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// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab ft=cpp
#pragma once
#include <exception>
#include <string>
#include <string_view>
#include <streambuf>
#include <istream>
#include <stdlib.h>
#include <system_error>
#include "include/types.h"
#include "rgw_common.h"
class RGWRestfulIO;
namespace rgw {
namespace io {
using Exception = std::system_error;
/* The minimal and simplest subset of methods that a client of RadosGW can be
* interacted with. */
class BasicClient {
protected:
virtual int init_env(CephContext *cct) = 0;
public:
virtual ~BasicClient() = default;
/* Initialize the BasicClient and inject CephContext. */
int init(CephContext *cct);
/* Return the RGWEnv describing the environment that a given request lives in.
* The method does not throw exceptions. */
virtual RGWEnv& get_env() noexcept = 0;
/* Complete request.
* On success returns number of bytes generated for a direct client of RadosGW.
* On failure throws rgw::io::Exception containing errno. */
virtual size_t complete_request() = 0;
}; /* rgw::io::Client */
class Accounter {
public:
virtual ~Accounter() = default;
/* Enable or disable the accounting of both sent and received data. Changing
* the state does not affect the counters. */
virtual void set_account(bool enabled) = 0;
/* Return number of bytes sent to a direct client of RadosGW (direct means
* eg. a web server instance in the case of using FastCGI front-end) when
* the accounting was enabled. */
virtual uint64_t get_bytes_sent() const = 0;
/* Return number of bytes received from a direct client of RadosGW (direct
* means eg. a web server instance in the case of using FastCGI front-end)
* when the accounting was enabled. */
virtual uint64_t get_bytes_received() const = 0;
}; /* rgw::io::Accounter */
/* Interface abstracting restful interactions with clients, usually through
* the HTTP protocol. The methods participating in the response generation
* process should be called in the specific order:
* 1. send_100_continue() - at most once,
* 2. send_status() - exactly once,
* 3. Any of:
* a. send_header(),
* b. send_content_length() XOR send_chunked_transfer_encoding()
* Please note that only one of those two methods must be called
at most once.
* 4. complete_header() - exactly once,
* 5. send_body()
* 6. complete_request() - exactly once.
* There are no restrictions on flush() - it may be called in any moment.
*
* Receiving data from a client isn't a subject to any further call order
* restrictions besides those imposed by BasicClient. That is, get_env()
* and recv_body can be mixed. */
class RestfulClient : public BasicClient {
template<typename T> friend class DecoratedRestfulClient;
public:
/* Generate the 100 Continue message.
* On success returns number of bytes generated for a direct client of RadosGW.
* On failure throws rgw::io::Exception containing errno. */
virtual size_t send_100_continue() = 0;
/* Generate the response's status part taking the HTTP status code as @status
* and its name pointed in @status_name.
* On success returns number of bytes generated for a direct client of RadosGW.
* On failure throws rgw::io::Exception containing errno. */
virtual size_t send_status(int status, const char *status_name) = 0;
/* Generate header. On success returns number of bytes generated for a direct
* client of RadosGW. On failure throws rgw::io::Exception containing errno.
*
* std::string_view is being used because of length it internally carries. */
virtual size_t send_header(const std::string_view& name,
const std::string_view& value) = 0;
/* Inform a client about a content length. Takes number of bytes as @len.
* On success returns number of bytes generated for a direct client of RadosGW.
* On failure throws rgw::io::Exception containing errno.
*
* CALL LIMITATIONS:
* - The method must be called EXACTLY ONCE.
* - The method is interchangeable with send_chunked_transfer_encoding(). */
virtual size_t send_content_length(uint64_t len) = 0;
/* Inform a client that the chunked transfer encoding will be used.
* On success returns number of bytes generated for a direct client of RadosGW.
* On failure throws rgw::io::Exception containing errno.
*
* CALL LIMITATIONS:
* - The method must be called EXACTLY ONCE.
* - The method is interchangeable with send_content_length(). */
virtual size_t send_chunked_transfer_encoding() {
/* This is a null implementation. We don't send anything here, even the HTTP
* header. The intended behaviour should be provided through a decorator or
* directly by a given front-end. */
return 0;
}
/* Generate completion (the CRLF sequence separating headers and body in
* the case of HTTP) of headers. On success returns number of generated bytes
* for a direct client of RadosGW. On failure throws rgw::io::Exception with
* errno. */
virtual size_t complete_header() = 0;
/* Receive no more than @max bytes from a request's body and store it in
* buffer pointed by @buf. On success returns number of bytes received from
* a direct client of RadosGW that has been stored in @buf. On failure throws
* rgw::io::Exception containing errno. */
virtual size_t recv_body(char* buf, size_t max) = 0;
/* Generate a part of response's body by taking exactly @len bytes from
* the buffer pointed by @buf. On success returns number of generated bytes
* of response's body. On failure throws rgw::io::Exception. */
virtual size_t send_body(const char* buf, size_t len) = 0;
/* Flushes all already generated data to a direct client of RadosGW.
* On failure throws rgw::io::Exception containing errno. */
virtual void flush() = 0;
} /* rgw::io::RestfulClient */;
/* Abstract decorator over any implementation of rgw::io::RestfulClient
* which could be provided both as a pointer-to-object or the object itself. */
template <typename DecorateeT>
class DecoratedRestfulClient : public RestfulClient {
template<typename T> friend class DecoratedRestfulClient;
friend RGWRestfulIO;
typedef typename std::remove_pointer<DecorateeT>::type DerefedDecorateeT;
static_assert(std::is_base_of<RestfulClient, DerefedDecorateeT>::value,
"DecorateeT must be a subclass of rgw::io::RestfulClient");
DecorateeT decoratee;
/* There is an indirection layer over accessing decoratee to share the same
* code base between dynamic and static decorators. The difference is about
* what we store internally: pointer to a decorated object versus the whole
* object itself. */
template <typename T = void,
typename std::enable_if<
! std::is_pointer<DecorateeT>::value, T>::type* = nullptr>
DerefedDecorateeT& get_decoratee() {
return decoratee;
}
protected:
template <typename T = void,
typename std::enable_if<
std::is_pointer<DecorateeT>::value, T>::type* = nullptr>
DerefedDecorateeT& get_decoratee() {
return *decoratee;
}
/* Dynamic decorators (those storing a pointer instead of the decorated
* object itself) can be reconfigured on-the-fly. HOWEVER: there are no
* facilities for orchestrating such changes. Callers must take care of
* atomicity and thread-safety. */
template <typename T = void,
typename std::enable_if<
std::is_pointer<DecorateeT>::value, T>::type* = nullptr>
void set_decoratee(DerefedDecorateeT& new_dec) {
decoratee = &new_dec;
}
int init_env(CephContext *cct) override {
return get_decoratee().init_env(cct);
}
public:
explicit DecoratedRestfulClient(DecorateeT&& decoratee)
: decoratee(std::forward<DecorateeT>(decoratee)) {
}
size_t send_status(const int status,
const char* const status_name) override {
return get_decoratee().send_status(status, status_name);
}
size_t send_100_continue() override {
return get_decoratee().send_100_continue();
}
size_t send_header(const std::string_view& name,
const std::string_view& value) override {
return get_decoratee().send_header(name, value);
}
size_t send_content_length(const uint64_t len) override {
return get_decoratee().send_content_length(len);
}
size_t send_chunked_transfer_encoding() override {
return get_decoratee().send_chunked_transfer_encoding();
}
size_t complete_header() override {
return get_decoratee().complete_header();
}
size_t recv_body(char* const buf, const size_t max) override {
return get_decoratee().recv_body(buf, max);
}
size_t send_body(const char* const buf,
const size_t len) override {
return get_decoratee().send_body(buf, len);
}
void flush() override {
return get_decoratee().flush();
}
RGWEnv& get_env() noexcept override {
return get_decoratee().get_env();
}
size_t complete_request() override {
return get_decoratee().complete_request();
}
} /* rgw::io::DecoratedRestfulClient */;
/* Interface that should be provided by a front-end class wanting to use
* the low-level buffering offered by i.e. StaticOutputBufferer. */
class BuffererSink {
public:
virtual ~BuffererSink() = default;
/* Send exactly @len bytes from the memory location pointed by @buf.
* On success returns @len. On failure throws rgw::io::Exception. */
virtual size_t write_data(const char *buf, size_t len) = 0;
};
/* Utility class providing RestfulClient's implementations with facilities
* for low-level buffering without relying on dynamic memory allocations.
* The buffer is carried entirely on stack. This narrows down applicability
* to these situations where buffers are relatively small. This perfectly
* fits the needs of composing an HTTP header. Without that a front-end
* might need to issue a lot of small IO operations leading to increased
* overhead on syscalls and fragmentation of a message if the Nagle's
* algorithm won't be able to form a single TCP segment (usually when
* running on extremely fast network interfaces like the loopback). */
template <size_t BufferSizeV = 4096>
class StaticOutputBufferer : public std::streambuf {
static_assert(BufferSizeV >= sizeof(std::streambuf::char_type),
"Buffer size must be bigger than a single char_type.");
using std::streambuf::int_type;
int_type overflow(const int_type c) override {
*pptr() = c;
pbump(sizeof(std::streambuf::char_type));
if (! sync()) {
/* No error, the buffer has been successfully synchronized. */
return c;
} else {
return std::streambuf::traits_type::eof();
}
}
int sync() override {
const auto len = static_cast<size_t>(std::streambuf::pptr() -
std::streambuf::pbase());
std::streambuf::pbump(-len);
sink.write_data(std::streambuf::pbase(), len);
/* Always return success here. In case of failure write_data() will throw
* rgw::io::Exception. */
return 0;
}
BuffererSink& sink;
std::streambuf::char_type buffer[BufferSizeV];
public:
explicit StaticOutputBufferer(BuffererSink& sink)
: sink(sink) {
constexpr size_t len = sizeof(buffer) - sizeof(std::streambuf::char_type);
std::streambuf::setp(buffer, buffer + len);
}
};
} /* namespace io */
} /* namespace rgw */
/* We're doing this nasty thing only because of extensive usage of templates
* to implement the static decorator pattern. C++ templates de facto enforce
* mixing interfaces with implementation. Additionally, those classes derive
* from RGWRestfulIO defined here. I believe that including in the middle of
* file is still better than polluting it directly. */
#include "rgw_client_io_filters.h"
/* RGWRestfulIO: high level interface to interact with RESTful clients. What
* differentiates it from rgw::io::RestfulClient is providing more specific APIs
* like rgw::io::Accounter or the AWS Auth v4 stuff implemented by filters
* while hiding the pipelined architecture from clients.
*
* rgw::io::Accounter came in as a part of rgw::io::AccountingFilter. */
class RGWRestfulIO : public rgw::io::AccountingFilter<rgw::io::RestfulClient*> {
std::vector<std::shared_ptr<DecoratedRestfulClient>> filters;
public:
~RGWRestfulIO() override = default;
RGWRestfulIO(CephContext *_cx, rgw::io::RestfulClient* engine)
: AccountingFilter<rgw::io::RestfulClient*>(_cx, std::move(engine)) {
}
void add_filter(std::shared_ptr<DecoratedRestfulClient> new_filter) {
new_filter->set_decoratee(this->get_decoratee());
this->set_decoratee(*new_filter);
filters.emplace_back(std::move(new_filter));
}
}; /* RGWRestfulIO */
/* Type conversions to work around lack of req_state type hierarchy matching
* (e.g.) REST backends (may be replaced w/dynamic typed req_state). */
static inline rgw::io::RestfulClient* RESTFUL_IO(req_state* s) {
ceph_assert(dynamic_cast<rgw::io::RestfulClient*>(s->cio) != nullptr);
return static_cast<rgw::io::RestfulClient*>(s->cio);
}
static inline rgw::io::Accounter* ACCOUNTING_IO(req_state* s) {
auto ptr = dynamic_cast<rgw::io::Accounter*>(s->cio);
ceph_assert(ptr != nullptr);
return ptr;
}
static inline RGWRestfulIO* AWS_AUTHv4_IO(const req_state* const s) {
ceph_assert(dynamic_cast<RGWRestfulIO*>(s->cio) != nullptr);
return static_cast<RGWRestfulIO*>(s->cio);
}
class RGWClientIOStreamBuf : public std::streambuf {
protected:
RGWRestfulIO &rio;
size_t const window_size;
size_t const putback_size;
std::vector<char> buffer;
public:
RGWClientIOStreamBuf(RGWRestfulIO &rio, size_t ws, size_t ps = 1)
: rio(rio),
window_size(ws),
putback_size(ps),
buffer(ws + ps)
{
setg(nullptr, nullptr, nullptr);
}
std::streambuf::int_type underflow() override {
if (gptr() < egptr()) {
return traits_type::to_int_type(*gptr());
}
char * const base = buffer.data();
char * start;
if (nullptr != eback()) {
/* We need to skip moving bytes on first underflow. In such case
* there is simply no previous data we should preserve for unget()
* or something similar. */
std::memmove(base, egptr() - putback_size, putback_size);
start = base + putback_size;
} else {
start = base;
}
size_t read_len = 0;
try {
read_len = rio.recv_body(base, window_size);
} catch (rgw::io::Exception&) {
return traits_type::eof();
}
if (0 == read_len) {
return traits_type::eof();
}
setg(base, start, start + read_len);
return traits_type::to_int_type(*gptr());
}
};
class RGWClientIOStream : private RGWClientIOStreamBuf, public std::istream {
/* Inheritance from RGWClientIOStreamBuf is a kind of shadow, undirect
* form of composition here. We cannot do that explicitly because istream
* ctor is being called prior to construction of any member of this class. */
public:
explicit RGWClientIOStream(RGWRestfulIO &s)
: RGWClientIOStreamBuf(s, 1, 2),
std::istream(static_cast<RGWClientIOStreamBuf *>(this)) {
}
};
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