verified, there is no need to encrypt since unix sockets cannot be intercepted. public: virtual kj::Promise<kj::Own<kj::AsyncIoStream>> wrapServer(kj::Own<kj::AsyncIoStream> stream) = 0; // Act as the server side of a connection. The given stream is already connected to a client, but // no authentication has occurred. The returned stream represents the secure transport once // established. virtual kj::Promise<kj::Own<kj::AsyncIoStream>> wrapClient( kj::Own<kj::AsyncIoStream> stream, kj::StringPtr expectedServerHostname) = 0; // Act as the client side of a connection. The given stream is already connecetd to a server, but // no authentication has occurred. This method will verify that the server actually is the given // hostname, then return the stream representing a secure transport to that server. virtual kj::Promise<kj::AuthenticatedStream> wrapServer(kj::AuthenticatedStream stream) = 0; virtual kj::Promise<kj::AuthenticatedStream> wrapClient( kj::AuthenticatedStream stream, kj::StringPtr expectedServerHostname) = 0; // Same as above, but implementing kj::AuthenticatedStream, which provides PeerIdentity objects // with more details about the peer. The SecureNetworkWrapper will provide its own implementation // of PeerIdentity with the specific details it is able to authenticate. virtual kj::Own<kj::ConnectionReceiver> wrapPort(kj::Own<kj::ConnectionReceiver> port) = 0; // Wrap a connection listener. This is equivalent to calling wrapServer() on every connection // received. virtual kj::Own<kj::NetworkAddress> wrapAddress( kj::Own<kj::NetworkAddress> address, kj::StringPtr expectedServerHostname) = 0; // Wrap a NetworkAddress. This is equivalent to calling `wrapClient()` on every connection // formed by calling `connect()` on the address. virtual kj::Own<kj::Network> wrapNetwork(kj::Network& network) = 0; // Wrap a whole `kj::Network`. This automatically wraps everything constructed using the network. // The network will only accept address strings that can be authenticated, and will automatically // authenticate servers against those addresses when connecting to them. }; } // namespace kj KJ_END_HEADER