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ramik_dev/include/crow_all.h
rami 639c8e8815 Updated blog
2024-06-15 15:15:13 -04:00

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/*BSD 3-Clause License
Copyright (c) 2014-2017, ipkn
2020-2022, CrowCpp
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright notice, this
list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright notice,
this list of conditions and the following disclaimer in the documentation
and/or other materials provided with the distribution.
* Neither the name of the author nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
The Crow logo and other graphic material (excluding third party logos) used are under exclusive Copyright (c) 2021-2022, Farook Al-Sammarraie (The-EDev), All rights reserved.
*/
#pragma once
// settings for crow
// TODO(ipkn) replace with runtime config. libucl?
/* #ifdef - enables debug mode */
//#define CROW_ENABLE_DEBUG
/* #ifdef - enables logging */
#define CROW_ENABLE_LOGGING
/* #ifdef - enables ssl */
//#define CROW_ENABLE_SSL
/* #ifdef - enforces section 5.2 and 6.1 of RFC6455 (only accepting masked messages from clients) */
//#define CROW_ENFORCE_WS_SPEC
/* #define - specifies log level */
/*
Debug = 0
Info = 1
Warning = 2
Error = 3
Critical = 4
default to INFO
*/
#ifndef CROW_LOG_LEVEL
#define CROW_LOG_LEVEL 1
#endif
#ifndef CROW_STATIC_DIRECTORY
#define CROW_STATIC_DIRECTORY "static/"
#endif
#ifndef CROW_STATIC_ENDPOINT
#define CROW_STATIC_ENDPOINT "/static/<path>"
#endif
// compiler flags
#if defined(_MSVC_LANG) && _MSVC_LANG >= 201402L
#define CROW_CAN_USE_CPP14
#endif
#if __cplusplus >= 201402L
#define CROW_CAN_USE_CPP14
#endif
#if defined(_MSVC_LANG) && _MSVC_LANG >= 201703L
#define CROW_CAN_USE_CPP17
#endif
#if __cplusplus >= 201703L
#define CROW_CAN_USE_CPP17
#endif
#if defined(_MSC_VER)
#if _MSC_VER < 1900
#define CROW_MSVC_WORKAROUND
#define constexpr const
#define noexcept throw()
#endif
#endif
#if defined(__GNUC__) && __GNUC__ == 8 && __GNUC_MINOR__ < 4
#if __cplusplus > 201103L
#define CROW_GCC83_WORKAROUND
#else
#error "GCC 8.1 - 8.3 has a bug that prevents Crow from compiling with C++11. Please update GCC to > 8.3 or use C++ > 11."
#endif
#endif
// This file is generated from nginx/conf/mime.types using nginx_mime2cpp.py on 2021-12-03.
#include <unordered_map>
#include <string>
namespace crow
{
const std::unordered_map<std::string, std::string> mime_types{
{"shtml", "text/html"},
{"htm", "text/html"},
{"html", "text/html"},
{"css", "text/css"},
{"xml", "text/xml"},
{"gif", "image/gif"},
{"jpg", "image/jpeg"},
{"jpeg", "image/jpeg"},
{"js", "application/javascript"},
{"atom", "application/atom+xml"},
{"rss", "application/rss+xml"},
{"mml", "text/mathml"},
{"txt", "text/plain"},
{"jad", "text/vnd.sun.j2me.app-descriptor"},
{"wml", "text/vnd.wap.wml"},
{"htc", "text/x-component"},
{"avif", "image/avif"},
{"png", "image/png"},
{"svgz", "image/svg+xml"},
{"svg", "image/svg+xml"},
{"tiff", "image/tiff"},
{"tif", "image/tiff"},
{"wbmp", "image/vnd.wap.wbmp"},
{"webp", "image/webp"},
{"ico", "image/x-icon"},
{"jng", "image/x-jng"},
{"bmp", "image/x-ms-bmp"},
{"woff", "font/woff"},
{"woff2", "font/woff2"},
{"ear", "application/java-archive"},
{"war", "application/java-archive"},
{"jar", "application/java-archive"},
{"json", "application/json"},
{"hqx", "application/mac-binhex40"},
{"doc", "application/msword"},
{"pdf", "application/pdf"},
{"ai", "application/postscript"},
{"eps", "application/postscript"},
{"ps", "application/postscript"},
{"rtf", "application/rtf"},
{"m3u8", "application/vnd.apple.mpegurl"},
{"kml", "application/vnd.google-earth.kml+xml"},
{"kmz", "application/vnd.google-earth.kmz"},
{"xls", "application/vnd.ms-excel"},
{"eot", "application/vnd.ms-fontobject"},
{"ppt", "application/vnd.ms-powerpoint"},
{"odg", "application/vnd.oasis.opendocument.graphics"},
{"odp", "application/vnd.oasis.opendocument.presentation"},
{"ods", "application/vnd.oasis.opendocument.spreadsheet"},
{"odt", "application/vnd.oasis.opendocument.text"},
{"pptx", "application/vnd.openxmlformats-officedocument.presentationml.presentation"},
{"xlsx", "application/vnd.openxmlformats-officedocument.spreadsheetml.sheet"},
{"docx", "application/vnd.openxmlformats-officedocument.wordprocessingml.document"},
{"wmlc", "application/vnd.wap.wmlc"},
{"wasm", "application/wasm"},
{"7z", "application/x-7z-compressed"},
{"cco", "application/x-cocoa"},
{"jardiff", "application/x-java-archive-diff"},
{"jnlp", "application/x-java-jnlp-file"},
{"run", "application/x-makeself"},
{"pm", "application/x-perl"},
{"pl", "application/x-perl"},
{"pdb", "application/x-pilot"},
{"prc", "application/x-pilot"},
{"rar", "application/x-rar-compressed"},
{"rpm", "application/x-redhat-package-manager"},
{"sea", "application/x-sea"},
{"swf", "application/x-shockwave-flash"},
{"sit", "application/x-stuffit"},
{"tk", "application/x-tcl"},
{"tcl", "application/x-tcl"},
{"crt", "application/x-x509-ca-cert"},
{"pem", "application/x-x509-ca-cert"},
{"der", "application/x-x509-ca-cert"},
{"xpi", "application/x-xpinstall"},
{"xhtml", "application/xhtml+xml"},
{"xspf", "application/xspf+xml"},
{"zip", "application/zip"},
{"dll", "application/octet-stream"},
{"exe", "application/octet-stream"},
{"bin", "application/octet-stream"},
{"deb", "application/octet-stream"},
{"dmg", "application/octet-stream"},
{"img", "application/octet-stream"},
{"iso", "application/octet-stream"},
{"msm", "application/octet-stream"},
{"msp", "application/octet-stream"},
{"msi", "application/octet-stream"},
{"kar", "audio/midi"},
{"midi", "audio/midi"},
{"mid", "audio/midi"},
{"mp3", "audio/mpeg"},
{"ogg", "audio/ogg"},
{"m4a", "audio/x-m4a"},
{"ra", "audio/x-realaudio"},
{"3gp", "video/3gpp"},
{"3gpp", "video/3gpp"},
{"ts", "video/mp2t"},
{"mp4", "video/mp4"},
{"mpg", "video/mpeg"},
{"mpeg", "video/mpeg"},
{"mov", "video/quicktime"},
{"webm", "video/webm"},
{"flv", "video/x-flv"},
{"m4v", "video/x-m4v"},
{"mng", "video/x-mng"},
{"asf", "video/x-ms-asf"},
{"asx", "video/x-ms-asf"},
{"wmv", "video/x-ms-wmv"},
{"avi", "video/x-msvideo"}};
}
#pragma once
#include <boost/algorithm/string/predicate.hpp>
#include <boost/functional/hash.hpp>
#include <unordered_map>
namespace crow
{
/// Hashing function for ci_map (unordered_multimap).
struct ci_hash
{
size_t operator()(const std::string& key) const
{
std::size_t seed = 0;
std::locale locale;
for (auto c : key)
{
boost::hash_combine(seed, std::toupper(c, locale));
}
return seed;
}
};
/// Equals function for ci_map (unordered_multimap).
struct ci_key_eq
{
bool operator()(const std::string& l, const std::string& r) const
{
return boost::iequals(l, r);
}
};
using ci_map = std::unordered_multimap<std::string, std::string, ci_hash, ci_key_eq>;
} // namespace crow
#pragma once
#include <string>
namespace crow
{
/// An abstract class that allows any other class to be returned by a handler.
struct returnable
{
std::string content_type;
virtual std::string dump() const = 0;
returnable(std::string ctype):
content_type{ctype}
{}
virtual ~returnable(){};
};
} // namespace crow
#pragma once
#include <cstdio>
#include <cstdlib>
#include <ctime>
#include <iostream>
#include <sstream>
#include <string>
namespace crow
{
enum class LogLevel
{
#ifndef ERROR
#ifndef DEBUG
DEBUG = 0,
INFO,
WARNING,
ERROR,
CRITICAL,
#endif
#endif
Debug = 0,
Info,
Warning,
Error,
Critical,
};
class ILogHandler
{
public:
virtual void log(std::string message, LogLevel level) = 0;
};
class CerrLogHandler : public ILogHandler
{
public:
void log(std::string message, LogLevel level) override
{
std::string prefix;
switch (level)
{
case LogLevel::Debug:
prefix = "DEBUG ";
break;
case LogLevel::Info:
prefix = "INFO ";
break;
case LogLevel::Warning:
prefix = "WARNING ";
break;
case LogLevel::Error:
prefix = "ERROR ";
break;
case LogLevel::Critical:
prefix = "CRITICAL";
break;
}
std::cerr << std::string("(") + timestamp() + std::string(") [") + prefix + std::string("] ") + message << std::endl;
}
private:
static std::string timestamp()
{
char date[32];
time_t t = time(0);
tm my_tm;
#if defined(_MSC_VER) || defined(__MINGW32__)
#ifdef CROW_USE_LOCALTIMEZONE
localtime_s(&my_tm, &t);
#else
gmtime_s(&my_tm, &t);
#endif
#else
#ifdef CROW_USE_LOCALTIMEZONE
localtime_r(&t, &my_tm);
#else
gmtime_r(&t, &my_tm);
#endif
#endif
size_t sz = strftime(date, sizeof(date), "%Y-%m-%d %H:%M:%S", &my_tm);
return std::string(date, date + sz);
}
};
class logger
{
public:
logger(LogLevel level):
level_(level)
{}
~logger()
{
#ifdef CROW_ENABLE_LOGGING
if (level_ >= get_current_log_level())
{
get_handler_ref()->log(stringstream_.str(), level_);
}
#endif
}
//
template<typename T>
logger& operator<<(T const& value)
{
#ifdef CROW_ENABLE_LOGGING
if (level_ >= get_current_log_level())
{
stringstream_ << value;
}
#endif
return *this;
}
//
static void setLogLevel(LogLevel level) { get_log_level_ref() = level; }
static void setHandler(ILogHandler* handler) { get_handler_ref() = handler; }
static LogLevel get_current_log_level() { return get_log_level_ref(); }
private:
//
static LogLevel& get_log_level_ref()
{
static LogLevel current_level = static_cast<LogLevel>(CROW_LOG_LEVEL);
return current_level;
}
static ILogHandler*& get_handler_ref()
{
static CerrLogHandler default_handler;
static ILogHandler* current_handler = &default_handler;
return current_handler;
}
//
std::ostringstream stringstream_;
LogLevel level_;
};
} // namespace crow
#define CROW_LOG_CRITICAL \
if (crow::logger::get_current_log_level() <= crow::LogLevel::Critical) \
crow::logger(crow::LogLevel::Critical)
#define CROW_LOG_ERROR \
if (crow::logger::get_current_log_level() <= crow::LogLevel::Error) \
crow::logger(crow::LogLevel::Error)
#define CROW_LOG_WARNING \
if (crow::logger::get_current_log_level() <= crow::LogLevel::Warning) \
crow::logger(crow::LogLevel::Warning)
#define CROW_LOG_INFO \
if (crow::logger::get_current_log_level() <= crow::LogLevel::Info) \
crow::logger(crow::LogLevel::Info)
#define CROW_LOG_DEBUG \
if (crow::logger::get_current_log_level() <= crow::LogLevel::Debug) \
crow::logger(crow::LogLevel::Debug)
#pragma once
namespace crow
{
constexpr const char VERSION[] = "1.0";
}
/*
*
* TinySHA1 - a header only implementation of the SHA1 algorithm in C++. Based
* on the implementation in boost::uuid::details.
*
* SHA1 Wikipedia Page: http://en.wikipedia.org/wiki/SHA-1
*
* Copyright (c) 2012-22 SAURAV MOHAPATRA <mohaps@gmail.com>
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#ifndef _TINY_SHA1_HPP_
#define _TINY_SHA1_HPP_
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <stdint.h>
namespace sha1
{
class SHA1
{
public:
typedef uint32_t digest32_t[5];
typedef uint8_t digest8_t[20];
inline static uint32_t LeftRotate(uint32_t value, size_t count) {
return (value << count) ^ (value >> (32-count));
}
SHA1(){ reset(); }
virtual ~SHA1() {}
SHA1(const SHA1& s) { *this = s; }
const SHA1& operator = (const SHA1& s) {
memcpy(m_digest, s.m_digest, 5 * sizeof(uint32_t));
memcpy(m_block, s.m_block, 64);
m_blockByteIndex = s.m_blockByteIndex;
m_byteCount = s.m_byteCount;
return *this;
}
SHA1& reset() {
m_digest[0] = 0x67452301;
m_digest[1] = 0xEFCDAB89;
m_digest[2] = 0x98BADCFE;
m_digest[3] = 0x10325476;
m_digest[4] = 0xC3D2E1F0;
m_blockByteIndex = 0;
m_byteCount = 0;
return *this;
}
SHA1& processByte(uint8_t octet) {
this->m_block[this->m_blockByteIndex++] = octet;
++this->m_byteCount;
if(m_blockByteIndex == 64) {
this->m_blockByteIndex = 0;
processBlock();
}
return *this;
}
SHA1& processBlock(const void* const start, const void* const end) {
const uint8_t* begin = static_cast<const uint8_t*>(start);
const uint8_t* finish = static_cast<const uint8_t*>(end);
while(begin != finish) {
processByte(*begin);
begin++;
}
return *this;
}
SHA1& processBytes(const void* const data, size_t len) {
const uint8_t* block = static_cast<const uint8_t*>(data);
processBlock(block, block + len);
return *this;
}
const uint32_t* getDigest(digest32_t digest) {
size_t bitCount = this->m_byteCount * 8;
processByte(0x80);
if (this->m_blockByteIndex > 56) {
while (m_blockByteIndex != 0) {
processByte(0);
}
while (m_blockByteIndex < 56) {
processByte(0);
}
} else {
while (m_blockByteIndex < 56) {
processByte(0);
}
}
processByte(0);
processByte(0);
processByte(0);
processByte(0);
processByte( static_cast<unsigned char>((bitCount>>24) & 0xFF));
processByte( static_cast<unsigned char>((bitCount>>16) & 0xFF));
processByte( static_cast<unsigned char>((bitCount>>8 ) & 0xFF));
processByte( static_cast<unsigned char>((bitCount) & 0xFF));
memcpy(digest, m_digest, 5 * sizeof(uint32_t));
return digest;
}
const uint8_t* getDigestBytes(digest8_t digest) {
digest32_t d32;
getDigest(d32);
size_t di = 0;
digest[di++] = ((d32[0] >> 24) & 0xFF);
digest[di++] = ((d32[0] >> 16) & 0xFF);
digest[di++] = ((d32[0] >> 8) & 0xFF);
digest[di++] = ((d32[0]) & 0xFF);
digest[di++] = ((d32[1] >> 24) & 0xFF);
digest[di++] = ((d32[1] >> 16) & 0xFF);
digest[di++] = ((d32[1] >> 8) & 0xFF);
digest[di++] = ((d32[1]) & 0xFF);
digest[di++] = ((d32[2] >> 24) & 0xFF);
digest[di++] = ((d32[2] >> 16) & 0xFF);
digest[di++] = ((d32[2] >> 8) & 0xFF);
digest[di++] = ((d32[2]) & 0xFF);
digest[di++] = ((d32[3] >> 24) & 0xFF);
digest[di++] = ((d32[3] >> 16) & 0xFF);
digest[di++] = ((d32[3] >> 8) & 0xFF);
digest[di++] = ((d32[3]) & 0xFF);
digest[di++] = ((d32[4] >> 24) & 0xFF);
digest[di++] = ((d32[4] >> 16) & 0xFF);
digest[di++] = ((d32[4] >> 8) & 0xFF);
digest[di++] = ((d32[4]) & 0xFF);
return digest;
}
protected:
void processBlock() {
uint32_t w[80];
for (size_t i = 0; i < 16; i++) {
w[i] = (m_block[i*4 + 0] << 24);
w[i] |= (m_block[i*4 + 1] << 16);
w[i] |= (m_block[i*4 + 2] << 8);
w[i] |= (m_block[i*4 + 3]);
}
for (size_t i = 16; i < 80; i++) {
w[i] = LeftRotate((w[i-3] ^ w[i-8] ^ w[i-14] ^ w[i-16]), 1);
}
uint32_t a = m_digest[0];
uint32_t b = m_digest[1];
uint32_t c = m_digest[2];
uint32_t d = m_digest[3];
uint32_t e = m_digest[4];
for (std::size_t i=0; i<80; ++i) {
uint32_t f = 0;
uint32_t k = 0;
if (i<20) {
f = (b & c) | (~b & d);
k = 0x5A827999;
} else if (i<40) {
f = b ^ c ^ d;
k = 0x6ED9EBA1;
} else if (i<60) {
f = (b & c) | (b & d) | (c & d);
k = 0x8F1BBCDC;
} else {
f = b ^ c ^ d;
k = 0xCA62C1D6;
}
uint32_t temp = LeftRotate(a, 5) + f + e + k + w[i];
e = d;
d = c;
c = LeftRotate(b, 30);
b = a;
a = temp;
}
m_digest[0] += a;
m_digest[1] += b;
m_digest[2] += c;
m_digest[3] += d;
m_digest[4] += e;
}
private:
digest32_t m_digest;
uint8_t m_block[64];
size_t m_blockByteIndex;
size_t m_byteCount;
};
}
#endif
#pragma once
#include <stdio.h>
#include <string.h>
#include <string>
#include <vector>
#include <unordered_map>
#include <iostream>
#include <boost/optional.hpp>
namespace crow
{
// ----------------------------------------------------------------------------
// qs_parse (modified)
// https://github.com/bartgrantham/qs_parse
// ----------------------------------------------------------------------------
/* Similar to strncmp, but handles URL-encoding for either string */
int qs_strncmp(const char * s, const char * qs, size_t n);
/* Finds the beginning of each key/value pair and stores a pointer in qs_kv.
* Also decodes the value portion of the k/v pair *in-place*. In a future
* enhancement it will also have a compile-time option of sorting qs_kv
* alphabetically by key. */
int qs_parse(char * qs, char * qs_kv[], int qs_kv_size);
/* Used by qs_parse to decode the value portion of a k/v pair */
int qs_decode(char * qs);
/* Looks up the value according to the key on a pre-processed query string
* A future enhancement will be a compile-time option to look up the key
* in a pre-sorted qs_kv array via a binary search. */
//char * qs_k2v(const char * key, char * qs_kv[], int qs_kv_size);
char * qs_k2v(const char * key, char * const * qs_kv, int qs_kv_size, int nth);
/* Non-destructive lookup of value, based on key. User provides the
* destinaton string and length. */
char * qs_scanvalue(const char * key, const char * qs, char * val, size_t val_len);
// TODO: implement sorting of the qs_kv array; for now ensure it's not compiled
#undef _qsSORTING
// isxdigit _is_ available in <ctype.h>, but let's avoid another header instead
#define CROW_QS_ISHEX(x) ((((x)>='0'&&(x)<='9') || ((x)>='A'&&(x)<='F') || ((x)>='a'&&(x)<='f')) ? 1 : 0)
#define CROW_QS_HEX2DEC(x) (((x)>='0'&&(x)<='9') ? (x)-48 : ((x)>='A'&&(x)<='F') ? (x)-55 : ((x)>='a'&&(x)<='f') ? (x)-87 : 0)
#define CROW_QS_ISQSCHR(x) ((((x)=='=')||((x)=='#')||((x)=='&')||((x)=='\0')) ? 0 : 1)
inline int qs_strncmp(const char * s, const char * qs, size_t n)
{
int i=0;
unsigned char u1, u2, unyb, lnyb;
while(n-- > 0)
{
u1 = static_cast<unsigned char>(*s++);
u2 = static_cast<unsigned char>(*qs++);
if ( ! CROW_QS_ISQSCHR(u1) ) { u1 = '\0'; }
if ( ! CROW_QS_ISQSCHR(u2) ) { u2 = '\0'; }
if ( u1 == '+' ) { u1 = ' '; }
if ( u1 == '%' ) // easier/safer than scanf
{
unyb = static_cast<unsigned char>(*s++);
lnyb = static_cast<unsigned char>(*s++);
if ( CROW_QS_ISHEX(unyb) && CROW_QS_ISHEX(lnyb) )
u1 = (CROW_QS_HEX2DEC(unyb) * 16) + CROW_QS_HEX2DEC(lnyb);
else
u1 = '\0';
}
if ( u2 == '+' ) { u2 = ' '; }
if ( u2 == '%' ) // easier/safer than scanf
{
unyb = static_cast<unsigned char>(*qs++);
lnyb = static_cast<unsigned char>(*qs++);
if ( CROW_QS_ISHEX(unyb) && CROW_QS_ISHEX(lnyb) )
u2 = (CROW_QS_HEX2DEC(unyb) * 16) + CROW_QS_HEX2DEC(lnyb);
else
u2 = '\0';
}
if ( u1 != u2 )
return u1 - u2;
if ( u1 == '\0' )
return 0;
i++;
}
if ( CROW_QS_ISQSCHR(*qs) )
return -1;
else
return 0;
}
inline int qs_parse(char * qs, char * qs_kv[], int qs_kv_size)
{
int i, j;
char * substr_ptr;
for(i=0; i<qs_kv_size; i++) qs_kv[i] = NULL;
// find the beginning of the k/v substrings or the fragment
substr_ptr = qs + strcspn(qs, "?#");
if (substr_ptr[0] != '\0')
substr_ptr++;
else
return 0; // no query or fragment
i=0;
while(i<qs_kv_size)
{
qs_kv[i] = substr_ptr;
j = strcspn(substr_ptr, "&");
if ( substr_ptr[j] == '\0' ) { i++; break; } // x &'s -> means x iterations of this loop -> means *x+1* k/v pairs
substr_ptr += j + 1;
i++;
}
// we only decode the values in place, the keys could have '='s in them
// which will hose our ability to distinguish keys from values later
for(j=0; j<i; j++)
{
substr_ptr = qs_kv[j] + strcspn(qs_kv[j], "=&#");
if ( substr_ptr[0] == '&' || substr_ptr[0] == '\0') // blank value: skip decoding
substr_ptr[0] = '\0';
else
qs_decode(++substr_ptr);
}
#ifdef _qsSORTING
// TODO: qsort qs_kv, using qs_strncmp() for the comparison
#endif
return i;
}
inline int qs_decode(char * qs)
{
int i=0, j=0;
while( CROW_QS_ISQSCHR(qs[j]) )
{
if ( qs[j] == '+' ) { qs[i] = ' '; }
else if ( qs[j] == '%' ) // easier/safer than scanf
{
if ( ! CROW_QS_ISHEX(qs[j+1]) || ! CROW_QS_ISHEX(qs[j+2]) )
{
qs[i] = '\0';
return i;
}
qs[i] = (CROW_QS_HEX2DEC(qs[j+1]) * 16) + CROW_QS_HEX2DEC(qs[j+2]);
j+=2;
}
else
{
qs[i] = qs[j];
}
i++; j++;
}
qs[i] = '\0';
return i;
}
inline char * qs_k2v(const char * key, char * const * qs_kv, int qs_kv_size, int nth = 0)
{
int i;
size_t key_len, skip;
key_len = strlen(key);
#ifdef _qsSORTING
// TODO: binary search for key in the sorted qs_kv
#else // _qsSORTING
for(i=0; i<qs_kv_size; i++)
{
// we rely on the unambiguous '=' to find the value in our k/v pair
if ( qs_strncmp(key, qs_kv[i], key_len) == 0 )
{
skip = strcspn(qs_kv[i], "=");
if ( qs_kv[i][skip] == '=' )
skip++;
// return (zero-char value) ? ptr to trailing '\0' : ptr to value
if(nth == 0)
return qs_kv[i] + skip;
else
--nth;
}
}
#endif // _qsSORTING
return nullptr;
}
inline boost::optional<std::pair<std::string, std::string>> qs_dict_name2kv(const char * dict_name, char * const * qs_kv, int qs_kv_size, int nth = 0)
{
int i;
size_t name_len, skip_to_eq, skip_to_brace_open, skip_to_brace_close;
name_len = strlen(dict_name);
#ifdef _qsSORTING
// TODO: binary search for key in the sorted qs_kv
#else // _qsSORTING
for(i=0; i<qs_kv_size; i++)
{
if ( strncmp(dict_name, qs_kv[i], name_len) == 0 )
{
skip_to_eq = strcspn(qs_kv[i], "=");
if ( qs_kv[i][skip_to_eq] == '=' )
skip_to_eq++;
skip_to_brace_open = strcspn(qs_kv[i], "[");
if ( qs_kv[i][skip_to_brace_open] == '[' )
skip_to_brace_open++;
skip_to_brace_close = strcspn(qs_kv[i], "]");
if ( skip_to_brace_open <= skip_to_brace_close &&
skip_to_brace_open > 0 &&
skip_to_brace_close > 0 &&
nth == 0 )
{
auto key = std::string(qs_kv[i] + skip_to_brace_open, skip_to_brace_close - skip_to_brace_open);
auto value = std::string(qs_kv[i] + skip_to_eq);
return boost::make_optional(std::make_pair(key, value));
}
else
{
--nth;
}
}
}
#endif // _qsSORTING
return boost::none;
}
inline char * qs_scanvalue(const char * key, const char * qs, char * val, size_t val_len)
{
size_t i, key_len;
const char * tmp;
// find the beginning of the k/v substrings
if ( (tmp = strchr(qs, '?')) != NULL )
qs = tmp + 1;
key_len = strlen(key);
while(qs[0] != '#' && qs[0] != '\0')
{
if ( qs_strncmp(key, qs, key_len) == 0 )
break;
qs += strcspn(qs, "&") + 1;
}
if ( qs[0] == '\0' ) return NULL;
qs += strcspn(qs, "=&#");
if ( qs[0] == '=' )
{
qs++;
i = strcspn(qs, "&=#");
#ifdef _MSC_VER
strncpy_s(val, val_len, qs, (val_len - 1)<(i + 1) ? (val_len - 1) : (i + 1));
#else
strncpy(val, qs, (val_len - 1)<(i + 1) ? (val_len - 1) : (i + 1));
#endif
qs_decode(val);
}
else
{
if ( val_len > 0 )
val[0] = '\0';
}
return val;
}
}
// ----------------------------------------------------------------------------
namespace crow
{
/// A class to represent any data coming after the `?` in the request URL into key-value pairs.
class query_string
{
public:
static const int MAX_KEY_VALUE_PAIRS_COUNT = 256;
query_string()
{
}
query_string(const query_string& qs)
: url_(qs.url_)
{
for(auto p:qs.key_value_pairs_)
{
key_value_pairs_.push_back((char*)(p-qs.url_.c_str()+url_.c_str()));
}
}
query_string& operator = (const query_string& qs)
{
url_ = qs.url_;
key_value_pairs_.clear();
for(auto p:qs.key_value_pairs_)
{
key_value_pairs_.push_back((char*)(p-qs.url_.c_str()+url_.c_str()));
}
return *this;
}
query_string& operator = (query_string&& qs)
{
key_value_pairs_ = std::move(qs.key_value_pairs_);
char* old_data = (char*)qs.url_.c_str();
url_ = std::move(qs.url_);
for(auto& p:key_value_pairs_)
{
p += (char*)url_.c_str() - old_data;
}
return *this;
}
query_string(std::string url)
: url_(std::move(url))
{
if (url_.empty())
return;
key_value_pairs_.resize(MAX_KEY_VALUE_PAIRS_COUNT);
int count = qs_parse(&url_[0], &key_value_pairs_[0], MAX_KEY_VALUE_PAIRS_COUNT);
key_value_pairs_.resize(count);
}
void clear()
{
key_value_pairs_.clear();
url_.clear();
}
friend std::ostream& operator<<(std::ostream& os, const query_string& qs)
{
os << "[ ";
for(size_t i = 0; i < qs.key_value_pairs_.size(); ++i) {
if (i)
os << ", ";
os << qs.key_value_pairs_[i];
}
os << " ]";
return os;
}
/// Get a value from a name, used for `?name=value`.
///
/// Note: this method returns the value of the first occurrence of the key only, to return all occurrences, see \ref get_list().
char* get (const std::string& name) const
{
char* ret = qs_k2v(name.c_str(), key_value_pairs_.data(), key_value_pairs_.size());
return ret;
}
/// Works similar to \ref get() except it removes the item from the query string.
char* pop (const std::string& name)
{
char* ret = get(name);
if (ret != nullptr)
{
for (unsigned int i = 0; i<key_value_pairs_.size(); i++)
{
std::string str_item(key_value_pairs_[i]);
if (str_item.substr(0, name.size()+1) == name+'=')
{
key_value_pairs_.erase(key_value_pairs_.begin()+i);
break;
}
}
}
return ret;
}
/// Returns a list of values, passed as `?name[]=value1&name[]=value2&...name[]=valuen` with n being the size of the list.
///
/// Note: Square brackets in the above example are controlled by `use_brackets` boolean (true by default). If set to false, the example becomes `?name=value1,name=value2...name=valuen`
std::vector<char*> get_list (const std::string& name, bool use_brackets = true) const
{
std::vector<char*> ret;
std::string plus = name + (use_brackets ? "[]" : "");
char* element = nullptr;
int count = 0;
while(1)
{
element = qs_k2v(plus.c_str(), key_value_pairs_.data(), key_value_pairs_.size(), count++);
if (!element)
break;
ret.push_back(element);
}
return ret;
}
/// Similar to \ref get_list() but it removes the
std::vector<char*> pop_list (const std::string& name, bool use_brackets = true)
{
std::vector<char*> ret = get_list(name, use_brackets);
if (!ret.empty())
{
for (unsigned int i = 0; i<key_value_pairs_.size(); i++)
{
std::string str_item(key_value_pairs_[i]);
if ((use_brackets ? (str_item.substr(0, name.size()+3) == name+"[]=") : (str_item.substr(0, name.size()+1) == name+'=')))
{
key_value_pairs_.erase(key_value_pairs_.begin()+i--);
}
}
}
return ret;
}
/// Works similar to \ref get_list() except the brackets are mandatory must not be empty.
///
/// For example calling `get_dict(yourname)` on `?yourname[sub1]=42&yourname[sub2]=84` would give a map containing `{sub1 : 42, sub2 : 84}`.
///
/// if your query string has both empty brackets and ones with a key inside, use pop_list() to get all the values without a key before running this method.
std::unordered_map<std::string, std::string> get_dict (const std::string& name) const
{
std::unordered_map<std::string, std::string> ret;
int count = 0;
while(1)
{
if (auto element = qs_dict_name2kv(name.c_str(), key_value_pairs_.data(), key_value_pairs_.size(), count++))
ret.insert(*element);
else
break;
}
return ret;
}
/// Works the same as \ref get_dict() but removes the values from the query string.
std::unordered_map<std::string, std::string> pop_dict (const std::string& name)
{
std::unordered_map<std::string, std::string> ret = get_dict(name);
if (!ret.empty())
{
for (unsigned int i = 0; i<key_value_pairs_.size(); i++)
{
std::string str_item(key_value_pairs_[i]);
if (str_item.substr(0, name.size()+1) == name+'[')
{
key_value_pairs_.erase(key_value_pairs_.begin()+i--);
}
}
}
return ret;
}
std::vector<std::string> keys() const
{
std::vector<std::string> ret;
for (auto element: key_value_pairs_)
{
std::string str_element(element);
ret.emplace_back(str_element.substr(0, str_element.find('=')));
}
return ret;
}
private:
std::string url_;
std::vector<char*> key_value_pairs_;
};
} // end namespace
#pragma once
#include <boost/asio.hpp>
#include <chrono>
#include <functional>
#include <map>
#include <vector>
namespace crow
{
namespace detail
{
/// A class for scheduling functions to be called after a specific amount of ticks. A tick is equal to 1 second.
class task_timer
{
public:
using task_type = std::function<void()>;
using identifier_type = size_t;
private:
using clock_type = std::chrono::steady_clock;
using time_type = clock_type::time_point;
public:
task_timer(boost::asio::io_service& io_service):
io_service_(io_service), deadline_timer_(io_service_)
{
deadline_timer_.expires_from_now(boost::posix_time::seconds(1));
deadline_timer_.async_wait(
std::bind(&task_timer::tick_handler, this, std::placeholders::_1));
}
~task_timer() { deadline_timer_.cancel(); }
void cancel(identifier_type id)
{
tasks_.erase(id);
CROW_LOG_DEBUG << "task_timer cancelled: " << this << ' ' << id;
}
/// Schedule the given task to be executed after the default amount of ticks.
///
/// \return identifier_type Used to cancel the thread.
/// It is not bound to this task_timer instance and in some cases could lead to
/// undefined behavior if used with other task_timer objects or after the task
/// has been successfully executed.
identifier_type schedule(const task_type& task)
{
tasks_.insert(
{++highest_id_,
{clock_type::now() + std::chrono::seconds(get_default_timeout()),
task}});
CROW_LOG_DEBUG << "task_timer scheduled: " << this << ' ' << highest_id_;
return highest_id_;
}
/// Schedule the given task to be executed after the given time.
///
/// \param timeout The amount of ticks (seconds) to wait before execution.
///
/// \return identifier_type Used to cancel the thread.
/// It is not bound to this task_timer instance and in some cases could lead to
/// undefined behavior if used with other task_timer objects or after the task
/// has been successfully executed.
identifier_type schedule(const task_type& task, std::uint8_t timeout)
{
tasks_.insert({++highest_id_,
{clock_type::now() + std::chrono::seconds(timeout), task}});
CROW_LOG_DEBUG << "task_timer scheduled: " << this << ' ' << highest_id_;
return highest_id_;
}
/// Set the default timeout for this task_timer instance. (Default: 5)
///
/// \param timeout The amount of ticks (seconds) to wait before execution.
void set_default_timeout(std::uint8_t timeout) { default_timeout_ = timeout; }
/// Get the default timeout. (Default: 5)
std::uint8_t get_default_timeout() const { return default_timeout_; }
private:
void process_tasks()
{
time_type current_time = clock_type::now();
std::vector<identifier_type> finished_tasks;
for (const auto& task : tasks_)
{
if (task.second.first < current_time)
{
(task.second.second)();
finished_tasks.push_back(task.first);
CROW_LOG_DEBUG << "task_timer called: " << this << ' ' << task.first;
}
}
for (const auto& task : finished_tasks)
tasks_.erase(task);
// If no task is currently scheduled, reset the issued ids back to 0.
if (tasks_.empty()) highest_id_ = 0;
}
void tick_handler(const boost::system::error_code& ec)
{
if (ec) return;
process_tasks();
deadline_timer_.expires_from_now(boost::posix_time::seconds(1));
deadline_timer_.async_wait(
std::bind(&task_timer::tick_handler, this, std::placeholders::_1));
}
private:
std::uint8_t default_timeout_{5};
boost::asio::io_service& io_service_;
boost::asio::deadline_timer deadline_timer_;
std::map<identifier_type, std::pair<time_type, task_type>> tasks_;
// A continuosly increasing number to be issued to threads to identify them.
// If no tasks are scheduled, it will be reset to 0.
identifier_type highest_id_{0};
};
} // namespace detail
} // namespace crow
#pragma once
#include <boost/asio.hpp>
#ifdef CROW_ENABLE_SSL
#include <boost/asio/ssl.hpp>
#endif
#if BOOST_VERSION >= 107000
#define GET_IO_SERVICE(s) ((boost::asio::io_context&)(s).get_executor().context())
#else
#define GET_IO_SERVICE(s) ((s).get_io_service())
#endif
namespace crow
{
using namespace boost;
using tcp = asio::ip::tcp;
/// A wrapper for the asio::ip::tcp::socket and asio::ssl::stream
struct SocketAdaptor
{
using context = void;
SocketAdaptor(boost::asio::io_service& io_service, context*):
socket_(io_service)
{}
boost::asio::io_service& get_io_service()
{
return GET_IO_SERVICE(socket_);
}
/// Get the TCP socket handling data trasfers, regardless of what layer is handling transfers on top of the socket.
tcp::socket& raw_socket()
{
return socket_;
}
/// Get the object handling data transfers, this can be either a TCP socket or an SSL stream (if SSL is enabled).
tcp::socket& socket()
{
return socket_;
}
tcp::endpoint remote_endpoint()
{
return socket_.remote_endpoint();
}
bool is_open()
{
return socket_.is_open();
}
void close()
{
boost::system::error_code ec;
socket_.close(ec);
}
void shutdown_readwrite()
{
boost::system::error_code ec;
socket_.shutdown(boost::asio::socket_base::shutdown_type::shutdown_both, ec);
}
void shutdown_write()
{
boost::system::error_code ec;
socket_.shutdown(boost::asio::socket_base::shutdown_type::shutdown_send, ec);
}
void shutdown_read()
{
boost::system::error_code ec;
socket_.shutdown(boost::asio::socket_base::shutdown_type::shutdown_receive, ec);
}
template<typename F>
void start(F f)
{
f(boost::system::error_code());
}
tcp::socket socket_;
};
#ifdef CROW_ENABLE_SSL
struct SSLAdaptor
{
using context = boost::asio::ssl::context;
using ssl_socket_t = boost::asio::ssl::stream<tcp::socket>;
SSLAdaptor(boost::asio::io_service& io_service, context* ctx):
ssl_socket_(new ssl_socket_t(io_service, *ctx))
{}
boost::asio::ssl::stream<tcp::socket>& socket()
{
return *ssl_socket_;
}
tcp::socket::lowest_layer_type&
raw_socket()
{
return ssl_socket_->lowest_layer();
}
tcp::endpoint remote_endpoint()
{
return raw_socket().remote_endpoint();
}
bool is_open()
{
return ssl_socket_ ? raw_socket().is_open() : false;
}
void close()
{
if (is_open())
{
boost::system::error_code ec;
raw_socket().close(ec);
}
}
void shutdown_readwrite()
{
if (is_open())
{
boost::system::error_code ec;
raw_socket().shutdown(boost::asio::socket_base::shutdown_type::shutdown_both, ec);
}
}
void shutdown_write()
{
if (is_open())
{
boost::system::error_code ec;
raw_socket().shutdown(boost::asio::socket_base::shutdown_type::shutdown_send, ec);
}
}
void shutdown_read()
{
if (is_open())
{
boost::system::error_code ec;
raw_socket().shutdown(boost::asio::socket_base::shutdown_type::shutdown_receive, ec);
}
}
boost::asio::io_service& get_io_service()
{
return GET_IO_SERVICE(raw_socket());
}
template<typename F>
void start(F f)
{
ssl_socket_->async_handshake(boost::asio::ssl::stream_base::server,
[f](const boost::system::error_code& ec) {
f(ec);
});
}
std::unique_ptr<boost::asio::ssl::stream<tcp::socket>> ssl_socket_;
};
#endif
} // namespace crow
#pragma once
#include <cstdint>
#include <stdexcept>
#include <tuple>
#include <type_traits>
#include <cstring>
#include <functional>
#include <string>
#include <unordered_map>
// TODO(EDev): Adding C++20's [[likely]] and [[unlikely]] attributes might be useful
#if defined(__GNUG__) || defined(__clang__)
#define CROW_LIKELY(X) __builtin_expect(!!(X), 1)
#define CROW_UNLIKELY(X) __builtin_expect(!!(X), 0)
#else
#define CROW_LIKELY(X) (X)
#define CROW_UNLIKELY(X) (X)
#endif
namespace crow
{
/// @cond SKIP
namespace black_magic
{
#ifndef CROW_MSVC_WORKAROUND
/// Out of Range Exception for const_str
struct OutOfRange
{
OutOfRange(unsigned /*pos*/, unsigned /*length*/) {}
};
/// Helper function to throw an exception if i is larger than len
constexpr unsigned requires_in_range(unsigned i, unsigned len)
{
return i >= len ? throw OutOfRange(i, len) : i;
}
/// A constant string implementation.
class const_str
{
const char* const begin_;
unsigned size_;
public:
template<unsigned N>
constexpr const_str(const char (&arr)[N]):
begin_(arr), size_(N - 1)
{
static_assert(N >= 1, "not a string literal");
}
constexpr char operator[](unsigned i) const
{
return requires_in_range(i, size_), begin_[i];
}
constexpr operator const char*() const
{
return begin_;
}
constexpr const char* begin() const { return begin_; }
constexpr const char* end() const { return begin_ + size_; }
constexpr unsigned size() const
{
return size_;
}
};
constexpr unsigned find_closing_tag(const_str s, unsigned p)
{
return s[p] == '>' ? p : find_closing_tag(s, p + 1);
}
/// Check that the CROW_ROUTE string is valid
constexpr bool is_valid(const_str s, unsigned i = 0, int f = 0)
{
return i == s.size() ? f == 0 :
f < 0 || f >= 2 ? false :
s[i] == '<' ? is_valid(s, i + 1, f + 1) :
s[i] == '>' ? is_valid(s, i + 1, f - 1) :
is_valid(s, i + 1, f);
}
constexpr bool is_equ_p(const char* a, const char* b, unsigned n)
{
return *a == 0 && *b == 0 && n == 0 ? true :
(*a == 0 || *b == 0) ? false :
n == 0 ? true :
*a != *b ? false :
is_equ_p(a + 1, b + 1, n - 1);
}
constexpr bool is_equ_n(const_str a, unsigned ai, const_str b, unsigned bi, unsigned n)
{
return ai + n > a.size() || bi + n > b.size() ? false :
n == 0 ? true :
a[ai] != b[bi] ? false :
is_equ_n(a, ai + 1, b, bi + 1, n - 1);
}
constexpr bool is_int(const_str s, unsigned i)
{
return is_equ_n(s, i, "<int>", 0, 5);
}
constexpr bool is_uint(const_str s, unsigned i)
{
return is_equ_n(s, i, "<uint>", 0, 6);
}
constexpr bool is_float(const_str s, unsigned i)
{
return is_equ_n(s, i, "<float>", 0, 7) ||
is_equ_n(s, i, "<double>", 0, 8);
}
constexpr bool is_str(const_str s, unsigned i)
{
return is_equ_n(s, i, "<str>", 0, 5) ||
is_equ_n(s, i, "<string>", 0, 8);
}
constexpr bool is_path(const_str s, unsigned i)
{
return is_equ_n(s, i, "<path>", 0, 6);
}
#endif
template<typename T>
struct parameter_tag
{
static const int value = 0;
};
#define CROW_INTERNAL_PARAMETER_TAG(t, i) \
template<> \
struct parameter_tag<t> \
{ \
static const int value = i; \
}
CROW_INTERNAL_PARAMETER_TAG(int, 1);
CROW_INTERNAL_PARAMETER_TAG(char, 1);
CROW_INTERNAL_PARAMETER_TAG(short, 1);
CROW_INTERNAL_PARAMETER_TAG(long, 1);
CROW_INTERNAL_PARAMETER_TAG(long long, 1);
CROW_INTERNAL_PARAMETER_TAG(unsigned int, 2);
CROW_INTERNAL_PARAMETER_TAG(unsigned char, 2);
CROW_INTERNAL_PARAMETER_TAG(unsigned short, 2);
CROW_INTERNAL_PARAMETER_TAG(unsigned long, 2);
CROW_INTERNAL_PARAMETER_TAG(unsigned long long, 2);
CROW_INTERNAL_PARAMETER_TAG(double, 3);
CROW_INTERNAL_PARAMETER_TAG(std::string, 4);
#undef CROW_INTERNAL_PARAMETER_TAG
template<typename... Args>
struct compute_parameter_tag_from_args_list;
template<>
struct compute_parameter_tag_from_args_list<>
{
static const int value = 0;
};
template<typename Arg, typename... Args>
struct compute_parameter_tag_from_args_list<Arg, Args...>
{
static const int sub_value =
compute_parameter_tag_from_args_list<Args...>::value;
static const int value =
parameter_tag<typename std::decay<Arg>::type>::value ? sub_value * 6 + parameter_tag<typename std::decay<Arg>::type>::value : sub_value;
};
static inline bool is_parameter_tag_compatible(uint64_t a, uint64_t b)
{
if (a == 0)
return b == 0;
if (b == 0)
return a == 0;
int sa = a % 6;
int sb = a % 6;
if (sa == 5) sa = 4;
if (sb == 5) sb = 4;
if (sa != sb)
return false;
return is_parameter_tag_compatible(a / 6, b / 6);
}
static inline unsigned find_closing_tag_runtime(const char* s, unsigned p)
{
return s[p] == 0 ? throw std::runtime_error("unmatched tag <") :
s[p] == '>' ? p :
find_closing_tag_runtime(s, p + 1);
}
static inline uint64_t get_parameter_tag_runtime(const char* s, unsigned p = 0)
{
return s[p] == 0 ? 0 :
s[p] == '<' ? (
std::strncmp(s + p, "<int>", 5) == 0 ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 1 :
std::strncmp(s + p, "<uint>", 6) == 0 ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 2 :
(std::strncmp(s + p, "<float>", 7) == 0 ||
std::strncmp(s + p, "<double>", 8) == 0) ?
get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 3 :
(std::strncmp(s + p, "<str>", 5) == 0 ||
std::strncmp(s + p, "<string>", 8) == 0) ?
get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 4 :
std::strncmp(s + p, "<path>", 6) == 0 ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 5 :
throw std::runtime_error("invalid parameter type")) :
get_parameter_tag_runtime(s, p + 1);
}
#ifndef CROW_MSVC_WORKAROUND
constexpr uint64_t get_parameter_tag(const_str s, unsigned p = 0)
{
return p == s.size() ? 0 :
s[p] == '<' ? (
is_int(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 1 :
is_uint(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 2 :
is_float(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 3 :
is_str(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 4 :
is_path(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 5 :
throw std::runtime_error("invalid parameter type")) :
get_parameter_tag(s, p + 1);
}
#endif
template<typename... T>
struct S
{
template<typename U>
using push = S<U, T...>;
template<typename U>
using push_back = S<T..., U>;
template<template<typename... Args> class U>
using rebind = U<T...>;
};
// Check whether the template function can be called with specific arguments
template<typename F, typename Set>
struct CallHelper;
template<typename F, typename... Args>
struct CallHelper<F, S<Args...>>
{
template<typename F1, typename... Args1, typename = decltype(std::declval<F1>()(std::declval<Args1>()...))>
static char __test(int);
template<typename...>
static int __test(...);
static constexpr bool value = sizeof(__test<F, Args...>(0)) == sizeof(char);
};
// Check Tuple contains type T
template<typename T, typename Tuple>
struct has_type;
template<typename T>
struct has_type<T, std::tuple<>> : std::false_type
{};
template<typename T, typename U, typename... Ts>
struct has_type<T, std::tuple<U, Ts...>> : has_type<T, std::tuple<Ts...>>
{};
template<typename T, typename... Ts>
struct has_type<T, std::tuple<T, Ts...>> : std::true_type
{};
// Kind of fold expressions in C++11
template<bool...>
struct bool_pack;
template<bool... bs>
using all_true = std::is_same<bool_pack<bs..., true>, bool_pack<true, bs...>>;
template<int N>
struct single_tag_to_type
{};
template<>
struct single_tag_to_type<1>
{
using type = int64_t;
};
template<>
struct single_tag_to_type<2>
{
using type = uint64_t;
};
template<>
struct single_tag_to_type<3>
{
using type = double;
};
template<>
struct single_tag_to_type<4>
{
using type = std::string;
};
template<>
struct single_tag_to_type<5>
{
using type = std::string;
};
template<uint64_t Tag>
struct arguments
{
using subarguments = typename arguments<Tag / 6>::type;
using type =
typename subarguments::template push<typename single_tag_to_type<Tag % 6>::type>;
};
template<>
struct arguments<0>
{
using type = S<>;
};
template<typename... T>
struct last_element_type
{
using type = typename std::tuple_element<sizeof...(T) - 1, std::tuple<T...>>::type;
};
template<>
struct last_element_type<>
{};
// from http://stackoverflow.com/questions/13072359/c11-compile-time-array-with-logarithmic-evaluation-depth
template<class T>
using Invoke = typename T::type;
template<unsigned...>
struct seq
{
using type = seq;
};
template<class S1, class S2>
struct concat;
template<unsigned... I1, unsigned... I2>
struct concat<seq<I1...>, seq<I2...>> : seq<I1..., (sizeof...(I1) + I2)...>
{};
template<class S1, class S2>
using Concat = Invoke<concat<S1, S2>>;
template<unsigned N>
struct gen_seq;
template<unsigned N>
using GenSeq = Invoke<gen_seq<N>>;
template<unsigned N>
struct gen_seq : Concat<GenSeq<N / 2>, GenSeq<N - N / 2>>
{};
template<>
struct gen_seq<0> : seq<>
{};
template<>
struct gen_seq<1> : seq<0>
{};
template<typename Seq, typename Tuple>
struct pop_back_helper;
template<unsigned... N, typename Tuple>
struct pop_back_helper<seq<N...>, Tuple>
{
template<template<typename... Args> class U>
using rebind = U<typename std::tuple_element<N, Tuple>::type...>;
};
template<typename... T>
struct pop_back //: public pop_back_helper<typename gen_seq<sizeof...(T)-1>::type, std::tuple<T...>>
{
template<template<typename... Args> class U>
using rebind = typename pop_back_helper<typename gen_seq<sizeof...(T) - 1>::type, std::tuple<T...>>::template rebind<U>;
};
template<>
struct pop_back<>
{
template<template<typename... Args> class U>
using rebind = U<>;
};
// from http://stackoverflow.com/questions/2118541/check-if-c0x-parameter-pack-contains-a-type
template<typename Tp, typename... List>
struct contains : std::true_type
{};
template<typename Tp, typename Head, typename... Rest>
struct contains<Tp, Head, Rest...> : std::conditional<std::is_same<Tp, Head>::value, std::true_type, contains<Tp, Rest...>>::type
{};
template<typename Tp>
struct contains<Tp> : std::false_type
{};
template<typename T>
struct empty_context
{};
template<typename T>
struct promote
{
using type = T;
};
#define CROW_INTERNAL_PROMOTE_TYPE(t1, t2) \
template<> \
struct promote<t1> \
{ \
using type = t2; \
}
CROW_INTERNAL_PROMOTE_TYPE(char, int64_t);
CROW_INTERNAL_PROMOTE_TYPE(short, int64_t);
CROW_INTERNAL_PROMOTE_TYPE(int, int64_t);
CROW_INTERNAL_PROMOTE_TYPE(long, int64_t);
CROW_INTERNAL_PROMOTE_TYPE(long long, int64_t);
CROW_INTERNAL_PROMOTE_TYPE(unsigned char, uint64_t);
CROW_INTERNAL_PROMOTE_TYPE(unsigned short, uint64_t);
CROW_INTERNAL_PROMOTE_TYPE(unsigned int, uint64_t);
CROW_INTERNAL_PROMOTE_TYPE(unsigned long, uint64_t);
CROW_INTERNAL_PROMOTE_TYPE(unsigned long long, uint64_t);
CROW_INTERNAL_PROMOTE_TYPE(float, double);
#undef CROW_INTERNAL_PROMOTE_TYPE
template<typename T>
using promote_t = typename promote<T>::type;
} // namespace black_magic
namespace detail
{
template<class T, std::size_t N, class... Args>
struct get_index_of_element_from_tuple_by_type_impl
{
static constexpr auto value = N;
};
template<class T, std::size_t N, class... Args>
struct get_index_of_element_from_tuple_by_type_impl<T, N, T, Args...>
{
static constexpr auto value = N;
};
template<class T, std::size_t N, class U, class... Args>
struct get_index_of_element_from_tuple_by_type_impl<T, N, U, Args...>
{
static constexpr auto value = get_index_of_element_from_tuple_by_type_impl<T, N + 1, Args...>::value;
};
} // namespace detail
namespace utility
{
template<class T, class... Args>
T& get_element_by_type(std::tuple<Args...>& t)
{
return std::get<detail::get_index_of_element_from_tuple_by_type_impl<T, 0, Args...>::value>(t);
}
template<typename T>
struct function_traits;
#ifndef CROW_MSVC_WORKAROUND
template<typename T>
struct function_traits : public function_traits<decltype(&T::operator())>
{
using parent_t = function_traits<decltype(&T::operator())>;
static const size_t arity = parent_t::arity;
using result_type = typename parent_t::result_type;
template<size_t i>
using arg = typename parent_t::template arg<i>;
};
#endif
template<typename ClassType, typename R, typename... Args>
struct function_traits<R (ClassType::*)(Args...) const>
{
static const size_t arity = sizeof...(Args);
typedef R result_type;
template<size_t i>
using arg = typename std::tuple_element<i, std::tuple<Args...>>::type;
};
template<typename ClassType, typename R, typename... Args>
struct function_traits<R (ClassType::*)(Args...)>
{
static const size_t arity = sizeof...(Args);
typedef R result_type;
template<size_t i>
using arg = typename std::tuple_element<i, std::tuple<Args...>>::type;
};
template<typename R, typename... Args>
struct function_traits<std::function<R(Args...)>>
{
static const size_t arity = sizeof...(Args);
typedef R result_type;
template<size_t i>
using arg = typename std::tuple_element<i, std::tuple<Args...>>::type;
};
/// @endcond
inline static std::string base64encode(const unsigned char* data, size_t size, const char* key = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/")
{
std::string ret;
ret.resize((size + 2) / 3 * 4);
auto it = ret.begin();
while (size >= 3)
{
*it++ = key[(static_cast<unsigned char>(*data) & 0xFC) >> 2];
unsigned char h = (static_cast<unsigned char>(*data++) & 0x03) << 4;
*it++ = key[h | ((static_cast<unsigned char>(*data) & 0xF0) >> 4)];
h = (static_cast<unsigned char>(*data++) & 0x0F) << 2;
*it++ = key[h | ((static_cast<unsigned char>(*data) & 0xC0) >> 6)];
*it++ = key[static_cast<unsigned char>(*data++) & 0x3F];
size -= 3;
}
if (size == 1)
{
*it++ = key[(static_cast<unsigned char>(*data) & 0xFC) >> 2];
unsigned char h = (static_cast<unsigned char>(*data++) & 0x03) << 4;
*it++ = key[h];
*it++ = '=';
*it++ = '=';
}
else if (size == 2)
{
*it++ = key[(static_cast<unsigned char>(*data) & 0xFC) >> 2];
unsigned char h = (static_cast<unsigned char>(*data++) & 0x03) << 4;
*it++ = key[h | ((static_cast<unsigned char>(*data) & 0xF0) >> 4)];
h = (static_cast<unsigned char>(*data++) & 0x0F) << 2;
*it++ = key[h];
*it++ = '=';
}
return ret;
}
inline static std::string base64encode(std::string data, size_t size, const char* key = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/")
{
return base64encode((const unsigned char*)data.c_str(), size, key);
}
inline static std::string base64encode_urlsafe(const unsigned char* data, size_t size)
{
return base64encode(data, size, "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_");
}
inline static std::string base64encode_urlsafe(std::string data, size_t size)
{
return base64encode((const unsigned char*)data.c_str(), size, "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_");
}
inline static std::string base64decode(const char* data, size_t size)
{
// We accept both regular and url encoding here, as there does not seem to be any downside to that.
// If we want to distinguish that we should use +/ for non-url and -_ for url.
// Mapping logic from characters to [0-63]
auto key = [](char c) -> unsigned char {
if ((c >= 'A') && (c <= 'Z')) return c - 'A';
if ((c >= 'a') && (c <= 'z')) return c - 'a' + 26;
if ((c >= '0') && (c <= '9')) return c - '0' + 52;
if ((c == '+') || (c == '-')) return 62;
if ((c == '/') || (c == '_')) return 63;
return 0;
};
// Not padded
if (size % 4 == 2) // missing last 2 characters
size = (size / 4 * 3) + 1; // Not subtracting extra characters because they're truncated in int division
else if (size % 4 == 3) // missing last character
size = (size / 4 * 3) + 2; // Not subtracting extra characters because they're truncated in int division
// Padded
else if (data[size - 2] == '=') // padded with '=='
size = (size / 4 * 3) - 2; // == padding means the last block only has 1 character instead of 3, hence the '-2'
else if (data[size - 1] == '=') // padded with '='
size = (size / 4 * 3) - 1; // = padding means the last block only has 2 character instead of 3, hence the '-1'
// Padding not needed
else
size = size / 4 * 3;
std::string ret;
ret.resize(size);
auto it = ret.begin();
// These will be used to decode 1 character at a time
unsigned char odd; // char1 and char3
unsigned char even; // char2 and char4
// Take 4 character blocks to turn into 3
while (size >= 3)
{
// dec_char1 = (char1 shifted 2 bits to the left) OR ((char2 AND 00110000) shifted 4 bits to the right))
odd = key(*data++);
even = key(*data++);
*it++ = (odd << 2) | ((even & 0x30) >> 4);
// dec_char2 = ((char2 AND 00001111) shifted 4 bits left) OR ((char3 AND 00111100) shifted 2 bits right))
odd = key(*data++);
*it++ = ((even & 0x0F) << 4) | ((odd & 0x3C) >> 2);
// dec_char3 = ((char3 AND 00000011) shifted 6 bits left) OR (char4)
even = key(*data++);
*it++ = ((odd & 0x03) << 6) | (even);
size -= 3;
}
if (size == 2)
{
// d_char1 = (char1 shifted 2 bits to the left) OR ((char2 AND 00110000) shifted 4 bits to the right))
odd = key(*data++);
even = key(*data++);
*it++ = (odd << 2) | ((even & 0x30) >> 4);
// d_char2 = ((char2 AND 00001111) shifted 4 bits left) OR ((char3 AND 00111100) shifted 2 bits right))
odd = key(*data++);
*it++ = ((even & 0x0F) << 4) | ((odd & 0x3C) >> 2);
}
else if (size == 1)
{
// d_char1 = (char1 shifted 2 bits to the left) OR ((char2 AND 00110000) shifted 4 bits to the right))
odd = key(*data++);
even = key(*data++);
*it++ = (odd << 2) | ((even & 0x30) >> 4);
}
return ret;
}
inline static std::string base64decode(const std::string& data, size_t size)
{
return base64decode(data.data(), size);
}
inline static std::string base64decode(const std::string& data)
{
return base64decode(data.data(), data.length());
}
inline static void sanitize_filename(std::string& data, char replacement = '_')
{
if (data.length() > 255)
data.resize(255);
static const auto toUpper = [](char c) {
return ((c >= 'a') && (c <= 'z')) ? (c - ('a' - 'A')) : c;
};
// Check for special device names. The Windows behavior is really odd here, it will consider both AUX and AUX.txt
// a special device. Thus we search for the string (case-insensitive), and then check if the string ends or if
// is has a dangerous follow up character (.:\/)
auto sanitizeSpecialFile = [](std::string& source, unsigned ofs, const char* pattern, bool includeNumber, char replacement) {
unsigned i = ofs, len = source.length();
const char* p = pattern;
while (*p)
{
if (i >= len) return;
if (toUpper(source[i]) != *p) return;
++i;
++p;
}
if (includeNumber)
{
if ((i >= len) || (source[i] < '1') || (source[i] > '9')) return;
++i;
}
if ((i >= len) || (source[i] == '.') || (source[i] == ':') || (source[i] == '/') || (source[i] == '\\'))
{
source.erase(ofs + 1, (i - ofs) - 1);
source[ofs] = replacement;
}
};
bool checkForSpecialEntries = true;
for (unsigned i = 0; i < data.length(); ++i)
{
// Recognize directory traversals and the special devices CON/PRN/AUX/NULL/COM[1-]/LPT[1-9]
if (checkForSpecialEntries)
{
checkForSpecialEntries = false;
switch (toUpper(data[i]))
{
case 'A':
sanitizeSpecialFile(data, i, "AUX", false, replacement);
break;
case 'C':
sanitizeSpecialFile(data, i, "CON", false, replacement);
sanitizeSpecialFile(data, i, "COM", true, replacement);
break;
case 'L':
sanitizeSpecialFile(data, i, "LPT", true, replacement);
break;
case 'N':
sanitizeSpecialFile(data, i, "NUL", false, replacement);
break;
case 'P':
sanitizeSpecialFile(data, i, "PRN", false, replacement);
break;
case '.':
sanitizeSpecialFile(data, i, "..", false, replacement);
break;
}
}
// Sanitize individual characters
unsigned char c = data[i];
if ((c < ' ') || ((c >= 0x80) && (c <= 0x9F)) || (c == '?') || (c == '<') || (c == '>') || (c == ':') || (c == '*') || (c == '|') || (c == '\"'))
{
data[i] = replacement;
}
else if ((c == '/') || (c == '\\'))
{
if (CROW_UNLIKELY(i == 0)) //Prevent Unix Absolute Paths (Windows Absolute Paths are prevented with `(c == ':')`)
{
data[i] = replacement;
}
else
{
checkForSpecialEntries = true;
}
}
}
}
} // namespace utility
} // namespace crow
#pragma once
#include <vector>
#include <string>
#include <stdexcept>
#include <iostream>
namespace crow
{
const char cr = '\r';
const char lf = '\n';
const std::string crlf("\r\n");
enum class HTTPMethod : char
{
#ifndef DELETE
DELETE = 0,
GET,
HEAD,
POST,
PUT,
CONNECT,
OPTIONS,
TRACE,
PATCH,
PURGE,
COPY,
LOCK,
MKCOL,
MOVE,
PROPFIND,
PROPPATCH,
SEARCH,
UNLOCK,
BIND,
REBIND,
UNBIND,
ACL,
REPORT,
MKACTIVITY,
CHECKOUT,
MERGE,
MSEARCH,
NOTIFY,
SUBSCRIBE,
UNSUBSCRIBE,
MKCALENDAR,
LINK,
UNLINK,
SOURCE,
#endif
Delete = 0,
Get,
Head,
Post,
Put,
Connect,
Options,
Trace,
Patch,
Purge,
Copy,
Lock,
MkCol,
Move,
Propfind,
Proppatch,
Search,
Unlock,
Bind,
Rebind,
Unbind,
Acl,
Report,
MkActivity,
Checkout,
Merge,
MSearch,
Notify,
Subscribe,
Unsubscribe,
MkCalendar,
Link,
Unlink,
Source,
InternalMethodCount,
// should not add an item below this line: used for array count
};
constexpr const char* method_strings[] =
{
"DELETE",
"GET",
"HEAD",
"POST",
"PUT",
"CONNECT",
"OPTIONS",
"TRACE",
"PATCH",
"PURGE",
"COPY",
"LOCK",
"MKCOL",
"MOVE",
"PROPFIND",
"PROPPATCH",
"SEARCH",
"UNLOCK",
"BIND",
"REBIND",
"UNBIND",
"ACL",
"REPORT",
"MKACTIVITY",
"CHECKOUT",
"MERGE",
"M-SEARCH",
"NOTIFY",
"SUBSCRIBE",
"UNSUBSCRIBE",
"MKCALENDAR",
"LINK",
"UNLINK",
"SOURCE"};
inline std::string method_name(HTTPMethod method)
{
if (CROW_LIKELY(method < HTTPMethod::InternalMethodCount))
{
return method_strings[(unsigned char)method];
}
return "invalid";
}
// clang-format off
enum status
{
CONTINUE = 100,
SWITCHING_PROTOCOLS = 101,
OK = 200,
CREATED = 201,
ACCEPTED = 202,
NON_AUTHORITATIVE_INFORMATION = 203,
NO_CONTENT = 204,
RESET_CONTENT = 205,
PARTIAL_CONTENT = 206,
MULTIPLE_CHOICES = 300,
MOVED_PERMANENTLY = 301,
FOUND = 302,
SEE_OTHER = 303,
NOT_MODIFIED = 304,
TEMPORARY_REDIRECT = 307,
PERMANENT_REDIRECT = 308,
BAD_REQUEST = 400,
UNAUTHORIZED = 401,
FORBIDDEN = 403,
NOT_FOUND = 404,
METHOD_NOT_ALLOWED = 405,
PROXY_AUTHENTICATION_REQUIRED = 407,
CONFLICT = 409,
GONE = 410,
PAYLOAD_TOO_LARGE = 413,
UNSUPPORTED_MEDIA_TYPE = 415,
RANGE_NOT_SATISFIABLE = 416,
EXPECTATION_FAILED = 417,
PRECONDITION_REQUIRED = 428,
TOO_MANY_REQUESTS = 429,
UNAVAILABLE_FOR_LEGAL_REASONS = 451,
INTERNAL_SERVER_ERROR = 500,
NOT_IMPLEMENTED = 501,
BAD_GATEWAY = 502,
SERVICE_UNAVAILABLE = 503,
GATEWAY_TIMEOUT = 504,
VARIANT_ALSO_NEGOTIATES = 506
};
// clang-format on
enum class ParamType : char
{
INT,
UINT,
DOUBLE,
STRING,
PATH,
MAX
};
/// @cond SKIP
struct routing_params
{
std::vector<int64_t> int_params;
std::vector<uint64_t> uint_params;
std::vector<double> double_params;
std::vector<std::string> string_params;
void debug_print() const
{
std::cerr << "routing_params" << std::endl;
for (auto i : int_params)
std::cerr << i << ", ";
std::cerr << std::endl;
for (auto i : uint_params)
std::cerr << i << ", ";
std::cerr << std::endl;
for (auto i : double_params)
std::cerr << i << ", ";
std::cerr << std::endl;
for (auto& i : string_params)
std::cerr << i << ", ";
std::cerr << std::endl;
}
template<typename T>
T get(unsigned) const;
};
template<>
inline int64_t routing_params::get<int64_t>(unsigned index) const
{
return int_params[index];
}
template<>
inline uint64_t routing_params::get<uint64_t>(unsigned index) const
{
return uint_params[index];
}
template<>
inline double routing_params::get<double>(unsigned index) const
{
return double_params[index];
}
template<>
inline std::string routing_params::get<std::string>(unsigned index) const
{
return string_params[index];
}
/// @endcond
} // namespace crow
// clang-format off
#ifndef CROW_MSVC_WORKAROUND
constexpr crow::HTTPMethod method_from_string(const char* str)
{
return crow::black_magic::is_equ_p(str, "GET", 3) ? crow::HTTPMethod::Get :
crow::black_magic::is_equ_p(str, "DELETE", 6) ? crow::HTTPMethod::Delete :
crow::black_magic::is_equ_p(str, "HEAD", 4) ? crow::HTTPMethod::Head :
crow::black_magic::is_equ_p(str, "POST", 4) ? crow::HTTPMethod::Post :
crow::black_magic::is_equ_p(str, "PUT", 3) ? crow::HTTPMethod::Put :
crow::black_magic::is_equ_p(str, "OPTIONS", 7) ? crow::HTTPMethod::Options :
crow::black_magic::is_equ_p(str, "CONNECT", 7) ? crow::HTTPMethod::Connect :
crow::black_magic::is_equ_p(str, "TRACE", 5) ? crow::HTTPMethod::Trace :
crow::black_magic::is_equ_p(str, "PATCH", 5) ? crow::HTTPMethod::Patch :
crow::black_magic::is_equ_p(str, "PURGE", 5) ? crow::HTTPMethod::Purge :
crow::black_magic::is_equ_p(str, "COPY", 4) ? crow::HTTPMethod::Copy :
crow::black_magic::is_equ_p(str, "LOCK", 4) ? crow::HTTPMethod::Lock :
crow::black_magic::is_equ_p(str, "MKCOL", 5) ? crow::HTTPMethod::MkCol :
crow::black_magic::is_equ_p(str, "MOVE", 4) ? crow::HTTPMethod::Move :
crow::black_magic::is_equ_p(str, "PROPFIND", 8) ? crow::HTTPMethod::Propfind :
crow::black_magic::is_equ_p(str, "PROPPATCH", 9) ? crow::HTTPMethod::Proppatch :
crow::black_magic::is_equ_p(str, "SEARCH", 6) ? crow::HTTPMethod::Search :
crow::black_magic::is_equ_p(str, "UNLOCK", 6) ? crow::HTTPMethod::Unlock :
crow::black_magic::is_equ_p(str, "BIND", 4) ? crow::HTTPMethod::Bind :
crow::black_magic::is_equ_p(str, "REBIND", 6) ? crow::HTTPMethod::Rebind :
crow::black_magic::is_equ_p(str, "UNBIND", 6) ? crow::HTTPMethod::Unbind :
crow::black_magic::is_equ_p(str, "ACL", 3) ? crow::HTTPMethod::Acl :
crow::black_magic::is_equ_p(str, "REPORT", 6) ? crow::HTTPMethod::Report :
crow::black_magic::is_equ_p(str, "MKACTIVITY", 10) ? crow::HTTPMethod::MkActivity :
crow::black_magic::is_equ_p(str, "CHECKOUT", 8) ? crow::HTTPMethod::Checkout :
crow::black_magic::is_equ_p(str, "MERGE", 5) ? crow::HTTPMethod::Merge :
crow::black_magic::is_equ_p(str, "MSEARCH", 7) ? crow::HTTPMethod::MSearch :
crow::black_magic::is_equ_p(str, "NOTIFY", 6) ? crow::HTTPMethod::Notify :
crow::black_magic::is_equ_p(str, "SUBSCRIBE", 9) ? crow::HTTPMethod::Subscribe :
crow::black_magic::is_equ_p(str, "UNSUBSCRIBE", 11) ? crow::HTTPMethod::Unsubscribe :
crow::black_magic::is_equ_p(str, "MKCALENDAR", 10) ? crow::HTTPMethod::MkCalendar :
crow::black_magic::is_equ_p(str, "LINK", 4) ? crow::HTTPMethod::Link :
crow::black_magic::is_equ_p(str, "UNLINK", 6) ? crow::HTTPMethod::Unlink :
crow::black_magic::is_equ_p(str, "SOURCE", 6) ? crow::HTTPMethod::Source :
throw std::runtime_error("invalid http method");
}
constexpr crow::HTTPMethod operator"" _method(const char* str, size_t /*len*/)
{
return method_from_string( str );
}
#endif
// clang-format on
#pragma once
#include <boost/asio.hpp>
namespace crow
{
/// Find and return the value associated with the key. (returns an empty string if nothing is found)
template<typename T>
inline const std::string& get_header_value(const T& headers, const std::string& key)
{
if (headers.count(key))
{
return headers.find(key)->second;
}
static std::string empty;
return empty;
}
/// An HTTP request.
struct request
{
HTTPMethod method;
std::string raw_url; ///< The full URL containing the `?` and URL parameters.
std::string url; ///< The endpoint without any parameters.
query_string url_params; ///< The parameters associated with the request. (everything after the `?`)
ci_map headers;
std::string body;
std::string remote_ip_address; ///< The IP address from which the request was sent.
unsigned char http_ver_major, http_ver_minor;
bool keep_alive, close_connection, upgrade;
void* middleware_context{};
void* middleware_container{};
boost::asio::io_service* io_service{};
/// Construct an empty request. (sets the method to `GET`)
request():
method(HTTPMethod::Get)
{}
/// Construct a request with all values assigned.
request(HTTPMethod method, std::string raw_url, std::string url, query_string url_params, ci_map headers, std::string body, unsigned char http_major, unsigned char http_minor, bool has_keep_alive, bool has_close_connection, bool is_upgrade):
method(method), raw_url(std::move(raw_url)), url(std::move(url)), url_params(std::move(url_params)), headers(std::move(headers)), body(std::move(body)), http_ver_major(http_major), http_ver_minor(http_minor), keep_alive(has_keep_alive), close_connection(has_close_connection), upgrade(is_upgrade)
{}
void add_header(std::string key, std::string value)
{
headers.emplace(std::move(key), std::move(value));
}
const std::string& get_header_value(const std::string& key) const
{
return crow::get_header_value(headers, key);
}
bool check_version(unsigned char major, unsigned char minor) const
{
return http_ver_major == major && http_ver_minor == minor;
}
/// Send data to whoever made this request with a completion handler and return immediately.
template<typename CompletionHandler>
void post(CompletionHandler handler)
{
io_service->post(handler);
}
/// Send data to whoever made this request with a completion handler.
template<typename CompletionHandler>
void dispatch(CompletionHandler handler)
{
io_service->dispatch(handler);
}
};
} // namespace crow
#pragma once
#include <string>
#include <vector>
#include <sstream>
namespace crow
{
/// Encapsulates anything related to processing and organizing `multipart/xyz` messages
namespace multipart
{
const std::string dd = "--";
/// The first part in a section, contains metadata about the part
struct header
{
std::string value; ///< The first part of the header, usually `Content-Type` or `Content-Disposition`
std::unordered_map<std::string, std::string> params; ///< The parameters of the header, come after the `value`
operator int() const { return std::stoi(value); } ///< Returns \ref value as integer
operator double() const { return std::stod(value); } ///< Returns \ref value as double
};
/// Multipart header map (key is header key).
using mph_map = std::unordered_multimap<std::string, header, ci_hash, ci_key_eq>;
/// Find and return the value object associated with the key. (returns an empty class if nothing is found)
template<typename O, typename T>
inline const O& get_header_value_object(const T& headers, const std::string& key)
{
if (headers.count(key))
{
return headers.find(key)->second;
}
static O empty;
return empty;
}
/// Same as \ref get_header_value_object() but for \ref multipart.header
template<typename T>
inline const header& get_header_object(const T& headers, const std::string& key)
{
return get_header_value_object<header>(headers, key);
}
///One part of the multipart message
///
/// It is usually separated from other sections by a `boundary`
struct part
{
mph_map headers; ///< (optional) The first part before the data, Contains information regarding the type of data and encoding
std::string body; ///< The actual data in the part
operator int() const { return std::stoi(body); } ///< Returns \ref body as integer
operator double() const { return std::stod(body); } ///< Returns \ref body as double
const header& get_header_object(const std::string& key) const
{
return multipart::get_header_object(headers, key);
}
};
/// Multipart map (key is the name parameter).
using mp_map = std::unordered_multimap<std::string, part, ci_hash, ci_key_eq>;
/// The parsed multipart request/response
struct message : public returnable
{
ci_map headers; ///< The request/response headers
std::string boundary; ///< The text boundary that separates different `parts`
std::vector<part> parts; ///< The individual parts of the message
mp_map part_map; ///< The individual parts of the message, organized in a map with the `name` header parameter being the key
const std::string& get_header_value(const std::string& key) const
{
return crow::get_header_value(headers, key);
}
part get_part_by_name(const std::string& name)
{
return part_map.find(name)->second;
}
/// Represent all parts as a string (**does not include message headers**)
std::string dump() const override
{
std::stringstream str;
std::string delimiter = dd + boundary;
for (unsigned i = 0; i < parts.size(); i++)
{
str << delimiter << crlf;
str << dump(i);
}
str << delimiter << dd << crlf;
return str.str();
}
/// Represent an individual part as a string
std::string dump(int part_) const
{
std::stringstream str;
part item = parts[part_];
for (auto& item_h : item.headers)
{
str << item_h.first << ": " << item_h.second.value;
for (auto& it : item_h.second.params)
{
str << "; " << it.first << '=' << pad(it.second);
}
str << crlf;
}
str << crlf;
str << item.body << crlf;
return str.str();
}
/// Default constructor using default values
message(const ci_map& headers, const std::string& boundary, const std::vector<part>& sections):
returnable("multipart/form-data; boundary=CROW-BOUNDARY"), headers(headers), boundary(boundary), parts(sections)
{
if (!boundary.empty())
content_type = "multipart/form-data; boundary=" + boundary;
for (auto& item : parts)
{
part_map.emplace(
(get_header_object(item.headers, "Content-Disposition").params.find("name")->second),
item);
}
}
/// Create a multipart message from a request data
message(const request& req):
returnable("multipart/form-data; boundary=CROW-BOUNDARY"),
headers(req.headers),
boundary(get_boundary(get_header_value("Content-Type")))
{
if (!boundary.empty())
content_type = "multipart/form-data; boundary=" + boundary;
parse_body(req.body, parts, part_map);
}
private:
std::string get_boundary(const std::string& header) const
{
constexpr char boundary_text[] = "boundary=";
size_t found = header.find(boundary_text);
if (found)
{
std::string to_return(header.substr(found + strlen(boundary_text)));
if (to_return[0] == '\"')
{
to_return = to_return.substr(1, to_return.length() - 2);
}
return to_return;
}
return std::string();
}
void parse_body(std::string body, std::vector<part>& sections, mp_map& part_map)
{
std::string delimiter = dd + boundary;
// TODO(EDev): Exit on error
while (body != (crlf))
{
size_t found = body.find(delimiter);
std::string section = body.substr(0, found);
// +2 is the CRLF.
// We don't check it and delete it so that the same delimiter can be used for The last delimiter (--delimiter--CRLF).
body.erase(0, found + delimiter.length() + 2);
if (!section.empty())
{
part parsed_section(parse_section(section));
part_map.emplace(
(get_header_object(parsed_section.headers, "Content-Disposition").params.find("name")->second),
parsed_section);
sections.push_back(std::move(parsed_section));
}
}
}
part parse_section(std::string& section)
{
struct part to_return;
size_t found = section.find(crlf + crlf);
std::string head_line = section.substr(0, found + 2);
section.erase(0, found + 4);
parse_section_head(head_line, to_return);
to_return.body = section.substr(0, section.length() - 2);
return to_return;
}
void parse_section_head(std::string& lines, part& part)
{
while (!lines.empty())
{
header to_add;
size_t found = lines.find(crlf);
std::string line = lines.substr(0, found);
std::string key;
lines.erase(0, found + 2);
// Add the header if available
if (!line.empty())
{
size_t found = line.find("; ");
std::string header = line.substr(0, found);
if (found != std::string::npos)
line.erase(0, found + 2);
else
line = std::string();
size_t header_split = header.find(": ");
key = header.substr(0, header_split);
to_add.value = header.substr(header_split + 2);
}
// Add the parameters
while (!line.empty())
{
size_t found = line.find("; ");
std::string param = line.substr(0, found);
if (found != std::string::npos)
line.erase(0, found + 2);
else
line = std::string();
size_t param_split = param.find('=');
std::string value = param.substr(param_split + 1);
to_add.params.emplace(param.substr(0, param_split), trim(value));
}
part.headers.emplace(key, to_add);
}
}
inline std::string trim(std::string& string, const char& excess = '"') const
{
if (string.length() > 1 && string[0] == excess && string[string.length() - 1] == excess)
return string.substr(1, string.length() - 2);
return string;
}
inline std::string pad(std::string& string, const char& padding = '"') const
{
return (padding + string + padding);
}
};
} // namespace multipart
} // namespace crow
#pragma once
#include <string>
#include <unordered_map>
#include <ios>
#include <fstream>
#include <sstream>
#include <sys/stat.h>
namespace crow
{
template<typename Adaptor, typename Handler, typename... Middlewares>
class Connection;
namespace detail
{
template<typename F, typename App, typename... Middlewares>
struct handler_middleware_wrapper;
} // namespace detail
/// HTTP response
struct response
{
template<typename Adaptor, typename Handler, typename... Middlewares>
friend class crow::Connection;
template<typename F, typename App, typename... Middlewares>
friend struct crow::detail::handler_middleware_wrapper;
int code{200}; ///< The Status code for the response.
std::string body; ///< The actual payload containing the response data.
ci_map headers; ///< HTTP headers.
#ifdef CROW_ENABLE_COMPRESSION
bool compressed = true; ///< If compression is enabled and this is false, the individual response will not be compressed.
#endif
bool skip_body = false; ///< Whether this is a response to a HEAD request.
bool manual_length_header = false; ///< Whether Crow should automatically add a "Content-Length" header.
/// Set the value of an existing header in the response.
void set_header(std::string key, std::string value)
{
headers.erase(key);
headers.emplace(std::move(key), std::move(value));
}
/// Add a new header to the response.
void add_header(std::string key, std::string value)
{
headers.emplace(std::move(key), std::move(value));
}
const std::string& get_header_value(const std::string& key)
{
return crow::get_header_value(headers, key);
}
// clang-format off
response() {}
explicit response(int code) : code(code) {}
response(std::string body) : body(std::move(body)) {}
response(int code, std::string body) : code(code), body(std::move(body)) {}
// clang-format on
response(returnable&& value)
{
body = value.dump();
set_header("Content-Type", value.content_type);
}
response(returnable& value)
{
body = value.dump();
set_header("Content-Type", value.content_type);
}
response(int code, returnable& value):
code(code)
{
body = value.dump();
set_header("Content-Type", value.content_type);
}
response(response&& r)
{
*this = std::move(r);
}
response(std::string contentType, std::string body):
body(std::move(body))
{
set_header("Content-Type", mime_types.at(contentType));
}
response(int code, std::string contentType, std::string body):
code(code), body(std::move(body))
{
set_header("Content-Type", mime_types.at(contentType));
}
response& operator=(const response& r) = delete;
response& operator=(response&& r) noexcept
{
body = std::move(r.body);
code = r.code;
headers = std::move(r.headers);
completed_ = r.completed_;
file_info = std::move(r.file_info);
return *this;
}
/// Check if the response has completed (whether response.end() has been called)
bool is_completed() const noexcept
{
return completed_;
}
void clear()
{
body.clear();
code = 200;
headers.clear();
completed_ = false;
file_info = static_file_info{};
}
/// Return a "Temporary Redirect" response.
///
/// Location can either be a route or a full URL.
void redirect(const std::string& location)
{
code = 307;
set_header("Location", location);
}
/// Return a "Permanent Redirect" response.
///
/// Location can either be a route or a full URL.
void redirect_perm(const std::string& location)
{
code = 308;
set_header("Location", location);
}
/// Return a "Found (Moved Temporarily)" response.
///
/// Location can either be a route or a full URL.
void moved(const std::string& location)
{
code = 302;
set_header("Location", location);
}
/// Return a "Moved Permanently" response.
///
/// Location can either be a route or a full URL.
void moved_perm(const std::string& location)
{
code = 301;
set_header("Location", location);
}
void write(const std::string& body_part)
{
body += body_part;
}
/// Set the response completion flag and call the handler (to send the response).
void end()
{
if (!completed_)
{
completed_ = true;
if (skip_body)
{
set_header("Content-Length", std::to_string(body.size()));
body = "";
manual_length_header = true;
}
if (complete_request_handler_)
{
complete_request_handler_();
}
}
}
/// Same as end() except it adds a body part right before ending.
void end(const std::string& body_part)
{
body += body_part;
end();
}
/// Check if the connection is still alive (usually by checking the socket status).
bool is_alive()
{
return is_alive_helper_ && is_alive_helper_();
}
/// Check whether the response has a static file defined.
bool is_static_type()
{
return file_info.path.size();
}
/// This constains metadata (coming from the `stat` command) related to any static files associated with this response.
///
/// Either a static file or a string body can be returned as 1 response.
struct static_file_info
{
std::string path = "";
struct stat statbuf;
int statResult;
};
/// Return a static file as the response body
void set_static_file_info(std::string path)
{
utility::sanitize_filename(path);
set_static_file_info_unsafe(path);
}
/// Return a static file as the response body without sanitizing the path (use set_static_file_info instead)
void set_static_file_info_unsafe(std::string path)
{
file_info.path = path;
file_info.statResult = stat(file_info.path.c_str(), &file_info.statbuf);
#ifdef CROW_ENABLE_COMPRESSION
compressed = false;
#endif
if (file_info.statResult == 0)
{
std::size_t last_dot = path.find_last_of(".");
std::string extension = path.substr(last_dot + 1);
code = 200;
this->add_header("Content-Length", std::to_string(file_info.statbuf.st_size));
if (!extension.empty())
{
const auto mimeType = mime_types.find(extension);
if (mimeType != mime_types.end())
{
this->add_header("Content-Type", mimeType->second);
}
else
{
this->add_header("Content-Type", "text/plain");
}
}
}
else
{
code = 404;
file_info.path.clear();
this->end();
}
}
private:
bool completed_{};
std::function<void()> complete_request_handler_;
std::function<bool()> is_alive_helper_;
static_file_info file_info;
};
} // namespace crow
#pragma once
namespace crow
{
struct UTF8
{
struct context
{};
void before_handle(request& /*req*/, response& /*res*/, context& /*ctx*/)
{}
void after_handle(request& /*req*/, response& res, context& /*ctx*/)
{
if (get_header_value(res.headers, "Content-Type").empty())
{
res.set_header("Content-Type", "text/plain; charset=utf-8");
}
}
};
} // namespace crow
#pragma once
#include <boost/algorithm/string/trim.hpp>
namespace crow
{
// Any middleware requires following 3 members:
// struct context;
// storing data for the middleware; can be read from another middleware or handlers
// before_handle
// called before handling the request.
// if res.end() is called, the operation is halted.
// (still call after_handle of this middleware)
// 2 signatures:
// void before_handle(request& req, response& res, context& ctx)
// if you only need to access this middlewares context.
// template <typename AllContext>
// void before_handle(request& req, response& res, context& ctx, AllContext& all_ctx)
// you can access another middlewares' context by calling `all_ctx.template get<MW>()'
// ctx == all_ctx.template get<CurrentMiddleware>()
// after_handle
// called after handling the request.
// void after_handle(request& req, response& res, context& ctx)
// template <typename AllContext>
// void after_handle(request& req, response& res, context& ctx, AllContext& all_ctx)
struct CookieParser
{
struct context
{
std::unordered_map<std::string, std::string> jar;
std::unordered_map<std::string, std::string> cookies_to_add;
std::string get_cookie(const std::string& key) const
{
auto cookie = jar.find(key);
if (cookie != jar.end())
return cookie->second;
return {};
}
void set_cookie(const std::string& key, const std::string& value)
{
cookies_to_add.emplace(key, value);
}
};
void before_handle(request& req, response& res, context& ctx)
{
int count = req.headers.count("Cookie");
if (!count)
return;
if (count > 1)
{
res.code = 400;
res.end();
return;
}
std::string cookies = req.get_header_value("Cookie");
size_t pos = 0;
while (pos < cookies.size())
{
size_t pos_equal = cookies.find('=', pos);
if (pos_equal == cookies.npos)
break;
std::string name = cookies.substr(pos, pos_equal - pos);
boost::trim(name);
pos = pos_equal + 1;
while (pos < cookies.size() && cookies[pos] == ' ')
pos++;
if (pos == cookies.size())
break;
size_t pos_semicolon = cookies.find(';', pos);
std::string value = cookies.substr(pos, pos_semicolon - pos);
boost::trim(value);
if (value[0] == '"' && value[value.size() - 1] == '"')
{
value = value.substr(1, value.size() - 2);
}
ctx.jar.emplace(std::move(name), std::move(value));
pos = pos_semicolon;
if (pos == cookies.npos)
break;
pos++;
while (pos < cookies.size() && cookies[pos] == ' ')
pos++;
}
}
void after_handle(request& /*req*/, response& res, context& ctx)
{
for (auto& cookie : ctx.cookies_to_add)
{
if (cookie.second.empty())
res.add_header("Set-Cookie", cookie.first + "=\"\"");
else
res.add_header("Set-Cookie", cookie.first + "=" + cookie.second);
}
}
};
/*
App<CookieParser, AnotherJarMW> app;
A B C
A::context
int aa;
ctx1 : public A::context
ctx2 : public ctx1, public B::context
ctx3 : public ctx2, public C::context
C depends on A
C::handle
context.aaa
App::context : private CookieParser::contetx, ...
{
jar
}
SimpleApp
*/
} // namespace crow
#pragma once
#include <tuple>
#include <type_traits>
#include <iostream>
#include <utility>
namespace crow
{
/// Local middleware should extend ILocalMiddleware
struct ILocalMiddleware
{
using call_global = std::false_type;
};
namespace detail
{
template<typename MW>
struct check_before_handle_arity_3_const
{
template<typename T, void (T::*)(request&, response&, typename MW::context&) const = &T::before_handle>
struct get
{};
};
template<typename MW>
struct check_before_handle_arity_3
{
template<typename T, void (T::*)(request&, response&, typename MW::context&) = &T::before_handle>
struct get
{};
};
template<typename MW>
struct check_after_handle_arity_3_const
{
template<typename T, void (T::*)(request&, response&, typename MW::context&) const = &T::after_handle>
struct get
{};
};
template<typename MW>
struct check_after_handle_arity_3
{
template<typename T, void (T::*)(request&, response&, typename MW::context&) = &T::after_handle>
struct get
{};
};
template<typename MW>
struct check_global_call_false
{
template<typename T, typename std::enable_if<T::call_global::value == false, bool>::type = true>
struct get
{};
};
template<typename T>
struct is_before_handle_arity_3_impl
{
template<typename C>
static std::true_type f(typename check_before_handle_arity_3_const<T>::template get<C>*);
template<typename C>
static std::true_type f(typename check_before_handle_arity_3<T>::template get<C>*);
template<typename C>
static std::false_type f(...);
public:
static const bool value = decltype(f<T>(nullptr))::value;
};
template<typename T>
struct is_after_handle_arity_3_impl
{
template<typename C>
static std::true_type f(typename check_after_handle_arity_3_const<T>::template get<C>*);
template<typename C>
static std::true_type f(typename check_after_handle_arity_3<T>::template get<C>*);
template<typename C>
static std::false_type f(...);
public:
static constexpr bool value = decltype(f<T>(nullptr))::value;
};
template<typename MW, typename Context, typename ParentContext>
typename std::enable_if<!is_before_handle_arity_3_impl<MW>::value>::type
before_handler_call(MW& mw, request& req, response& res, Context& ctx, ParentContext& /*parent_ctx*/)
{
mw.before_handle(req, res, ctx.template get<MW>(), ctx);
}
template<typename MW, typename Context, typename ParentContext>
typename std::enable_if<is_before_handle_arity_3_impl<MW>::value>::type
before_handler_call(MW& mw, request& req, response& res, Context& ctx, ParentContext& /*parent_ctx*/)
{
mw.before_handle(req, res, ctx.template get<MW>());
}
template<typename MW, typename Context, typename ParentContext>
typename std::enable_if<!is_after_handle_arity_3_impl<MW>::value>::type
after_handler_call(MW& mw, request& req, response& res, Context& ctx, ParentContext& /*parent_ctx*/)
{
mw.after_handle(req, res, ctx.template get<MW>(), ctx);
}
template<typename MW, typename Context, typename ParentContext>
typename std::enable_if<is_after_handle_arity_3_impl<MW>::value>::type
after_handler_call(MW& mw, request& req, response& res, Context& ctx, ParentContext& /*parent_ctx*/)
{
mw.after_handle(req, res, ctx.template get<MW>());
}
template<template<typename QueryMW> class CallCriteria, // Checks if QueryMW should be called in this context
int N, typename Context, typename Container>
typename std::enable_if<(N < std::tuple_size<typename std::remove_reference<Container>::type>::value), bool>::type
middleware_call_helper(Container& middlewares, request& req, response& res, Context& ctx)
{
using CurrentMW = typename std::tuple_element<N, typename std::remove_reference<Container>::type>::type;
if (!CallCriteria<CurrentMW>::value)
{
return middleware_call_helper<CallCriteria, N + 1, Context, Container>(middlewares, req, res, ctx);
}
using parent_context_t = typename Context::template partial<N - 1>;
before_handler_call<CurrentMW, Context, parent_context_t>(std::get<N>(middlewares), req, res, ctx, static_cast<parent_context_t&>(ctx));
if (res.is_completed())
{
after_handler_call<CurrentMW, Context, parent_context_t>(std::get<N>(middlewares), req, res, ctx, static_cast<parent_context_t&>(ctx));
return true;
}
if (middleware_call_helper<CallCriteria, N + 1, Context, Container>(middlewares, req, res, ctx))
{
after_handler_call<CurrentMW, Context, parent_context_t>(std::get<N>(middlewares), req, res, ctx, static_cast<parent_context_t&>(ctx));
return true;
}
return false;
}
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
typename std::enable_if<(N >= std::tuple_size<typename std::remove_reference<Container>::type>::value), bool>::type
middleware_call_helper(Container& /*middlewares*/, request& /*req*/, response& /*res*/, Context& /*ctx*/)
{
return false;
}
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
typename std::enable_if<(N < 0)>::type
after_handlers_call_helper(Container& /*middlewares*/, Context& /*context*/, request& /*req*/, response& /*res*/)
{
}
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
typename std::enable_if<(N == 0)>::type after_handlers_call_helper(Container& middlewares, Context& ctx, request& req, response& res)
{
using parent_context_t = typename Context::template partial<N - 1>;
using CurrentMW = typename std::tuple_element<N, typename std::remove_reference<Container>::type>::type;
if (CallCriteria<CurrentMW>::value)
{
after_handler_call<CurrentMW, Context, parent_context_t>(std::get<N>(middlewares), req, res, ctx, static_cast<parent_context_t&>(ctx));
}
}
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
typename std::enable_if<(N > 0)>::type after_handlers_call_helper(Container& middlewares, Context& ctx, request& req, response& res)
{
using parent_context_t = typename Context::template partial<N - 1>;
using CurrentMW = typename std::tuple_element<N, typename std::remove_reference<Container>::type>::type;
if (CallCriteria<CurrentMW>::value)
{
after_handler_call<CurrentMW, Context, parent_context_t>(std::get<N>(middlewares), req, res, ctx, static_cast<parent_context_t&>(ctx));
}
after_handlers_call_helper<CallCriteria, N - 1, Context, Container>(middlewares, ctx, req, res);
}
// A CallCriteria that accepts only global middleware
template<typename MW>
struct middleware_call_criteria_only_global
{
template<typename C>
static std::false_type f(typename check_global_call_false<MW>::template get<C>*);
template<typename C>
static std::true_type f(...);
static const bool value = decltype(f<MW>(nullptr))::value;
};
template<typename F, typename... Args>
typename std::enable_if<black_magic::CallHelper<F, black_magic::S<Args...>>::value, void>::type
wrapped_handler_call(crow::request& /*req*/, crow::response& res, const F& f, Args&&... args)
{
static_assert(!std::is_same<void, decltype(f(std::declval<Args>()...))>::value,
"Handler function cannot have void return type; valid return types: string, int, crow::response, crow::returnable");
res = crow::response(f(std::forward<Args>(args)...));
res.end();
}
template<typename F, typename... Args>
typename std::enable_if<
!black_magic::CallHelper<F, black_magic::S<Args...>>::value &&
black_magic::CallHelper<F, black_magic::S<crow::request&, Args...>>::value,
void>::type
wrapped_handler_call(crow::request& req, crow::response& res, const F& f, Args&&... args)
{
static_assert(!std::is_same<void, decltype(f(std::declval<crow::request>(), std::declval<Args>()...))>::value,
"Handler function cannot have void return type; valid return types: string, int, crow::response, crow::returnable");
res = crow::response(f(req, std::forward<Args>(args)...));
res.end();
}
template<typename F, typename... Args>
typename std::enable_if<
!black_magic::CallHelper<F, black_magic::S<Args...>>::value &&
!black_magic::CallHelper<F, black_magic::S<crow::request&, Args...>>::value &&
black_magic::CallHelper<F, black_magic::S<crow::response&, Args...>>::value,
void>::type
wrapped_handler_call(crow::request& /*req*/, crow::response& res, const F& f, Args&&... args)
{
static_assert(std::is_same<void, decltype(f(std::declval<crow::response&>(), std::declval<Args>()...))>::value,
"Handler function with response argument should have void return type");
f(res, std::forward<Args>(args)...);
}
template<typename F, typename... Args>
typename std::enable_if<
!black_magic::CallHelper<F, black_magic::S<Args...>>::value &&
!black_magic::CallHelper<F, black_magic::S<crow::request&, Args...>>::value &&
!black_magic::CallHelper<F, black_magic::S<crow::response&, Args...>>::value &&
black_magic::CallHelper<F, black_magic::S<const crow::request&, crow::response&, Args...>>::value,
void>::type
wrapped_handler_call(crow::request& req, crow::response& res, const F& f, Args&&... args)
{
static_assert(std::is_same<void, decltype(f(std::declval<crow::request&>(), std::declval<crow::response&>(), std::declval<Args>()...))>::value,
"Handler function with response argument should have void return type");
f(req, res, std::forward<Args>(args)...);
}
// wrapped_handler_call transparently wraps a handler call behind (req, res, args...)
template<typename F, typename... Args>
typename std::enable_if<
!black_magic::CallHelper<F, black_magic::S<Args...>>::value &&
!black_magic::CallHelper<F, black_magic::S<crow::request&, Args...>>::value &&
!black_magic::CallHelper<F, black_magic::S<crow::response&, Args...>>::value &&
!black_magic::CallHelper<F, black_magic::S<const crow::request&, crow::response&, Args...>>::value,
void>::type
wrapped_handler_call(crow::request& req, crow::response& res, const F& f, Args&&... args)
{
static_assert(std::is_same<void, decltype(f(std::declval<crow::request&>(), std::declval<crow::response&>(), std::declval<Args>()...))>::value,
"Handler function with response argument should have void return type");
f(req, res, std::forward<Args>(args)...);
}
template<typename F, typename App, typename... Middlewares>
struct handler_middleware_wrapper
{
// CallCriteria bound to the current Middlewares pack
template<typename MW>
struct middleware_call_criteria
{
static constexpr bool value = black_magic::has_type<MW, std::tuple<Middlewares...>>::value;
};
template<typename... Args>
void operator()(crow::request& req, crow::response& res, Args&&... args) const
{
auto& ctx = *reinterpret_cast<typename App::context_t*>(req.middleware_context);
auto& container = *reinterpret_cast<typename App::mw_container_t*>(req.middleware_container);
auto glob_completion_handler = std::move(res.complete_request_handler_);
res.complete_request_handler_ = [] {};
middleware_call_helper<middleware_call_criteria,
0, typename App::context_t, typename App::mw_container_t>(container, req, res, ctx);
if (res.completed_)
{
glob_completion_handler();
return;
}
res.complete_request_handler_ = [&ctx, &container, &req, &res, &glob_completion_handler] {
after_handlers_call_helper<
middleware_call_criteria,
std::tuple_size<typename App::mw_container_t>::value - 1,
typename App::context_t,
typename App::mw_container_t>(container, ctx, req, res);
glob_completion_handler();
};
wrapped_handler_call(req, res, f, std::forward<Args>(args)...);
}
F f;
};
template<typename Route, typename App, typename... Middlewares>
struct handler_call_bridge
{
template<typename MW>
using check_app_contains = typename black_magic::has_type<MW, typename App::mw_container_t>;
static_assert(black_magic::all_true<(std::is_base_of<crow::ILocalMiddleware, Middlewares>::value)...>::value,
"Local middleware has to inherit crow::ILocalMiddleware");
static_assert(black_magic::all_true<(check_app_contains<Middlewares>::value)...>::value,
"Local middleware has to be listed in app middleware");
template<typename F>
void operator()(F&& f) const
{
auto wrapped = handler_middleware_wrapper<F, App, Middlewares...>{std::forward<F>(f)};
tptr->operator()(std::move(wrapped));
}
Route* tptr;
};
} // namespace detail
} // namespace crow
#pragma once
#include <boost/algorithm/string/predicate.hpp>
#include <boost/array.hpp>
namespace crow
{
namespace websocket
{
enum class WebSocketReadState
{
MiniHeader,
Len16,
Len64,
Mask,
Payload,
};
/// A base class for websocket connection.
struct connection
{
virtual void send_binary(const std::string& msg) = 0;
virtual void send_text(const std::string& msg) = 0;
virtual void send_ping(const std::string& msg) = 0;
virtual void send_pong(const std::string& msg) = 0;
virtual void close(const std::string& msg = "quit") = 0;
virtual std::string get_remote_ip() = 0;
virtual ~connection() {}
void userdata(void* u) { userdata_ = u; }
void* userdata() { return userdata_; }
private:
void* userdata_;
};
// Modified version of the illustration in RFC6455 Section-5.2
//
//
// 0 1 2 3 -byte
// 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 -bit
// +-+-+-+-+-------+-+-------------+-------------------------------+
// |F|R|R|R| opcode|M| Payload len | Extended payload length |
// |I|S|S|S| (4) |A| (7) | (16/64) |
// |N|V|V|V| |S| | (if payload len==126/127) |
// | |1|2|3| |K| | |
// +-+-+-+-+-------+-+-------------+ - - - - - - - - - - - - - - - +
// | Extended payload length continued, if payload len == 127 |
// + - - - - - - - - - - - - - - - +-------------------------------+
// | |Masking-key, if MASK set to 1 |
// +-------------------------------+-------------------------------+
// | Masking-key (continued) | Payload Data |
// +-------------------------------- - - - - - - - - - - - - - - - +
// : Payload Data continued ... :
// + - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - +
// | Payload Data continued ... |
// +---------------------------------------------------------------+
//
/// A websocket connection.
template<typename Adaptor>
class Connection : public connection
{
public:
/// Constructor for a connection.
///
/// Requires a request with an "Upgrade: websocket" header.<br>
/// Automatically handles the handshake.
Connection(const crow::request& req, Adaptor&& adaptor,
std::function<void(crow::websocket::connection&)> open_handler,
std::function<void(crow::websocket::connection&, const std::string&, bool)> message_handler,
std::function<void(crow::websocket::connection&, const std::string&)> close_handler,
std::function<void(crow::websocket::connection&)> error_handler,
std::function<bool(const crow::request&)> accept_handler):
adaptor_(std::move(adaptor)),
open_handler_(std::move(open_handler)), message_handler_(std::move(message_handler)), close_handler_(std::move(close_handler)), error_handler_(std::move(error_handler)), accept_handler_(std::move(accept_handler))
{
if (!boost::iequals(req.get_header_value("upgrade"), "websocket"))
{
adaptor.close();
delete this;
return;
}
if (accept_handler_)
{
if (!accept_handler_(req))
{
adaptor.close();
delete this;
return;
}
}
// Sec-WebSocket-Key: dGhlIHNhbXBsZSBub25jZQ==
// Sec-WebSocket-Version: 13
std::string magic = req.get_header_value("Sec-WebSocket-Key") + "258EAFA5-E914-47DA-95CA-C5AB0DC85B11";
sha1::SHA1 s;
s.processBytes(magic.data(), magic.size());
uint8_t digest[20];
s.getDigestBytes(digest);
start(crow::utility::base64encode((unsigned char*)digest, 20));
}
/// Send data through the socket.
template<typename CompletionHandler>
void dispatch(CompletionHandler handler)
{
adaptor_.get_io_service().dispatch(handler);
}
/// Send data through the socket and return immediately.
template<typename CompletionHandler>
void post(CompletionHandler handler)
{
adaptor_.get_io_service().post(handler);
}
/// Send a "Ping" message.
///
/// Usually invoked to check if the other point is still online.
void send_ping(const std::string& msg) override
{
dispatch([this, msg] {
auto header = build_header(0x9, msg.size());
write_buffers_.emplace_back(std::move(header));
write_buffers_.emplace_back(msg);
do_write();
});
}
/// Send a "Pong" message.
///
/// Usually automatically invoked as a response to a "Ping" message.
void send_pong(const std::string& msg) override
{
dispatch([this, msg] {
auto header = build_header(0xA, msg.size());
write_buffers_.emplace_back(std::move(header));
write_buffers_.emplace_back(msg);
do_write();
});
}
/// Send a binary encoded message.
void send_binary(const std::string& msg) override
{
dispatch([this, msg] {
auto header = build_header(2, msg.size());
write_buffers_.emplace_back(std::move(header));
write_buffers_.emplace_back(msg);
do_write();
});
}
/// Send a plaintext message.
void send_text(const std::string& msg) override
{
dispatch([this, msg] {
auto header = build_header(1, msg.size());
write_buffers_.emplace_back(std::move(header));
write_buffers_.emplace_back(msg);
do_write();
});
}
/// Send a close signal.
///
/// Sets a flag to destroy the object once the message is sent.
void close(const std::string& msg) override
{
dispatch([this, msg] {
has_sent_close_ = true;
if (has_recv_close_ && !is_close_handler_called_)
{
is_close_handler_called_ = true;
if (close_handler_)
close_handler_(*this, msg);
}
auto header = build_header(0x8, msg.size());
write_buffers_.emplace_back(std::move(header));
write_buffers_.emplace_back(msg);
do_write();
});
}
std::string get_remote_ip() override
{
return adaptor_.remote_endpoint().address().to_string();
}
protected:
/// Generate the websocket headers using an opcode and the message size (in bytes).
std::string build_header(int opcode, size_t size)
{
char buf[2 + 8] = "\x80\x00";
buf[0] += opcode;
if (size < 126)
{
buf[1] += static_cast<char>(size);
return {buf, buf + 2};
}
else if (size < 0x10000)
{
buf[1] += 126;
*(uint16_t*)(buf + 2) = htons(static_cast<uint16_t>(size));
return {buf, buf + 4};
}
else
{
buf[1] += 127;
*reinterpret_cast<uint64_t*>(buf + 2) = ((1 == htonl(1)) ? static_cast<uint64_t>(size) : (static_cast<uint64_t>(htonl((size)&0xFFFFFFFF)) << 32) | htonl(static_cast<uint64_t>(size) >> 32));
return {buf, buf + 10};
}
}
/// Send the HTTP upgrade response.
///
/// Finishes the handshake process, then starts reading messages from the socket.
void start(std::string&& hello)
{
static std::string header = "HTTP/1.1 101 Switching Protocols\r\n"
"Upgrade: websocket\r\n"
"Connection: Upgrade\r\n"
"Sec-WebSocket-Accept: ";
write_buffers_.emplace_back(header);
write_buffers_.emplace_back(std::move(hello));
write_buffers_.emplace_back(crlf);
write_buffers_.emplace_back(crlf);
do_write();
if (open_handler_)
open_handler_(*this);
do_read();
}
/// Read a websocket message.
///
/// Involves:<br>
/// Handling headers (opcodes, size).<br>
/// Unmasking the payload.<br>
/// Reading the actual payload.<br>
void do_read()
{
is_reading = true;
switch (state_)
{
case WebSocketReadState::MiniHeader:
{
mini_header_ = 0;
//boost::asio::async_read(adaptor_.socket(), boost::asio::buffer(&mini_header_, 1),
adaptor_.socket().async_read_some(
boost::asio::buffer(&mini_header_, 2),
[this](const boost::system::error_code& ec, std::size_t
#ifdef CROW_ENABLE_DEBUG
bytes_transferred
#endif
)
{
is_reading = false;
mini_header_ = ntohs(mini_header_);
#ifdef CROW_ENABLE_DEBUG
if (!ec && bytes_transferred != 2)
{
throw std::runtime_error("WebSocket:MiniHeader:async_read fail:asio bug?");
}
#endif
if (!ec)
{
if ((mini_header_ & 0x80) == 0x80)
has_mask_ = true;
else //if the websocket specification is enforced and the message isn't masked, terminate the connection
{
#ifndef CROW_ENFORCE_WS_SPEC
has_mask_ = false;
#else
close_connection_ = true;
adaptor_.close();
if (error_handler_)
error_handler_(*this);
check_destroy();
#endif
}
if ((mini_header_ & 0x7f) == 127)
{
state_ = WebSocketReadState::Len64;
}
else if ((mini_header_ & 0x7f) == 126)
{
state_ = WebSocketReadState::Len16;
}
else
{
remaining_length_ = mini_header_ & 0x7f;
state_ = WebSocketReadState::Mask;
}
do_read();
}
else
{
close_connection_ = true;
adaptor_.close();
if (error_handler_)
error_handler_(*this);
check_destroy();
}
});
}
break;
case WebSocketReadState::Len16:
{
remaining_length_ = 0;
remaining_length16_ = 0;
boost::asio::async_read(
adaptor_.socket(), boost::asio::buffer(&remaining_length16_, 2),
[this](const boost::system::error_code& ec, std::size_t
#ifdef CROW_ENABLE_DEBUG
bytes_transferred
#endif
) {
is_reading = false;
remaining_length16_ = ntohs(remaining_length16_);
remaining_length_ = remaining_length16_;
#ifdef CROW_ENABLE_DEBUG
if (!ec && bytes_transferred != 2)
{
throw std::runtime_error("WebSocket:Len16:async_read fail:asio bug?");
}
#endif
if (!ec)
{
state_ = WebSocketReadState::Mask;
do_read();
}
else
{
close_connection_ = true;
adaptor_.close();
if (error_handler_)
error_handler_(*this);
check_destroy();
}
});
}
break;
case WebSocketReadState::Len64:
{
boost::asio::async_read(
adaptor_.socket(), boost::asio::buffer(&remaining_length_, 8),
[this](const boost::system::error_code& ec, std::size_t
#ifdef CROW_ENABLE_DEBUG
bytes_transferred
#endif
) {
is_reading = false;
remaining_length_ = ((1 == ntohl(1)) ? (remaining_length_) : (static_cast<uint64_t>(ntohl((remaining_length_)&0xFFFFFFFF)) << 32) | ntohl((remaining_length_) >> 32));
#ifdef CROW_ENABLE_DEBUG
if (!ec && bytes_transferred != 8)
{
throw std::runtime_error("WebSocket:Len16:async_read fail:asio bug?");
}
#endif
if (!ec)
{
state_ = WebSocketReadState::Mask;
do_read();
}
else
{
close_connection_ = true;
adaptor_.close();
if (error_handler_)
error_handler_(*this);
check_destroy();
}
});
}
break;
case WebSocketReadState::Mask:
if (has_mask_)
{
boost::asio::async_read(
adaptor_.socket(), boost::asio::buffer((char*)&mask_, 4),
[this](const boost::system::error_code& ec, std::size_t
#ifdef CROW_ENABLE_DEBUG
bytes_transferred
#endif
) {
is_reading = false;
#ifdef CROW_ENABLE_DEBUG
if (!ec && bytes_transferred != 4)
{
throw std::runtime_error("WebSocket:Mask:async_read fail:asio bug?");
}
#endif
if (!ec)
{
state_ = WebSocketReadState::Payload;
do_read();
}
else
{
close_connection_ = true;
if (error_handler_)
error_handler_(*this);
adaptor_.close();
}
});
}
else
{
state_ = WebSocketReadState::Payload;
do_read();
}
break;
case WebSocketReadState::Payload:
{
auto to_read = static_cast<std::uint64_t>(buffer_.size());
if (remaining_length_ < to_read)
to_read = remaining_length_;
adaptor_.socket().async_read_some(
boost::asio::buffer(buffer_, static_cast<std::size_t>(to_read)),
[this](const boost::system::error_code& ec, std::size_t bytes_transferred) {
is_reading = false;
if (!ec)
{
fragment_.insert(fragment_.end(), buffer_.begin(), buffer_.begin() + bytes_transferred);
remaining_length_ -= bytes_transferred;
if (remaining_length_ == 0)
{
handle_fragment();
state_ = WebSocketReadState::MiniHeader;
do_read();
}
else
do_read();
}
else
{
close_connection_ = true;
if (error_handler_)
error_handler_(*this);
adaptor_.close();
}
});
}
break;
}
}
/// Check if the FIN bit is set.
bool is_FIN()
{
return mini_header_ & 0x8000;
}
/// Extract the opcode from the header.
int opcode()
{
return (mini_header_ & 0x0f00) >> 8;
}
/// Process the payload fragment.
///
/// Unmasks the fragment, checks the opcode, merges fragments into 1 message body, and calls the appropriate handler.
void handle_fragment()
{
if (has_mask_)
{
for (decltype(fragment_.length()) i = 0; i < fragment_.length(); i++)
{
fragment_[i] ^= ((char*)&mask_)[i % 4];
}
}
switch (opcode())
{
case 0: // Continuation
{
message_ += fragment_;
if (is_FIN())
{
if (message_handler_)
message_handler_(*this, message_, is_binary_);
message_.clear();
}
}
break;
case 1: // Text
{
is_binary_ = false;
message_ += fragment_;
if (is_FIN())
{
if (message_handler_)
message_handler_(*this, message_, is_binary_);
message_.clear();
}
}
break;
case 2: // Binary
{
is_binary_ = true;
message_ += fragment_;
if (is_FIN())
{
if (message_handler_)
message_handler_(*this, message_, is_binary_);
message_.clear();
}
}
break;
case 0x8: // Close
{
has_recv_close_ = true;
if (!has_sent_close_)
{
close(fragment_);
}
else
{
adaptor_.close();
close_connection_ = true;
if (!is_close_handler_called_)
{
if (close_handler_)
close_handler_(*this, fragment_);
is_close_handler_called_ = true;
}
check_destroy();
}
}
break;
case 0x9: // Ping
{
send_pong(fragment_);
}
break;
case 0xA: // Pong
{
pong_received_ = true;
}
break;
}
fragment_.clear();
}
/// Send the buffers' data through the socket.
///
/// Also destroyes the object if the Close flag is set.
void do_write()
{
if (sending_buffers_.empty())
{
sending_buffers_.swap(write_buffers_);
std::vector<boost::asio::const_buffer> buffers;
buffers.reserve(sending_buffers_.size());
for (auto& s : sending_buffers_)
{
buffers.emplace_back(boost::asio::buffer(s));
}
boost::asio::async_write(
adaptor_.socket(), buffers,
[&](const boost::system::error_code& ec, std::size_t /*bytes_transferred*/) {
sending_buffers_.clear();
if (!ec && !close_connection_)
{
if (!write_buffers_.empty())
do_write();
if (has_sent_close_)
close_connection_ = true;
}
else
{
close_connection_ = true;
check_destroy();
}
});
}
}
/// Destroy the Connection.
void check_destroy()
{
//if (has_sent_close_ && has_recv_close_)
if (!is_close_handler_called_)
if (close_handler_)
close_handler_(*this, "uncleanly");
if (sending_buffers_.empty() && !is_reading)
delete this;
}
private:
Adaptor adaptor_;
std::vector<std::string> sending_buffers_;
std::vector<std::string> write_buffers_;
boost::array<char, 4096> buffer_;
bool is_binary_;
std::string message_;
std::string fragment_;
WebSocketReadState state_{WebSocketReadState::MiniHeader};
uint16_t remaining_length16_{0};
uint64_t remaining_length_{0};
bool close_connection_{false};
bool is_reading{false};
bool has_mask_{false};
uint32_t mask_;
uint16_t mini_header_;
bool has_sent_close_{false};
bool has_recv_close_{false};
bool error_occured_{false};
bool pong_received_{false};
bool is_close_handler_called_{false};
std::function<void(crow::websocket::connection&)> open_handler_;
std::function<void(crow::websocket::connection&, const std::string&, bool)> message_handler_;
std::function<void(crow::websocket::connection&, const std::string&)> close_handler_;
std::function<void(crow::websocket::connection&)> error_handler_;
std::function<bool(const crow::request&)> accept_handler_;
};
} // namespace websocket
} // namespace crow
/* merged revision: 5b951d74bd66ec9d38448e0a85b1cf8b85d97db3 */
/* updated to : e13b274770da9b82a1085dec29182acfea72e7a7 (beyond v2.9.5) */
/* commits not included:
* 091ebb87783a58b249062540bbea07de2a11e9cf
* 6132d1fefa03f769a3979355d1f5da0b8889cad2
* 7ba312397c2a6c851a4b5efe6c1603b1e1bda6ff
* d7675453a6c03180572f084e95eea0d02df39164
* dff604db203986e532e5a679bafd0e7382c6bdd9 (Might be useful to actually add [upgrade requests with a body])
* e01811e7f4894d7f0f7f4bd8492cccec6f6b4038 (related to above)
* 05525c5fde1fc562481f6ae08fa7056185325daf (also related to above)
* 350258965909f249f9c59823aac240313e0d0120 (cannot be implemented due to upgrade)
*/
// clang-format off
#pragma once
namespace crow
{
extern "C" {
#include <stddef.h>
#if defined(_WIN32) && !defined(__MINGW32__) && \
(!defined(_MSC_VER) || _MSC_VER<1600) && !defined(__WINE__)
#include <BaseTsd.h>
typedef __int8 int8_t;
typedef unsigned __int8 uint8_t;
typedef __int16 int16_t;
typedef unsigned __int16 uint16_t;
typedef __int32 int32_t;
typedef unsigned __int32 uint32_t;
typedef __int64 int64_t;
typedef unsigned __int64 uint64_t;
#elif (defined(__sun) || defined(__sun__)) && defined(__SunOS_5_9)
#include <sys/inttypes.h>
#else
#include <stdint.h>
#endif
/* Maximium header size allowed. If the macro is not defined
* before including this header then the default is used. To
* change the maximum header size, define the macro in the build
* environment (e.g. -DHTTP_MAX_HEADER_SIZE=<value>). To remove
* the effective limit on the size of the header, define the macro
* to a very large number (e.g. -DCROW_HTTP_MAX_HEADER_SIZE=0x7fffffff)
*/
#ifndef CROW_HTTP_MAX_HEADER_SIZE
# define CROW_HTTP_MAX_HEADER_SIZE (80*1024)
#endif
typedef struct http_parser http_parser;
typedef struct http_parser_settings http_parser_settings;
/* Callbacks should return non-zero to indicate an error. The parser will
* then halt execution.
*
* The one exception is on_headers_complete. In a HTTP_RESPONSE parser
* returning '1' from on_headers_complete will tell the parser that it
* should not expect a body. This is used when receiving a response to a
* HEAD request which may contain 'Content-Length' or 'Transfer-Encoding:
* chunked' headers that indicate the presence of a body.
*
* Returning `2` from on_headers_complete will tell parser that it should not
* expect neither a body nor any futher responses on this connection. This is
* useful for handling responses to a CONNECT request which may not contain
* `Upgrade` or `Connection: upgrade` headers.
*
* http_data_cb does not return data chunks. It will be called arbitrarally
* many times for each string. E.G. you might get 10 callbacks for "on_url"
* each providing just a few characters more data.
*/
typedef int (*http_data_cb) (http_parser*, const char *at, size_t length);
typedef int (*http_cb) (http_parser*);
/* Flag values for http_parser.flags field */
enum http_connection_flags // This is basically 7 booleans placed into 1 integer. Uses 4 bytes instead of n bytes (7 currently).
{ F_CHUNKED = 1 << 0 // 00000000 00000000 00000000 00000001
, F_CONNECTION_KEEP_ALIVE = 1 << 1 // 00000000 00000000 00000000 00000010
, F_CONNECTION_CLOSE = 1 << 2 // 00000000 00000000 00000000 00000100
, F_TRAILING = 1 << 3 // 00000000 00000000 00000000 00001000
, F_UPGRADE = 1 << 4 // 00000000 00000000 00000000 00010000
, F_SKIPBODY = 1 << 5 // 00000000 00000000 00000000 00100000
, F_CONTENTLENGTH = 1 << 6 // 00000000 00000000 00000000 01000000
};
/* Map for errno-related constants
*
* The provided argument should be a macro that takes 2 arguments.
*/
#define CROW_HTTP_ERRNO_MAP(CROW_XX) \
/* No error */ \
CROW_XX(OK, "success") \
\
/* Callback-related errors */ \
CROW_XX(CB_message_begin, "the on_message_begin callback failed") \
CROW_XX(CB_url, "the \"on_url\" callback failed") \
CROW_XX(CB_header_field, "the \"on_header_field\" callback failed") \
CROW_XX(CB_header_value, "the \"on_header_value\" callback failed") \
CROW_XX(CB_headers_complete, "the \"on_headers_complete\" callback failed") \
CROW_XX(CB_body, "the \"on_body\" callback failed") \
CROW_XX(CB_message_complete, "the \"on_message_complete\" callback failed") \
CROW_XX(CB_status, "the \"on_status\" callback failed") \
\
/* Parsing-related errors */ \
CROW_XX(INVALID_EOF_STATE, "stream ended at an unexpected time") \
CROW_XX(HEADER_OVERFLOW, "too many header bytes seen; overflow detected") \
CROW_XX(CLOSED_CONNECTION, "data received after completed connection: close message") \
CROW_XX(INVALID_VERSION, "invalid HTTP version") \
CROW_XX(INVALID_STATUS, "invalid HTTP status code") \
CROW_XX(INVALID_METHOD, "invalid HTTP method") \
CROW_XX(INVALID_URL, "invalid URL") \
CROW_XX(INVALID_HOST, "invalid host") \
CROW_XX(INVALID_PORT, "invalid port") \
CROW_XX(INVALID_PATH, "invalid path") \
CROW_XX(INVALID_QUERY_STRING, "invalid query string") \
CROW_XX(INVALID_FRAGMENT, "invalid fragment") \
CROW_XX(LF_EXPECTED, "LF character expected") \
CROW_XX(INVALID_HEADER_TOKEN, "invalid character in header") \
CROW_XX(INVALID_CONTENT_LENGTH, "invalid character in content-length header") \
CROW_XX(UNEXPECTED_CONTENT_LENGTH, "unexpected content-length header") \
CROW_XX(INVALID_CHUNK_SIZE, "invalid character in chunk size header") \
CROW_XX(INVALID_CONSTANT, "invalid constant string") \
CROW_XX(INVALID_INTERNAL_STATE, "encountered unexpected internal state") \
CROW_XX(STRICT, "strict mode assertion failed") \
CROW_XX(UNKNOWN, "an unknown error occurred") \
CROW_XX(INVALID_TRANSFER_ENCODING, "request has invalid transfer-encoding") \
/* Define CHPE_* values for each errno value above */
#define CROW_HTTP_ERRNO_GEN(n, s) CHPE_##n,
enum http_errno {
CROW_HTTP_ERRNO_MAP(CROW_HTTP_ERRNO_GEN)
};
#undef CROW_HTTP_ERRNO_GEN
/* Get an http_errno value from an http_parser */
#define CROW_HTTP_PARSER_ERRNO(p) ((enum http_errno)(p)->http_errno)
struct http_parser
{
/** PRIVATE **/
unsigned int flags : 7; /* F_* values from 'flags' enum; semi-public */
unsigned int state : 8; /* enum state from http_parser.c */
unsigned int header_state : 7; /* enum header_state from http_parser.c */
unsigned int index : 5; /* index into current matcher */
unsigned int uses_transfer_encoding : 1; /* Transfer-Encoding header is present */
unsigned int allow_chunked_length : 1; /* Allow headers with both `Content-Length` and `Transfer-Encoding: chunked` set */
unsigned int lenient_http_headers : 1;
uint32_t nread; /* # bytes read in various scenarios */
uint64_t content_length; /* # bytes in body. `(uint64_t) -1` (all bits one) if no Content-Length header. */
unsigned long qs_point;
/** READ-ONLY **/
unsigned char http_major;
unsigned char http_minor;
unsigned int method : 8; /* requests only */
unsigned int http_errno : 7;
/* 1 = Upgrade header was present and the parser has exited because of that.
* 0 = No upgrade header present.
* Should be checked when http_parser_execute() returns in addition to
* error checking.
*/
unsigned int upgrade : 1;
/** PUBLIC **/
void* data; /* A pointer to get hook to the "connection" or "socket" object */
};
struct http_parser_settings
{
http_cb on_message_begin;
http_data_cb on_url;
http_data_cb on_header_field;
http_data_cb on_header_value;
http_cb on_headers_complete;
http_data_cb on_body;
http_cb on_message_complete;
};
// SOURCE (.c) CODE
#include <assert.h>
#include <stddef.h>
#include <ctype.h>
#include <string.h>
#include <limits.h>
static uint32_t max_header_size = CROW_HTTP_MAX_HEADER_SIZE;
#ifndef CROW_ULLONG_MAX
# define CROW_ULLONG_MAX ((uint64_t) -1) /* 2^64-1 */
#endif
#ifndef CROW_MIN
# define CROW_MIN(a,b) ((a) < (b) ? (a) : (b))
#endif
#ifndef CROW_ARRAY_SIZE
# define CROW_ARRAY_SIZE(a) (sizeof(a) / sizeof((a)[0]))
#endif
#ifndef CROW_BIT_AT
# define CROW_BIT_AT(a, i) \
(!!((unsigned int) (a)[(unsigned int) (i) >> 3] & \
(1 << ((unsigned int) (i) & 7))))
#endif
#define CROW_SET_ERRNO(e) \
do { \
parser->nread = nread; \
parser->http_errno = (e); \
} while(0)
/* Run the notify callback FOR, returning ER if it fails */
#define CROW_CALLBACK_NOTIFY_(FOR, ER) \
do { \
assert(CROW_HTTP_PARSER_ERRNO(parser) == CHPE_OK); \
\
if (CROW_LIKELY(settings->on_##FOR)) { \
if (CROW_UNLIKELY(0 != settings->on_##FOR(parser))) { \
CROW_SET_ERRNO(CHPE_CB_##FOR); \
} \
\
/* We either errored above or got paused; get out */ \
if (CROW_UNLIKELY(CROW_HTTP_PARSER_ERRNO(parser) != CHPE_OK)) { \
return (ER); \
} \
} \
} while (0)
/* Run the notify callback FOR and consume the current byte */
#define CROW_CALLBACK_NOTIFY(FOR) CROW_CALLBACK_NOTIFY_(FOR, p - data + 1)
/* Run the notify callback FOR and don't consume the current byte */
#define CROW_CALLBACK_NOTIFY_NOADVANCE(FOR) CROW_CALLBACK_NOTIFY_(FOR, p - data)
/* Run data callback FOR with LEN bytes, returning ER if it fails */
#define CROW_CALLBACK_DATA_(FOR, LEN, ER) \
do { \
assert(CROW_HTTP_PARSER_ERRNO(parser) == CHPE_OK); \
\
if (FOR##_mark) { \
if (CROW_LIKELY(settings->on_##FOR)) { \
if (CROW_UNLIKELY(0 != \
settings->on_##FOR(parser, FOR##_mark, (LEN)))) { \
CROW_SET_ERRNO(CHPE_CB_##FOR); \
} \
\
/* We either errored above or got paused; get out */ \
if (CROW_UNLIKELY(CROW_HTTP_PARSER_ERRNO(parser) != CHPE_OK)) {\
return (ER); \
} \
} \
FOR##_mark = NULL; \
} \
} while (0)
/* Run the data callback FOR and consume the current byte */
#define CROW_CALLBACK_DATA(FOR) \
CROW_CALLBACK_DATA_(FOR, p - FOR##_mark, p - data + 1)
/* Run the data callback FOR and don't consume the current byte */
#define CROW_CALLBACK_DATA_NOADVANCE(FOR) \
CROW_CALLBACK_DATA_(FOR, p - FOR##_mark, p - data)
/* Set the mark FOR; non-destructive if mark is already set */
#define CROW_MARK(FOR) \
do { \
if (!FOR##_mark) { \
FOR##_mark = p; \
} \
} while (0)
/* Don't allow the total size of the HTTP headers (including the status
* line) to exceed max_header_size. This check is here to protect
* embedders against denial-of-service attacks where the attacker feeds
* us a never-ending header that the embedder keeps buffering.
*
* This check is arguably the responsibility of embedders but we're doing
* it on the embedder's behalf because most won't bother and this way we
* make the web a little safer. max_header_size is still far bigger
* than any reasonable request or response so this should never affect
* day-to-day operation.
*/
#define CROW_COUNT_HEADER_SIZE(V) \
do { \
nread += (uint32_t)(V); \
if (CROW_UNLIKELY(nread > max_header_size)) { \
CROW_SET_ERRNO(CHPE_HEADER_OVERFLOW); \
goto error; \
} \
} while (0)
#define CROW_REEXECUTE() \
goto reexecute; \
#define CROW_PROXY_CONNECTION "proxy-connection"
#define CROW_CONNECTION "connection"
#define CROW_CONTENT_LENGTH "content-length"
#define CROW_TRANSFER_ENCODING "transfer-encoding"
#define CROW_UPGRADE "upgrade"
#define CROW_CHUNKED "chunked"
#define CROW_KEEP_ALIVE "keep-alive"
#define CROW_CLOSE "close"
enum state
{
s_dead = 1 /* important that this is > 0 */
,
s_start_req
,
s_req_method,
s_req_spaces_before_url,
s_req_schema,
s_req_schema_slash,
s_req_schema_slash_slash,
s_req_server_start,
s_req_server, // }
s_req_server_with_at, // |
s_req_path, // | The parser recognizes how to switch between these states,
s_req_query_string_start, // | however it doesn't process them any differently.
s_req_query_string, // }
s_req_http_start,
s_req_http_H,
s_req_http_HT,
s_req_http_HTT,
s_req_http_HTTP,
s_req_http_I,
s_req_http_IC,
s_req_http_major,
s_req_http_dot,
s_req_http_minor,
s_req_http_end,
s_req_line_almost_done
,
s_header_field_start,
s_header_field,
s_header_value_discard_ws,
s_header_value_discard_ws_almost_done,
s_header_value_discard_lws,
s_header_value_start,
s_header_value,
s_header_value_lws
,
s_header_almost_done
,
s_chunk_size_start,
s_chunk_size,
s_chunk_parameters,
s_chunk_size_almost_done
,
s_headers_almost_done,
s_headers_done
/* Important: 's_headers_done' must be the last 'header' state. All
* states beyond this must be 'body' states. It is used for overflow
* checking. See the CROW_PARSING_HEADER() macro.
*/
,
s_chunk_data,
s_chunk_data_almost_done,
s_chunk_data_done
,
s_body_identity,
s_body_identity_eof
,
s_message_done
};
#define CROW_PARSING_HEADER(state) (state <= s_headers_done)
enum header_states
{ h_general = 0
, h_C
, h_CO
, h_CON
, h_matching_connection
, h_matching_proxy_connection
, h_matching_content_length
, h_matching_transfer_encoding
, h_matching_upgrade
, h_connection
, h_content_length
, h_content_length_num
, h_content_length_ws
, h_transfer_encoding
, h_upgrade
, h_matching_transfer_encoding_token_start
, h_matching_transfer_encoding_chunked
, h_matching_transfer_encoding_token
, h_matching_connection_keep_alive
, h_matching_connection_close
, h_transfer_encoding_chunked
, h_connection_keep_alive
, h_connection_close
};
enum http_host_state
{
s_http_host_dead = 1
, s_http_userinfo_start
, s_http_userinfo
, s_http_host_start
, s_http_host_v6_start
, s_http_host
, s_http_host_v6
, s_http_host_v6_end
, s_http_host_v6_zone_start
, s_http_host_v6_zone
, s_http_host_port_start
, s_http_host_port
};
/* Macros for character classes; depends on strict-mode */
#define CROW_LOWER(c) (unsigned char)(c | 0x20)
#define CROW_IS_ALPHA(c) (CROW_LOWER(c) >= 'a' && CROW_LOWER(c) <= 'z')
#define CROW_IS_NUM(c) ((c) >= '0' && (c) <= '9')
#define CROW_IS_ALPHANUM(c) (CROW_IS_ALPHA(c) || CROW_IS_NUM(c))
//#define CROW_IS_HEX(c) (CROW_IS_NUM(c) || (CROW_LOWER(c) >= 'a' && CROW_LOWER(c) <= 'f'))
#define CROW_IS_MARK(c) ((c) == '-' || (c) == '_' || (c) == '.' || \
(c) == '!' || (c) == '~' || (c) == '*' || (c) == '\'' || (c) == '(' || \
(c) == ')')
#define CROW_IS_USERINFO_CHAR(c) (CROW_IS_ALPHANUM(c) || CROW_IS_MARK(c) || (c) == '%' || \
(c) == ';' || (c) == ':' || (c) == '&' || (c) == '=' || (c) == '+' || \
(c) == '$' || (c) == ',')
#define CROW_TOKEN(c) (tokens[(unsigned char)c])
#define CROW_IS_URL_CHAR(c) (CROW_BIT_AT(normal_url_char, (unsigned char)c))
//#define CROW_IS_HOST_CHAR(c) (CROW_IS_ALPHANUM(c) || (c) == '.' || (c) == '-')
/**
* Verify that a char is a valid visible (printable) US-ASCII
* character or %x80-FF
**/
#define CROW_IS_HEADER_CHAR(ch) \
(ch == cr || ch == lf || ch == 9 || ((unsigned char)ch > 31 && ch != 127))
#define CROW_start_state s_start_req
# define CROW_STRICT_CHECK(cond) \
do { \
if (cond) { \
CROW_SET_ERRNO(CHPE_STRICT); \
goto error; \
} \
} while (0)
#define CROW_NEW_MESSAGE() (CROW_start_state)
/* Our URL parser.
*
* This is designed to be shared by http_parser_execute() for URL validation,
* hence it has a state transition + byte-for-byte interface. In addition, it
* is meant to be embedded in http_parser_parse_url(), which does the dirty
* work of turning state transitions URL components for its API.
*
* This function should only be invoked with non-space characters. It is
* assumed that the caller cares about (and can detect) the transition between
* URL and non-URL states by looking for these.
*/
inline enum state
parse_url_char(enum state s, const char ch, http_parser *parser, const char* url_mark, const char* p)
{
# define CROW_T(v) 0
static const uint8_t normal_url_char[32] = {
/* 0 nul 1 soh 2 stx 3 etx 4 eot 5 enq 6 ack 7 bel */
0 | 0 | 0 | 0 | 0 | 0 | 0 | 0,
/* 8 bs 9 ht 10 nl 11 vt 12 np 13 cr 14 so 15 si */
0 |CROW_T(2)| 0 | 0 |CROW_T(16)| 0 | 0 | 0,
/* 16 dle 17 dc1 18 dc2 19 dc3 20 dc4 21 nak 22 syn 23 etb */
0 | 0 | 0 | 0 | 0 | 0 | 0 | 0,
/* 24 can 25 em 26 sub 27 esc 28 fs 29 gs 30 rs 31 us */
0 | 0 | 0 | 0 | 0 | 0 | 0 | 0,
/* 32 sp 33 ! 34 " 35 # 36 $ 37 % 38 & 39 ' */
0 | 2 | 4 | 0 | 16 | 32 | 64 | 128,
/* 40 ( 41 ) 42 * 43 + 44 , 45 - 46 . 47 / */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 48 0 49 1 50 2 51 3 52 4 53 5 54 6 55 7 */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 56 8 57 9 58 : 59 ; 60 < 61 = 62 > 63 ? */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 0,
/* 64 @ 65 A 66 B 67 C 68 D 69 E 70 F 71 G */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 72 H 73 I 74 J 75 K 76 L 77 M 78 N 79 O */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 80 P 81 Q 82 R 83 S 84 CROW_T 85 U 86 V 87 W */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 88 X 89 Y 90 Z 91 [ 92 \ 93 ] 94 ^ 95 _ */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 96 ` 97 a 98 b 99 c 100 d 101 e 102 f 103 g */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 104 h 105 i 106 j 107 k 108 l 109 m 110 n 111 o */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 112 p 113 q 114 r 115 s 116 t 117 u 118 v 119 w */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 128,
/* 120 x 121 y 122 z 123 { 124 | 125 } 126 ~ 127 del */
1 | 2 | 4 | 8 | 16 | 32 | 64 | 0, };
#undef CROW_T
if (ch == ' ' || ch == '\r' || ch == '\n') {
return s_dead;
}
if (ch == '\t' || ch == '\f') {
return s_dead;
}
switch (s) {
case s_req_spaces_before_url:
/* Proxied requests are followed by scheme of an absolute URI (alpha).
* All methods except CONNECT are followed by '/' or '*'.
*/
if (ch == '/' || ch == '*') {
return s_req_path;
}
if (CROW_IS_ALPHA(ch)) {
return s_req_schema;
}
break;
case s_req_schema:
if (CROW_IS_ALPHA(ch)) {
return s;
}
if (ch == ':') {
return s_req_schema_slash;
}
break;
case s_req_schema_slash:
if (ch == '/') {
return s_req_schema_slash_slash;
}
break;
case s_req_schema_slash_slash:
if (ch == '/') {
return s_req_server_start;
}
break;
case s_req_server_with_at:
if (ch == '@') {
return s_dead;
}
/* fall through */
case s_req_server_start:
case s_req_server:
if (ch == '/') {
return s_req_path;
}
if (ch == '?') {
parser->qs_point = p - url_mark;
return s_req_query_string_start;
}
if (ch == '@') {
return s_req_server_with_at;
}
if (CROW_IS_USERINFO_CHAR(ch) || ch == '[' || ch == ']') {
return s_req_server;
}
break;
case s_req_path:
if (CROW_IS_URL_CHAR(ch)) {
return s;
}
else if (ch == '?')
{
parser->qs_point = p - url_mark;
return s_req_query_string_start;
}
break;
case s_req_query_string_start:
case s_req_query_string:
if (CROW_IS_URL_CHAR(ch)) {
return s_req_query_string;
}
else if (ch == '?')
{
return s_req_query_string;
}
break;
default:
break;
}
/* We should never fall out of the switch above unless there's an error */
return s_dead;
}
inline size_t http_parser_execute (http_parser *parser,
const http_parser_settings *settings,
const char *data,
size_t len)
{
/* Tokens as defined by rfc 2616. Also lowercases them.
* token = 1*<any CHAR except CTLs or separators>
* separators = "(" | ")" | "<" | ">" | "@"
* | "," | ";" | ":" | "\" | <">
* | "/" | "[" | "]" | "?" | "="
* | "{" | "}" | SP | HT
*/
static const char tokens[256] = {
/* 0 nul 1 soh 2 stx 3 etx 4 eot 5 enq 6 ack 7 bel */
0, 0, 0, 0, 0, 0, 0, 0,
/* 8 bs 9 ht 10 nl 11 vt 12 np 13 cr 14 so 15 si */
0, 0, 0, 0, 0, 0, 0, 0,
/* 16 dle 17 dc1 18 dc2 19 dc3 20 dc4 21 nak 22 syn 23 etb */
0, 0, 0, 0, 0, 0, 0, 0,
/* 24 can 25 em 26 sub 27 esc 28 fs 29 gs 30 rs 31 us */
0, 0, 0, 0, 0, 0, 0, 0,
/* 32 sp 33 ! 34 " 35 # 36 $ 37 % 38 & 39 ' */
0, '!', 0, '#', '$', '%', '&', '\'',
/* 40 ( 41 ) 42 * 43 + 44 , 45 - 46 . 47 / */
0, 0, '*', '+', 0, '-', '.', 0,
/* 48 0 49 1 50 2 51 3 52 4 53 5 54 6 55 7 */
'0', '1', '2', '3', '4', '5', '6', '7',
/* 56 8 57 9 58 : 59 ; 60 < 61 = 62 > 63 ? */
'8', '9', 0, 0, 0, 0, 0, 0,
/* 64 @ 65 A 66 B 67 C 68 D 69 E 70 F 71 G */
0, 'a', 'b', 'c', 'd', 'e', 'f', 'g',
/* 72 H 73 I 74 J 75 K 76 L 77 M 78 N 79 O */
'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o',
/* 80 P 81 Q 82 R 83 S 84 T 85 U 86 V 87 W */
'p', 'q', 'r', 's', 't', 'u', 'v', 'w',
/* 88 X 89 Y 90 Z 91 [ 92 \ 93 ] 94 ^ 95 _ */
'x', 'y', 'z', 0, 0, 0, '^', '_',
/* 96 ` 97 a 98 b 99 c 100 d 101 e 102 f 103 g */
'`', 'a', 'b', 'c', 'd', 'e', 'f', 'g',
/* 104 h 105 i 106 j 107 k 108 l 109 m 110 n 111 o */
'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o',
/* 112 p 113 q 114 r 115 s 116 t 117 u 118 v 119 w */
'p', 'q', 'r', 's', 't', 'u', 'v', 'w',
/* 120 x 121 y 122 z 123 { 124 | 125 } 126 ~ 127 del */
'x', 'y', 'z', 0, '|', 0, '~', 0 };
static const int8_t unhex[256] =
{-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1
,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1
,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1
, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9,-1,-1,-1,-1,-1,-1
,-1,10,11,12,13,14,15,-1,-1,-1,-1,-1,-1,-1,-1,-1
,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1
,-1,10,11,12,13,14,15,-1,-1,-1,-1,-1,-1,-1,-1,-1
,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1
};
char c, ch;
int8_t unhex_val;
const char *p = data;
const char *header_field_mark = 0;
const char *header_value_mark = 0;
const char *url_mark = 0;
const char *url_start_mark = 0;
const char *body_mark = 0;
const unsigned int lenient = parser->lenient_http_headers;
const unsigned int allow_chunked_length = parser->allow_chunked_length;
uint32_t nread = parser->nread;
/* We're in an error state. Don't bother doing anything. */
if (CROW_HTTP_PARSER_ERRNO(parser) != CHPE_OK) {
return 0;
}
if (len == 0) {
switch (parser->state) {
case s_body_identity_eof:
/* Use of CROW_CALLBACK_NOTIFY() here would erroneously return 1 byte read if we got paused. */
CROW_CALLBACK_NOTIFY_NOADVANCE(message_complete);
return 0;
case s_dead:
case s_start_req:
return 0;
default:
CROW_SET_ERRNO(CHPE_INVALID_EOF_STATE);
return 1;
}
}
if (parser->state == s_header_field)
header_field_mark = data;
if (parser->state == s_header_value)
header_value_mark = data;
switch (parser->state) {
case s_req_path:
case s_req_schema:
case s_req_schema_slash:
case s_req_schema_slash_slash:
case s_req_server_start:
case s_req_server:
case s_req_server_with_at:
case s_req_query_string_start:
case s_req_query_string:
url_mark = data;
break;
default:
break;
}
for (p=data; p != data + len; p++) {
ch = *p;
if (CROW_PARSING_HEADER(parser->state))
CROW_COUNT_HEADER_SIZE(1);
reexecute:
switch (parser->state) {
case s_dead:
/* this state is used after a 'Connection: close' message
* the parser will error out if it reads another message
*/
if (CROW_LIKELY(ch == cr || ch == lf))
break;
CROW_SET_ERRNO(CHPE_CLOSED_CONNECTION);
goto error;
case s_start_req:
{
if (ch == cr || ch == lf)
break;
parser->flags = 0;
parser->uses_transfer_encoding = 0;
parser->content_length = CROW_ULLONG_MAX;
if (CROW_UNLIKELY(!CROW_IS_ALPHA(ch))) {
CROW_SET_ERRNO(CHPE_INVALID_METHOD);
goto error;
}
parser->method = 0;
parser->index = 1;
switch (ch) {
case 'A': parser->method = (unsigned)HTTPMethod::Acl; break;
case 'B': parser->method = (unsigned)HTTPMethod::Bind; break;
case 'C': parser->method = (unsigned)HTTPMethod::Connect; /* or COPY, CHECKOUT */ break;
case 'D': parser->method = (unsigned)HTTPMethod::Delete; break;
case 'G': parser->method = (unsigned)HTTPMethod::Get; break;
case 'H': parser->method = (unsigned)HTTPMethod::Head; break;
case 'L': parser->method = (unsigned)HTTPMethod::Lock; /* or LINK */ break;
case 'M': parser->method = (unsigned)HTTPMethod::MkCol; /* or MOVE, MKACTIVITY, MERGE, M-SEARCH, MKCALENDAR */ break;
case 'N': parser->method = (unsigned)HTTPMethod::Notify; break;
case 'O': parser->method = (unsigned)HTTPMethod::Options; break;
case 'P': parser->method = (unsigned)HTTPMethod::Post; /* or PROPFIND|PROPPATCH|PUT|PATCH|PURGE */ break;
case 'R': parser->method = (unsigned)HTTPMethod::Report; /* or REBIND */ break;
case 'S': parser->method = (unsigned)HTTPMethod::Subscribe; /* or SEARCH, SOURCE */ break;
case 'T': parser->method = (unsigned)HTTPMethod::Trace; break;
case 'U': parser->method = (unsigned)HTTPMethod::Unlock; /* or UNSUBSCRIBE, UNBIND, UNLINK */ break;
default:
CROW_SET_ERRNO(CHPE_INVALID_METHOD);
goto error;
}
parser->state = s_req_method;
CROW_CALLBACK_NOTIFY(message_begin);
break;
}
case s_req_method:
{
const char *matcher;
if (CROW_UNLIKELY(ch == '\0')) {
CROW_SET_ERRNO(CHPE_INVALID_METHOD);
goto error;
}
matcher = method_strings[parser->method];
if (ch == ' ' && matcher[parser->index] == '\0') {
parser->state = s_req_spaces_before_url;
} else if (ch == matcher[parser->index]) {
; /* nada */
} else if ((ch >= 'A' && ch <= 'Z') || ch == '-') {
switch (parser->method << 16 | parser->index << 8 | ch) {
#define CROW_XX(meth, pos, ch, new_meth) \
case ((unsigned)HTTPMethod::meth << 16 | pos << 8 | ch): \
parser->method = (unsigned)HTTPMethod::new_meth; break;
CROW_XX(Post, 1, 'U', Put)
CROW_XX(Post, 1, 'A', Patch)
CROW_XX(Post, 1, 'R', Propfind)
CROW_XX(Put, 2, 'R', Purge)
CROW_XX(Connect, 1, 'H', Checkout)
CROW_XX(Connect, 2, 'P', Copy)
CROW_XX(MkCol, 1, 'O', Move)
CROW_XX(MkCol, 1, 'E', Merge)
CROW_XX(MkCol, 1, '-', MSearch)
CROW_XX(MkCol, 2, 'A', MkActivity)
CROW_XX(MkCol, 3, 'A', MkCalendar)
CROW_XX(Subscribe, 1, 'E', Search)
CROW_XX(Subscribe, 1, 'O', Source)
CROW_XX(Report, 2, 'B', Rebind)
CROW_XX(Propfind, 4, 'P', Proppatch)
CROW_XX(Lock, 1, 'I', Link)
CROW_XX(Unlock, 2, 'S', Unsubscribe)
CROW_XX(Unlock, 2, 'B', Unbind)
CROW_XX(Unlock, 3, 'I', Unlink)
#undef CROW_XX
default:
CROW_SET_ERRNO(CHPE_INVALID_METHOD);
goto error;
}
} else {
CROW_SET_ERRNO(CHPE_INVALID_METHOD);
goto error;
}
++parser->index;
break;
}
case s_req_spaces_before_url:
{
if (ch == ' ') break;
CROW_MARK(url);
CROW_MARK(url_start);
if (parser->method == (unsigned)HTTPMethod::Connect) {
parser->state = s_req_server_start;
}
parser->state = parse_url_char(static_cast<state>(parser->state), ch, parser, url_start_mark, p);
if (CROW_UNLIKELY(parser->state == s_dead)) {
CROW_SET_ERRNO(CHPE_INVALID_URL);
goto error;
}
break;
}
case s_req_schema:
case s_req_schema_slash:
case s_req_schema_slash_slash:
case s_req_server_start:
{
switch (ch) {
/* No whitespace allowed here */
case ' ':
case cr:
case lf:
CROW_SET_ERRNO(CHPE_INVALID_URL);
goto error;
default:
parser->state = parse_url_char(static_cast<state>(parser->state), ch, parser, url_start_mark, p);
if (CROW_UNLIKELY(parser->state == s_dead)) {
CROW_SET_ERRNO(CHPE_INVALID_URL);
goto error;
}
}
break;
}
case s_req_server:
case s_req_server_with_at:
case s_req_path:
case s_req_query_string_start:
case s_req_query_string:
{
switch (ch) {
case ' ':
parser->state = s_req_http_start;
CROW_CALLBACK_DATA(url);
break;
case cr: // No space after URL means no HTTP version. Which means the request is using HTTP/0.9
case lf:
if (CROW_UNLIKELY(parser->method != (unsigned)HTTPMethod::Get)) // HTTP/0.9 doesn't define any method other than GET
{
parser->state = s_dead;
CROW_SET_ERRNO(CHPE_INVALID_VERSION);
goto error;
}
parser->http_major = 0;
parser->http_minor = 9;
parser->state = (ch == cr) ?
s_req_line_almost_done :
s_header_field_start;
CROW_CALLBACK_DATA(url);
break;
default:
parser->state = parse_url_char(static_cast<state>(parser->state), ch, parser, url_start_mark, p);
if (CROW_UNLIKELY(parser->state == s_dead)) {
CROW_SET_ERRNO(CHPE_INVALID_URL);
goto error;
}
}
break;
}
case s_req_http_start:
switch (ch) {
case ' ':
break;
case 'H':
parser->state = s_req_http_H;
break;
case 'I':
if (parser->method == (unsigned)HTTPMethod::Source) {
parser->state = s_req_http_I;
break;
}
/* fall through */
default:
CROW_SET_ERRNO(CHPE_INVALID_CONSTANT);
goto error;
}
break;
case s_req_http_H:
CROW_STRICT_CHECK(ch != 'T');
parser->state = s_req_http_HT;
break;
case s_req_http_HT:
CROW_STRICT_CHECK(ch != 'T');
parser->state = s_req_http_HTT;
break;
case s_req_http_HTT:
CROW_STRICT_CHECK(ch != 'P');
parser->state = s_req_http_HTTP;
break;
case s_req_http_I:
CROW_STRICT_CHECK(ch != 'C');
parser->state = s_req_http_IC;
break;
case s_req_http_IC:
CROW_STRICT_CHECK(ch != 'E');
parser->state = s_req_http_HTTP; /* Treat "ICE" as "HTTP". */
break;
case s_req_http_HTTP:
CROW_STRICT_CHECK(ch != '/');
parser->state = s_req_http_major;
break;
/* dot */
case s_req_http_major:
if (CROW_UNLIKELY(!CROW_IS_NUM(ch))) {
CROW_SET_ERRNO(CHPE_INVALID_VERSION);
goto error;
}
parser->http_major = ch - '0';
parser->state = s_req_http_dot;
break;
case s_req_http_dot:
{
if (CROW_UNLIKELY(ch != '.')) {
CROW_SET_ERRNO(CHPE_INVALID_VERSION);
goto error;
}
parser->state = s_req_http_minor;
break;
}
/* minor HTTP version */
case s_req_http_minor:
if (CROW_UNLIKELY(!CROW_IS_NUM(ch))) {
CROW_SET_ERRNO(CHPE_INVALID_VERSION);
goto error;
}
parser->http_minor = ch - '0';
parser->state = s_req_http_end;
break;
/* end of request line */
case s_req_http_end:
{
if (ch == cr) {
parser->state = s_req_line_almost_done;
break;
}
if (ch == lf) {
parser->state = s_header_field_start;
break;
}
CROW_SET_ERRNO(CHPE_INVALID_VERSION);
goto error;
break;
}
/* end of request line */
case s_req_line_almost_done:
{
if (CROW_UNLIKELY(ch != lf)) {
CROW_SET_ERRNO(CHPE_LF_EXPECTED);
goto error;
}
parser->state = s_header_field_start;
break;
}
case s_header_field_start:
{
if (ch == cr) {
parser->state = s_headers_almost_done;
break;
}
if (ch == lf) {
/* they might be just sending \n instead of \r\n so this would be
* the second \n to denote the end of headers*/
parser->state = s_headers_almost_done;
CROW_REEXECUTE();
}
c = CROW_TOKEN(ch);
if (CROW_UNLIKELY(!c)) {
CROW_SET_ERRNO(CHPE_INVALID_HEADER_TOKEN);
goto error;
}
CROW_MARK(header_field);
parser->index = 0;
parser->state = s_header_field;
switch (c) {
case 'c':
parser->header_state = h_C;
break;
case 'p':
parser->header_state = h_matching_proxy_connection;
break;
case 't':
parser->header_state = h_matching_transfer_encoding;
break;
case 'u':
parser->header_state = h_matching_upgrade;
break;
default:
parser->header_state = h_general;
break;
}
break;
}
case s_header_field:
{
const char* start = p;
for (; p != data + len; p++) {
ch = *p;
c = CROW_TOKEN(ch);
if (!c)
break;
switch (parser->header_state) {
case h_general: {
size_t left = data + len - p;
const char* pe = p + CROW_MIN(left, max_header_size);
while (p+1 < pe && CROW_TOKEN(p[1])) {
p++;
}
break;
}
case h_C:
parser->index++;
parser->header_state = (c == 'o' ? h_CO : h_general);
break;
case h_CO:
parser->index++;
parser->header_state = (c == 'n' ? h_CON : h_general);
break;
case h_CON:
parser->index++;
switch (c) {
case 'n':
parser->header_state = h_matching_connection;
break;
case 't':
parser->header_state = h_matching_content_length;
break;
default:
parser->header_state = h_general;
break;
}
break;
/* connection */
case h_matching_connection:
parser->index++;
if (parser->index > sizeof(CROW_CONNECTION)-1 || c != CROW_CONNECTION[parser->index]) {
parser->header_state = h_general;
} else if (parser->index == sizeof(CROW_CONNECTION)-2) {
parser->header_state = h_connection;
}
break;
/* proxy-connection */
case h_matching_proxy_connection:
parser->index++;
if (parser->index > sizeof(CROW_PROXY_CONNECTION)-1 || c != CROW_PROXY_CONNECTION[parser->index]) {
parser->header_state = h_general;
} else if (parser->index == sizeof(CROW_PROXY_CONNECTION)-2) {
parser->header_state = h_connection;
}
break;
/* content-length */
case h_matching_content_length:
parser->index++;
if (parser->index > sizeof(CROW_CONTENT_LENGTH)-1 || c != CROW_CONTENT_LENGTH[parser->index]) {
parser->header_state = h_general;
} else if (parser->index == sizeof(CROW_CONTENT_LENGTH)-2) {
parser->header_state = h_content_length;
}
break;
/* transfer-encoding */
case h_matching_transfer_encoding:
parser->index++;
if (parser->index > sizeof(CROW_TRANSFER_ENCODING)-1 || c != CROW_TRANSFER_ENCODING[parser->index]) {
parser->header_state = h_general;
} else if (parser->index == sizeof(CROW_TRANSFER_ENCODING)-2) {
parser->header_state = h_transfer_encoding;
parser->uses_transfer_encoding = 1;
}
break;
/* upgrade */
case h_matching_upgrade:
parser->index++;
if (parser->index > sizeof(CROW_UPGRADE)-1 || c != CROW_UPGRADE[parser->index]) {
parser->header_state = h_general;
} else if (parser->index == sizeof(CROW_UPGRADE)-2) {
parser->header_state = h_upgrade;
}
break;
case h_connection:
case h_content_length:
case h_transfer_encoding:
case h_upgrade:
if (ch != ' ') parser->header_state = h_general;
break;
default:
assert(0 && "Unknown header_state");
break;
}
}
if (p == data + len) {
--p;
CROW_COUNT_HEADER_SIZE(p - start);
break;
}
CROW_COUNT_HEADER_SIZE(p - start);
if (ch == ':') {
parser->state = s_header_value_discard_ws;
CROW_CALLBACK_DATA(header_field);
break;
}
/* RFC-7230 Sec 3.2.4 expressly forbids line-folding in header field-names.
if (ch == cr) {
parser->state = s_header_almost_done;
CROW_CALLBACK_DATA(header_field);
break;
}
if (ch == lf) {
parser->state = s_header_field_start;
CROW_CALLBACK_DATA(header_field);
break;
}
*/
CROW_SET_ERRNO(CHPE_INVALID_HEADER_TOKEN);
goto error;
}
case s_header_value_discard_ws:
if (ch == ' ' || ch == '\t') break;
if (ch == cr) {
parser->state = s_header_value_discard_ws_almost_done;
break;
}
if (ch == lf) {
parser->state = s_header_value_discard_lws;
break;
}
/* fall through */
case s_header_value_start:
{
CROW_MARK(header_value);
parser->state = s_header_value;
parser->index = 0;
c = CROW_LOWER(ch);
switch (parser->header_state) {
case h_upgrade:
parser->flags |= F_UPGRADE;
parser->header_state = h_general;
break;
case h_transfer_encoding:
/* looking for 'Transfer-Encoding: chunked' */
if ('c' == c) {
parser->header_state = h_matching_transfer_encoding_chunked;
} else {
parser->header_state = h_matching_transfer_encoding_token;
}
break;
/* Multi-value `Transfer-Encoding` header */
case h_matching_transfer_encoding_token_start:
break;
case h_content_length:
if (CROW_UNLIKELY(!CROW_IS_NUM(ch))) {
CROW_SET_ERRNO(CHPE_INVALID_CONTENT_LENGTH);
goto error;
}
if (parser->flags & F_CONTENTLENGTH) {
CROW_SET_ERRNO(CHPE_UNEXPECTED_CONTENT_LENGTH);
goto error;
}
parser->flags |= F_CONTENTLENGTH;
parser->content_length = ch - '0';
parser->header_state = h_content_length_num;
break;
/* when obsolete line folding is encountered for content length
* continue to the s_header_value state */
case h_content_length_ws:
break;
case h_connection:
/* looking for 'Connection: keep-alive' */
if (c == 'k') {
parser->header_state = h_matching_connection_keep_alive;
/* looking for 'Connection: close' */
} else if (c == 'c') {
parser->header_state = h_matching_connection_close;
} else if (c == ' ' || c == '\t') {
/* Skip lws */
} else {
parser->header_state = h_general;
}
break;
default:
parser->header_state = h_general;
break;
}
break;
}
case s_header_value:
{
const char* start = p;
enum header_states h_state = static_cast<header_states>(parser->header_state);
for (; p != data + len; p++) {
ch = *p;
if (ch == cr) {
parser->state = s_header_almost_done;
parser->header_state = h_state;
CROW_CALLBACK_DATA(header_value);
break;
}
if (ch == lf) {
parser->state = s_header_almost_done;
CROW_COUNT_HEADER_SIZE(p - start);
parser->header_state = h_state;
CROW_CALLBACK_DATA_NOADVANCE(header_value);
CROW_REEXECUTE();
}
if (!lenient && !CROW_IS_HEADER_CHAR(ch)) {
CROW_SET_ERRNO(CHPE_INVALID_HEADER_TOKEN);
goto error;
}
c = CROW_LOWER(ch);
switch (h_state) {
case h_general:
{
size_t left = data + len - p;
const char* pe = p + CROW_MIN(left, max_header_size);
for (; p != pe; p++) {
ch = *p;
if (ch == cr || ch == lf) {
--p;
break;
}
if (!lenient && !CROW_IS_HEADER_CHAR(ch)) {
CROW_SET_ERRNO(CHPE_INVALID_HEADER_TOKEN);
goto error;
}
}
if (p == data + len)
--p;
break;
}
case h_connection:
case h_transfer_encoding:
assert(0 && "Shouldn't get here.");
break;
case h_content_length:
if (ch == ' ') break;
h_state = h_content_length_num;
/* fall through */
case h_content_length_num:
{
uint64_t t;
if (ch == ' ') {
h_state = h_content_length_ws;
break;
}
if (CROW_UNLIKELY(!CROW_IS_NUM(ch))) {
CROW_SET_ERRNO(CHPE_INVALID_CONTENT_LENGTH);
parser->header_state = h_state;
goto error;
}
t = parser->content_length;
t *= 10;
t += ch - '0';
/* Overflow? Test against a conservative limit for simplicity. */
if (CROW_UNLIKELY((CROW_ULLONG_MAX - 10) / 10 < parser->content_length)) {
CROW_SET_ERRNO(CHPE_INVALID_CONTENT_LENGTH);
parser->header_state = h_state;
goto error;
}
parser->content_length = t;
break;
}
case h_content_length_ws:
if (ch == ' ') break;
CROW_SET_ERRNO(CHPE_INVALID_CONTENT_LENGTH);
parser->header_state = h_state;
goto error;
/* Transfer-Encoding: chunked */
case h_matching_transfer_encoding_token_start:
/* looking for 'Transfer-Encoding: chunked' */
if ('c' == c) {
h_state = h_matching_transfer_encoding_chunked;
} else if (CROW_TOKEN(c)) {
/* TODO(indutny): similar code below does this, but why?
* At the very least it seems to be inconsistent given that
* h_matching_transfer_encoding_token does not check for
* `STRICT_TOKEN`
*/
h_state = h_matching_transfer_encoding_token;
} else if (c == ' ' || c == '\t') {
/* Skip lws */
} else {
h_state = h_general;
}
break;
case h_matching_transfer_encoding_chunked:
parser->index++;
if (parser->index > sizeof(CROW_CHUNKED)-1 || c != CROW_CHUNKED[parser->index]) {
h_state = h_matching_transfer_encoding_token;
} else if (parser->index == sizeof(CROW_CHUNKED)-2) {
h_state = h_transfer_encoding_chunked;
}
break;
case h_matching_transfer_encoding_token:
if (ch == ',') {
h_state = h_matching_transfer_encoding_token_start;
parser->index = 0;
}
break;
/* looking for 'Connection: keep-alive' */
case h_matching_connection_keep_alive:
parser->index++;
if (parser->index > sizeof(CROW_KEEP_ALIVE)-1 || c != CROW_KEEP_ALIVE[parser->index]) {
h_state = h_general;
} else if (parser->index == sizeof(CROW_KEEP_ALIVE)-2) {
h_state = h_connection_keep_alive;
}
break;
/* looking for 'Connection: close' */
case h_matching_connection_close:
parser->index++;
if (parser->index > sizeof(CROW_CLOSE)-1 || c != CROW_CLOSE[parser->index]) {
h_state = h_general;
} else if (parser->index == sizeof(CROW_CLOSE)-2) {
h_state = h_connection_close;
}
break;
// Edited from original (because of commits that werent included)
case h_transfer_encoding_chunked:
if (ch != ' ') h_state = h_matching_transfer_encoding_token;
break;
case h_connection_keep_alive:
case h_connection_close:
if (ch != ' ') h_state = h_general;
break;
default:
parser->state = s_header_value;
h_state = h_general;
break;
}
}
parser->header_state = h_state;
if (p == data + len)
--p;
CROW_COUNT_HEADER_SIZE(p - start);
break;
}
case s_header_almost_done:
{
if (CROW_UNLIKELY(ch != lf)) {
CROW_SET_ERRNO(CHPE_LF_EXPECTED);
goto error;
}
parser->state = s_header_value_lws;
break;
}
case s_header_value_lws:
{
if (ch == ' ' || ch == '\t') {
if (parser->header_state == h_content_length_num) {
/* treat obsolete line folding as space */
parser->header_state = h_content_length_ws;
}
parser->state = s_header_value_start;
CROW_REEXECUTE();
}
/* finished the header */
switch (parser->header_state) {
case h_connection_keep_alive:
parser->flags |= F_CONNECTION_KEEP_ALIVE;
break;
case h_connection_close:
parser->flags |= F_CONNECTION_CLOSE;
break;
case h_transfer_encoding_chunked:
parser->flags |= F_CHUNKED;
break;
default:
break;
}
parser->state = s_header_field_start;
CROW_REEXECUTE();
}
case s_header_value_discard_ws_almost_done:
{
CROW_STRICT_CHECK(ch != lf);
parser->state = s_header_value_discard_lws;
break;
}
case s_header_value_discard_lws:
{
if (ch == ' ' || ch == '\t') {
parser->state = s_header_value_discard_ws;
break;
} else {
/* header value was empty */
CROW_MARK(header_value);
parser->state = s_header_field_start;
CROW_CALLBACK_DATA_NOADVANCE(header_value);
CROW_REEXECUTE();
}
}
case s_headers_almost_done:
{
CROW_STRICT_CHECK(ch != lf);
if (parser->flags & F_TRAILING) {
/* End of a chunked request */
CROW_CALLBACK_NOTIFY(message_complete);
break;
}
/* Cannot use transfer-encoding and a content-length header together
per the HTTP specification. (RFC 7230 Section 3.3.3) */
if ((parser->uses_transfer_encoding == 1) &&
(parser->flags & F_CONTENTLENGTH)) {
/* Allow it for lenient parsing as long as `Transfer-Encoding` is
* not `chunked` or allow_length_with_encoding is set
*/
if (parser->flags & F_CHUNKED) {
if (!allow_chunked_length) {
CROW_SET_ERRNO(CHPE_UNEXPECTED_CONTENT_LENGTH);
goto error;
}
} else if (!lenient) {
CROW_SET_ERRNO(CHPE_UNEXPECTED_CONTENT_LENGTH);
goto error;
}
}
parser->state = s_headers_done;
/* Set this here so that on_headers_complete() callbacks can see it */
parser->upgrade =
(parser->flags & F_UPGRADE || parser->method == (unsigned)HTTPMethod::Connect);
/* Here we call the headers_complete callback. This is somewhat
* different than other callbacks because if the user returns 1, we
* will interpret that as saying that this message has no body. This
* is needed for the annoying case of recieving a response to a HEAD
* request.
*
* We'd like to use CROW_CALLBACK_NOTIFY_NOADVANCE() here but we cannot, so
* we have to simulate it by handling a change in errno below.
*/
if (settings->on_headers_complete) {
switch (settings->on_headers_complete(parser)) {
case 0:
break;
case 2:
parser->upgrade = 1;
//break;
/* fall through */
case 1:
parser->flags |= F_SKIPBODY;
break;
default:
CROW_SET_ERRNO(CHPE_CB_headers_complete);
parser->nread = nread;
return p - data; /* Error */
}
}
if (CROW_HTTP_PARSER_ERRNO(parser) != CHPE_OK) {
parser->nread = nread;
return p - data;
}
CROW_REEXECUTE();
}
case s_headers_done:
{
CROW_STRICT_CHECK(ch != lf);
parser->nread = 0;
nread = 0;
/* Exit, the rest of the connect is in a different protocol. */
if (parser->upgrade) {
CROW_CALLBACK_NOTIFY(message_complete);
parser->nread = nread;
return (p - data) + 1;
}
if (parser->flags & F_SKIPBODY) {
CROW_CALLBACK_NOTIFY(message_complete);
} else if (parser->flags & F_CHUNKED) {
/* chunked encoding - ignore Content-Length header,
* prepare for a chunk */
parser->state = s_chunk_size_start;
}
else if (parser->uses_transfer_encoding == 1)
{
if (!lenient)
{
/* RFC 7230 3.3.3 */
/* If a Transfer-Encoding header field
* is present in a request and the chunked transfer coding is not
* the final encoding, the message body length cannot be determined
* reliably; the server MUST respond with the 400 (Bad Request)
* status code and then close the connection.
*/
CROW_SET_ERRNO(CHPE_INVALID_TRANSFER_ENCODING);
parser->nread = nread;
return (p - data); /* Error */
}
else
{
/* RFC 7230 3.3.3 */
/* If a Transfer-Encoding header field is present in a response and
* the chunked transfer coding is not the final encoding, the
* message body length is determined by reading the connection until
* it is closed by the server.
*/
parser->state = s_body_identity_eof;
}
}
else
{
if (parser->content_length == 0)
{
/* Content-Length header given but zero: Content-Length: 0\r\n */
CROW_CALLBACK_NOTIFY(message_complete);
}
else if (parser->content_length != CROW_ULLONG_MAX)
{
/* Content-Length header given and non-zero */
parser->state = s_body_identity;
}
else
{
/* Assume content-length 0 - read the next */
CROW_CALLBACK_NOTIFY(message_complete);
}
}
break;
}
case s_body_identity:
{
uint64_t to_read = CROW_MIN(parser->content_length,
(uint64_t) ((data + len) - p));
assert(parser->content_length != 0
&& parser->content_length != CROW_ULLONG_MAX);
/* The difference between advancing content_length and p is because
* the latter will automaticaly advance on the next loop iteration.
* Further, if content_length ends up at 0, we want to see the last
* byte again for our message complete callback.
*/
CROW_MARK(body);
parser->content_length -= to_read;
p += to_read - 1;
if (parser->content_length == 0) {
parser->state = s_message_done;
/* Mimic CROW_CALLBACK_DATA_NOADVANCE() but with one extra byte.
*
* The alternative to doing this is to wait for the next byte to
* trigger the data callback, just as in every other case. The
* problem with this is that this makes it difficult for the test
* harness to distinguish between complete-on-EOF and
* complete-on-length. It's not clear that this distinction is
* important for applications, but let's keep it for now.
*/
CROW_CALLBACK_DATA_(body, p - body_mark + 1, p - data);
CROW_REEXECUTE();
}
break;
}
/* read until EOF */
case s_body_identity_eof:
CROW_MARK(body);
p = data + len - 1;
break;
case s_message_done:
CROW_CALLBACK_NOTIFY(message_complete);
break;
case s_chunk_size_start:
{
assert(nread == 1);
assert(parser->flags & F_CHUNKED);
unhex_val = unhex[static_cast<unsigned char>(ch)];
if (CROW_UNLIKELY(unhex_val == -1)) {
CROW_SET_ERRNO(CHPE_INVALID_CHUNK_SIZE);
goto error;
}
parser->content_length = unhex_val;
parser->state = s_chunk_size;
break;
}
case s_chunk_size:
{
uint64_t t;
assert(parser->flags & F_CHUNKED);
if (ch == cr) {
parser->state = s_chunk_size_almost_done;
break;
}
unhex_val = unhex[static_cast<unsigned char>(ch)];
if (unhex_val == -1) {
if (ch == ';' || ch == ' ') {
parser->state = s_chunk_parameters;
break;
}
CROW_SET_ERRNO(CHPE_INVALID_CHUNK_SIZE);
goto error;
}
t = parser->content_length;
t *= 16;
t += unhex_val;
/* Overflow? Test against a conservative limit for simplicity. */
if (CROW_UNLIKELY((CROW_ULLONG_MAX - 16) / 16 < parser->content_length)) {
CROW_SET_ERRNO(CHPE_INVALID_CONTENT_LENGTH);
goto error;
}
parser->content_length = t;
break;
}
case s_chunk_parameters:
{
assert(parser->flags & F_CHUNKED);
/* just ignore this shit. TODO check for overflow */
if (ch == cr) {
parser->state = s_chunk_size_almost_done;
break;
}
break;
}
case s_chunk_size_almost_done:
{
assert(parser->flags & F_CHUNKED);
CROW_STRICT_CHECK(ch != lf);
parser->nread = 0;
nread = 0;
if (parser->content_length == 0) {
parser->flags |= F_TRAILING;
parser->state = s_header_field_start;
} else {
parser->state = s_chunk_data;
}
break;
}
case s_chunk_data:
{
uint64_t to_read = CROW_MIN(parser->content_length,
(uint64_t) ((data + len) - p));
assert(parser->flags & F_CHUNKED);
assert(parser->content_length != 0
&& parser->content_length != CROW_ULLONG_MAX);
/* See the explanation in s_body_identity for why the content
* length and data pointers are managed this way.
*/
CROW_MARK(body);
parser->content_length -= to_read;
p += to_read - 1;
if (parser->content_length == 0) {
parser->state = s_chunk_data_almost_done;
}
break;
}
case s_chunk_data_almost_done:
assert(parser->flags & F_CHUNKED);
assert(parser->content_length == 0);
CROW_STRICT_CHECK(ch != cr);
parser->state = s_chunk_data_done;
CROW_CALLBACK_DATA(body);
break;
case s_chunk_data_done:
assert(parser->flags & F_CHUNKED);
CROW_STRICT_CHECK(ch != lf);
parser->nread = 0;
nread = 0;
parser->state = s_chunk_size_start;
break;
default:
assert(0 && "unhandled state");
CROW_SET_ERRNO(CHPE_INVALID_INTERNAL_STATE);
goto error;
}
}
/* Run callbacks for any marks that we have leftover after we ran out of
* bytes. There should be at most one of these set, so it's OK to invoke
* them in series (unset marks will not result in callbacks).
*
* We use the NOADVANCE() variety of callbacks here because 'p' has already
* overflowed 'data' and this allows us to correct for the off-by-one that
* we'd otherwise have (since CROW_CALLBACK_DATA() is meant to be run with a 'p'
* value that's in-bounds).
*/
assert(((header_field_mark ? 1 : 0) +
(header_value_mark ? 1 : 0) +
(url_mark ? 1 : 0) +
(body_mark ? 1 : 0)) <= 1);
CROW_CALLBACK_DATA_NOADVANCE(header_field);
CROW_CALLBACK_DATA_NOADVANCE(header_value);
CROW_CALLBACK_DATA_NOADVANCE(url);
CROW_CALLBACK_DATA_NOADVANCE(body);
parser->nread = nread;
return len;
error:
if (CROW_HTTP_PARSER_ERRNO(parser) == CHPE_OK) {
CROW_SET_ERRNO(CHPE_UNKNOWN);
}
parser->nread = nread;
return (p - data);
}
inline void
http_parser_init(http_parser* parser)
{
void *data = parser->data; /* preserve application data */
memset(parser, 0, sizeof(*parser));
parser->data = data;
parser->state = s_start_req;
parser->http_errno = CHPE_OK;
}
/* Return a string name of the given error */
inline const char *
http_errno_name(enum http_errno err) {
/* Map errno values to strings for human-readable output */
#define CROW_HTTP_STRERROR_GEN(n, s) { "CHPE_" #n, s },
static struct {
const char *name;
const char *description;
} http_strerror_tab[] = {
CROW_HTTP_ERRNO_MAP(CROW_HTTP_STRERROR_GEN)
};
#undef CROW_HTTP_STRERROR_GEN
assert(((size_t) err) < CROW_ARRAY_SIZE(http_strerror_tab));
return http_strerror_tab[err].name;
}
/* Return a string description of the given error */
inline const char *
http_errno_description(enum http_errno err) {
/* Map errno values to strings for human-readable output */
#define CROW_HTTP_STRERROR_GEN(n, s) { "CHPE_" #n, s },
static struct {
const char *name;
const char *description;
} http_strerror_tab[] = {
CROW_HTTP_ERRNO_MAP(CROW_HTTP_STRERROR_GEN)
};
#undef CROW_HTTP_STRERROR_GEN
assert(((size_t) err) < CROW_ARRAY_SIZE(http_strerror_tab));
return http_strerror_tab[err].description;
}
/* Checks if this is the final chunk of the body. */
inline int
http_body_is_final(const struct http_parser *parser) {
return parser->state == s_message_done;
}
/* Change the maximum header size provided at compile time. */
inline void
http_parser_set_max_header_size(uint32_t size) {
max_header_size = size;
}
#undef CROW_HTTP_ERRNO_MAP
#undef CROW_SET_ERRNO
#undef CROW_CALLBACK_NOTIFY_
#undef CROW_CALLBACK_NOTIFY
#undef CROW_CALLBACK_NOTIFY_NOADVANCE
#undef CROW_CALLBACK_DATA_
#undef CROW_CALLBACK_DATA
#undef CROW_CALLBACK_DATA_NOADVANCE
#undef CROW_MARK
#undef CROW_PROXY_CONNECTION
#undef CROW_CONNECTION
#undef CROW_CONTENT_LENGTH
#undef CROW_TRANSFER_ENCODING
#undef CROW_UPGRADE
#undef CROW_CHUNKED
#undef CROW_KEEP_ALIVE
#undef CROW_CLOSE
#undef CROW_PARSING_HEADER
#undef CROW_LOWER
#undef CROW_IS_ALPHA
#undef CROW_IS_NUM
#undef CROW_IS_ALPHANUM
//#undef CROW_IS_HEX
#undef CROW_IS_MARK
#undef CROW_IS_USERINFO_CHAR
#undef CROW_TOKEN
#undef CROW_IS_URL_CHAR
//#undef CROW_IS_HOST_CHAR
#undef CROW_STRICT_CHECK
}
}
// clang-format on
#pragma once
#include <string>
#include <unordered_map>
#include <boost/algorithm/string.hpp>
#include <algorithm>
namespace crow
{
/// A wrapper for `nodejs/http-parser`.
///
/// Used to generate a \ref crow.request from the TCP socket buffer.
template<typename Handler>
struct HTTPParser : public http_parser
{
static int on_message_begin(http_parser*)
{
return 0;
}
static int on_url(http_parser* self_, const char* at, size_t length)
{
HTTPParser* self = static_cast<HTTPParser*>(self_);
self->raw_url.insert(self->raw_url.end(), at, at + length);
return 0;
}
static int on_header_field(http_parser* self_, const char* at, size_t length)
{
HTTPParser* self = static_cast<HTTPParser*>(self_);
switch (self->header_building_state)
{
case 0:
if (!self->header_value.empty())
{
self->headers.emplace(std::move(self->header_field), std::move(self->header_value));
}
self->header_field.assign(at, at + length);
self->header_building_state = 1;
break;
case 1:
self->header_field.insert(self->header_field.end(), at, at + length);
break;
}
return 0;
}
static int on_header_value(http_parser* self_, const char* at, size_t length)
{
HTTPParser* self = static_cast<HTTPParser*>(self_);
switch (self->header_building_state)
{
case 0:
self->header_value.insert(self->header_value.end(), at, at + length);
break;
case 1:
self->header_building_state = 0;
self->header_value.assign(at, at + length);
break;
}
return 0;
}
static int on_headers_complete(http_parser* self_)
{
HTTPParser* self = static_cast<HTTPParser*>(self_);
if (!self->header_field.empty())
{
self->headers.emplace(std::move(self->header_field), std::move(self->header_value));
}
self->set_connection_parameters();
self->process_header();
return 0;
}
static int on_body(http_parser* self_, const char* at, size_t length)
{
HTTPParser* self = static_cast<HTTPParser*>(self_);
self->body.insert(self->body.end(), at, at + length);
return 0;
}
static int on_message_complete(http_parser* self_)
{
HTTPParser* self = static_cast<HTTPParser*>(self_);
self->message_complete = true;
// url params
self->url = self->raw_url.substr(0, self->qs_point != 0 ? self->qs_point : std::string::npos);
self->url_params = query_string(self->raw_url);
self->process_message();
return 0;
}
HTTPParser(Handler* handler):
handler_(handler)
{
http_parser_init(this);
}
// return false on error
/// Parse a buffer into the different sections of an HTTP request.
bool feed(const char* buffer, int length)
{
if (message_complete)
return true;
const static http_parser_settings settings_{
on_message_begin,
on_url,
on_header_field,
on_header_value,
on_headers_complete,
on_body,
on_message_complete,
};
int nparsed = http_parser_execute(this, &settings_, buffer, length);
if (http_errno != CHPE_OK)
{
return false;
}
return nparsed == length;
}
bool done()
{
return feed(nullptr, 0);
}
void clear()
{
url.clear();
raw_url.clear();
header_field.clear();
header_value.clear();
headers.clear();
url_params.clear();
body.clear();
header_building_state = 0;
qs_point = 0;
http_major = 0;
http_minor = 0;
message_complete = false;
state = CROW_NEW_MESSAGE();
keep_alive = false;
close_connection = false;
}
inline void process_header()
{
handler_->handle_header();
}
inline void process_message()
{
handler_->handle();
}
inline void set_connection_parameters()
{
//NOTE(EDev): it seems that the problem is with crow's policy on closing the connection for HTTP_VERSION < 1.0, the behaviour for that in crow is "don't close the connection, but don't send a keep-alive either"
// HTTP1.1 = always send keep_alive, HTTP1.0 = only send if header exists, HTTP?.? = never send
keep_alive = (http_major == 1 && http_minor == 0) ?
((flags & F_CONNECTION_KEEP_ALIVE) ? true : false) :
((http_major == 1 && http_minor == 1) ? true : false);
// HTTP1.1 = only close if close header exists, HTTP1.0 = always close unless keep_alive header exists, HTTP?.?= never close
close_connection = (http_major == 1 && http_minor == 0) ?
((flags & F_CONNECTION_KEEP_ALIVE) ? false : true) :
((http_major == 1 && http_minor == 1) ? ((flags & F_CONNECTION_CLOSE) ? true : false) : false);
}
/// Take the parsed HTTP request data and convert it to a \ref crow.request
request to_request() const
{
return request{static_cast<HTTPMethod>(method), std::move(raw_url), std::move(url), std::move(url_params), std::move(headers), std::move(body), http_major, http_minor, keep_alive, close_connection, static_cast<bool>(upgrade)};
}
std::string raw_url;
std::string url;
int header_building_state = 0;
bool message_complete = false;
std::string header_field;
std::string header_value;
ci_map headers;
query_string url_params; ///< What comes after the `?` in the URL.
std::string body;
bool keep_alive; ///< Whether or not the server should send a `connection: Keep-Alive` header to the client.
bool close_connection; ///< Whether or not the server should shut down the TCP connection once a response is sent.
Handler* handler_; ///< This is currently an HTTP connection object (\ref crow.Connection).
};
} // namespace crow
#undef CROW_NEW_MESSAGE
#undef CROW_start_state
#pragma once
namespace crow
{
namespace detail
{
template<typename... Middlewares>
struct partial_context : public black_magic::pop_back<Middlewares...>::template rebind<partial_context>, public black_magic::last_element_type<Middlewares...>::type::context
{
using parent_context = typename black_magic::pop_back<Middlewares...>::template rebind<::crow::detail::partial_context>;
template<int N>
using partial = typename std::conditional<N == sizeof...(Middlewares) - 1, partial_context, typename parent_context::template partial<N>>::type;
template<typename T>
typename T::context& get()
{
return static_cast<typename T::context&>(*this);
}
};
template<>
struct partial_context<>
{
template<int>
using partial = partial_context;
};
template<typename... Middlewares>
struct context : private partial_context<Middlewares...>
//struct context : private Middlewares::context... // simple but less type-safe
{
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
friend typename std::enable_if<(N == 0)>::type after_handlers_call_helper(Container& middlewares, Context& ctx, request& req, response& res);
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
friend typename std::enable_if<(N > 0)>::type after_handlers_call_helper(Container& middlewares, Context& ctx, request& req, response& res);
template<template<typename QueryMW> class CallCriteria, int N, typename Context, typename Container>
friend typename std::enable_if<(N < std::tuple_size<typename std::remove_reference<Container>::type>::value), bool>::type
middleware_call_helper(Container& middlewares, request& req, response& res, Context& ctx);
template<typename T>
typename T::context& get()
{
return static_cast<typename T::context&>(*this);
}
template<int N>
using partial = typename partial_context<Middlewares...>::template partial<N>;
};
} // namespace detail
} // namespace crow
#pragma once
//#define CROW_JSON_NO_ERROR_CHECK
//#define CROW_JSON_USE_MAP
#include <string>
#ifdef CROW_JSON_USE_MAP
#include <map>
#else
#include <unordered_map>
#endif
#include <iostream>
#include <algorithm>
#include <memory>
#include <boost/lexical_cast.hpp>
#include <boost/algorithm/string/predicate.hpp>
#include <boost/operators.hpp>
#include <vector>
#include <cmath>
using std::isinf;
using std::isnan;
namespace crow
{
namespace mustache
{
class template_t;
}
namespace json
{
inline void escape(const std::string& str, std::string& ret)
{
ret.reserve(ret.size() + str.size() + str.size() / 4);
for (auto c : str)
{
switch (c)
{
case '"': ret += "\\\""; break;
case '\\': ret += "\\\\"; break;
case '\n': ret += "\\n"; break;
case '\b': ret += "\\b"; break;
case '\f': ret += "\\f"; break;
case '\r': ret += "\\r"; break;
case '\t': ret += "\\t"; break;
default:
if (c >= 0 && c < 0x20)
{
ret += "\\u00";
auto to_hex = [](char c) {
c = c & 0xf;
if (c < 10)
return '0' + c;
return 'a' + c - 10;
};
ret += to_hex(c / 16);
ret += to_hex(c % 16);
}
else
ret += c;
break;
}
}
}
inline std::string escape(const std::string& str)
{
std::string ret;
escape(str, ret);
return ret;
}
enum class type : char
{
Null,
False,
True,
Number,
String,
List,
Object,
Function
};
inline const char* get_type_str(type t)
{
switch (t)
{
case type::Number: return "Number";
case type::False: return "False";
case type::True: return "True";
case type::List: return "List";
case type::String: return "String";
case type::Object: return "Object";
case type::Function: return "Function";
default: return "Unknown";
}
}
enum class num_type : char
{
Signed_integer,
Unsigned_integer,
Floating_point,
Null
};
class rvalue;
rvalue load(const char* data, size_t size);
namespace detail
{
/// A read string implementation with comparison functionality.
struct r_string : boost::less_than_comparable<r_string>, boost::less_than_comparable<r_string, std::string>, boost::equality_comparable<r_string>, boost::equality_comparable<r_string, std::string>
{
r_string(){};
r_string(char* s, char* e):
s_(s), e_(e){};
~r_string()
{
if (owned_)
delete[] s_;
}
r_string(const r_string& r)
{
*this = r;
}
r_string(r_string&& r)
{
*this = r;
}
r_string& operator=(r_string&& r)
{
s_ = r.s_;
e_ = r.e_;
owned_ = r.owned_;
if (r.owned_)
r.owned_ = 0;
return *this;
}
r_string& operator=(const r_string& r)
{
s_ = r.s_;
e_ = r.e_;
owned_ = 0;
return *this;
}
operator std::string() const
{
return std::string(s_, e_);
}
const char* begin() const { return s_; }
const char* end() const { return e_; }
size_t size() const { return end() - begin(); }
using iterator = const char*;
using const_iterator = const char*;
char* s_; ///< Start.
mutable char* e_; ///< End.
uint8_t owned_{0};
friend std::ostream& operator<<(std::ostream& os, const r_string& s)
{
os << static_cast<std::string>(s);
return os;
}
private:
void force(char* s, uint32_t length)
{
s_ = s;
e_ = s_ + length;
owned_ = 1;
}
friend rvalue crow::json::load(const char* data, size_t size);
};
inline bool operator<(const r_string& l, const r_string& r)
{
return boost::lexicographical_compare(l, r);
}
inline bool operator<(const r_string& l, const std::string& r)
{
return boost::lexicographical_compare(l, r);
}
inline bool operator>(const r_string& l, const std::string& r)
{
return boost::lexicographical_compare(r, l);
}
inline bool operator==(const r_string& l, const r_string& r)
{
return boost::equals(l, r);
}
inline bool operator==(const r_string& l, const std::string& r)
{
return boost::equals(l, r);
}
} // namespace detail
/// JSON read value.
///
/// Value can mean any json value, including a JSON object.
/// Read means this class is used to primarily read strings into a JSON value.
class rvalue
{
static const int cached_bit = 2;
static const int error_bit = 4;
public:
rvalue() noexcept:
option_{error_bit}
{
}
rvalue(type t) noexcept:
lsize_{}, lremain_{}, t_{t}
{
}
rvalue(type t, char* s, char* e) noexcept:
start_{s}, end_{e}, t_{t}
{
determine_num_type();
}
rvalue(const rvalue& r):
start_(r.start_), end_(r.end_), key_(r.key_), t_(r.t_), nt_(r.nt_), option_(r.option_)
{
copy_l(r);
}
rvalue(rvalue&& r) noexcept
{
*this = std::move(r);
}
rvalue& operator=(const rvalue& r)
{
start_ = r.start_;
end_ = r.end_;
key_ = r.key_;
t_ = r.t_;
nt_ = r.nt_;
option_ = r.option_;
copy_l(r);
return *this;
}
rvalue& operator=(rvalue&& r) noexcept
{
start_ = r.start_;
end_ = r.end_;
key_ = std::move(r.key_);
l_ = std::move(r.l_);
lsize_ = r.lsize_;
lremain_ = r.lremain_;
t_ = r.t_;
nt_ = r.nt_;
option_ = r.option_;
return *this;
}
explicit operator bool() const noexcept
{
return (option_ & error_bit) == 0;
}
explicit operator int64_t() const
{
return i();
}
explicit operator uint64_t() const
{
return u();
}
explicit operator int() const
{
return static_cast<int>(i());
}
/// Return any json value (not object or list) as a string.
explicit operator std::string() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() == type::Object || t() == type::List)
throw std::runtime_error("json type container");
#endif
switch (t())
{
case type::String:
return std::string(s());
case type::Null:
return std::string("null");
case type::True:
return std::string("true");
case type::False:
return std::string("false");
default:
return std::string(start_, end_ - start_);
}
}
/// The type of the JSON value.
type t() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (option_ & error_bit)
{
throw std::runtime_error("invalid json object");
}
#endif
return t_;
}
/// The number type of the JSON value.
num_type nt() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (option_ & error_bit)
{
throw std::runtime_error("invalid json object");
}
#endif
return nt_;
}
/// The integer value.
int64_t i() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
switch (t())
{
case type::Number:
case type::String:
return boost::lexical_cast<int64_t>(start_, end_ - start_);
default:
const std::string msg = "expected number, got: " + std::string(get_type_str(t()));
throw std::runtime_error(msg);
}
#endif
return boost::lexical_cast<int64_t>(start_, end_ - start_);
}
/// The unsigned integer value.
uint64_t u() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
switch (t())
{
case type::Number:
case type::String:
return boost::lexical_cast<uint64_t>(start_, end_ - start_);
default:
throw std::runtime_error(std::string("expected number, got: ") + get_type_str(t()));
}
#endif
return boost::lexical_cast<uint64_t>(start_, end_ - start_);
}
/// The double precision floating-point number value.
double d() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Number)
throw std::runtime_error("value is not number");
#endif
return boost::lexical_cast<double>(start_, end_ - start_);
}
/// The boolean value.
bool b() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::True && t() != type::False)
throw std::runtime_error("value is not boolean");
#endif
return t() == type::True;
}
/// The string value.
detail::r_string s() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::String)
throw std::runtime_error("value is not string");
#endif
unescape();
return detail::r_string{start_, end_};
}
/// The list or object value
std::vector<rvalue> lo()
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Object && t() != type::List)
throw std::runtime_error("value is not a container");
#endif
std::vector<rvalue> ret;
ret.reserve(lsize_);
for (uint32_t i = 0; i < lsize_; i++)
{
ret.emplace_back(l_[i]);
}
return ret;
}
/// Convert escaped string character to their original form ("\\n" -> '\n').
void unescape() const
{
if (*(start_ - 1))
{
char* head = start_;
char* tail = start_;
while (head != end_)
{
if (*head == '\\')
{
switch (*++head)
{
case '"': *tail++ = '"'; break;
case '\\': *tail++ = '\\'; break;
case '/': *tail++ = '/'; break;
case 'b': *tail++ = '\b'; break;
case 'f': *tail++ = '\f'; break;
case 'n': *tail++ = '\n'; break;
case 'r': *tail++ = '\r'; break;
case 't': *tail++ = '\t'; break;
case 'u':
{
auto from_hex = [](char c) {
if (c >= 'a')
return c - 'a' + 10;
if (c >= 'A')
return c - 'A' + 10;
return c - '0';
};
unsigned int code =
(from_hex(head[1]) << 12) +
(from_hex(head[2]) << 8) +
(from_hex(head[3]) << 4) +
from_hex(head[4]);
if (code >= 0x800)
{
*tail++ = 0xE0 | (code >> 12);
*tail++ = 0x80 | ((code >> 6) & 0x3F);
*tail++ = 0x80 | (code & 0x3F);
}
else if (code >= 0x80)
{
*tail++ = 0xC0 | (code >> 6);
*tail++ = 0x80 | (code & 0x3F);
}
else
{
*tail++ = code;
}
head += 4;
}
break;
}
}
else
*tail++ = *head;
head++;
}
end_ = tail;
*end_ = 0;
*(start_ - 1) = 0;
}
}
/// Check if the json object has the passed string as a key.
bool has(const char* str) const
{
return has(std::string(str));
}
bool has(const std::string& str) const
{
struct Pred
{
bool operator()(const rvalue& l, const rvalue& r) const
{
return l.key_ < r.key_;
};
bool operator()(const rvalue& l, const std::string& r) const
{
return l.key_ < r;
};
bool operator()(const std::string& l, const rvalue& r) const
{
return l < r.key_;
};
};
if (!is_cached())
{
std::sort(begin(), end(), Pred());
set_cached();
}
auto it = lower_bound(begin(), end(), str, Pred());
return it != end() && it->key_ == str;
}
int count(const std::string& str)
{
return has(str) ? 1 : 0;
}
rvalue* begin() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Object && t() != type::List)
throw std::runtime_error("value is not a container");
#endif
return l_.get();
}
rvalue* end() const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Object && t() != type::List)
throw std::runtime_error("value is not a container");
#endif
return l_.get() + lsize_;
}
const detail::r_string& key() const
{
return key_;
}
size_t size() const
{
if (t() == type::String)
return s().size();
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Object && t() != type::List)
throw std::runtime_error("value is not a container");
#endif
return lsize_;
}
const rvalue& operator[](int index) const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::List)
throw std::runtime_error("value is not a list");
if (index >= static_cast<int>(lsize_) || index < 0)
throw std::runtime_error("list out of bound");
#endif
return l_[index];
}
const rvalue& operator[](size_t index) const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::List)
throw std::runtime_error("value is not a list");
if (index >= lsize_)
throw std::runtime_error("list out of bound");
#endif
return l_[index];
}
const rvalue& operator[](const char* str) const
{
return this->operator[](std::string(str));
}
const rvalue& operator[](const std::string& str) const
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Object)
throw std::runtime_error("value is not an object");
#endif
struct Pred
{
bool operator()(const rvalue& l, const rvalue& r) const
{
return l.key_ < r.key_;
};
bool operator()(const rvalue& l, const std::string& r) const
{
return l.key_ < r;
};
bool operator()(const std::string& l, const rvalue& r) const
{
return l < r.key_;
};
};
if (!is_cached())
{
std::sort(begin(), end(), Pred());
set_cached();
}
auto it = lower_bound(begin(), end(), str, Pred());
if (it != end() && it->key_ == str)
return *it;
#ifndef CROW_JSON_NO_ERROR_CHECK
throw std::runtime_error("cannot find key");
#else
static rvalue nullValue;
return nullValue;
#endif
}
void set_error()
{
option_ |= error_bit;
}
bool error() const
{
return (option_ & error_bit) != 0;
}
std::vector<std::string> keys()
{
#ifndef CROW_JSON_NO_ERROR_CHECK
if (t() != type::Object)
throw std::runtime_error("value is not an object");
#endif
std::vector<std::string> ret;
ret.reserve(lsize_);
for (uint32_t i = 0; i < lsize_; i++)
{
ret.emplace_back(std::string(l_[i].key()));
}
return ret;
}
private:
bool is_cached() const
{
return (option_ & cached_bit) != 0;
}
void set_cached() const
{
option_ |= cached_bit;
}
void copy_l(const rvalue& r)
{
if (r.t() != type::Object && r.t() != type::List)
return;
lsize_ = r.lsize_;
lremain_ = 0;
l_.reset(new rvalue[lsize_]);
std::copy(r.begin(), r.end(), begin());
}
void emplace_back(rvalue&& v)
{
if (!lremain_)
{
int new_size = lsize_ + lsize_;
if (new_size - lsize_ > 60000)
new_size = lsize_ + 60000;
if (new_size < 4)
new_size = 4;
rvalue* p = new rvalue[new_size];
rvalue* p2 = p;
for (auto& x : *this)
*p2++ = std::move(x);
l_.reset(p);
lremain_ = new_size - lsize_;
}
l_[lsize_++] = std::move(v);
lremain_--;
}
/// Determines num_type from the string.
void determine_num_type()
{
if (t_ != type::Number)
{
nt_ = num_type::Null;
return;
}
const std::size_t len = end_ - start_;
const bool has_minus = std::memchr(start_, '-', len) != nullptr;
const bool has_e = std::memchr(start_, 'e', len) != nullptr || std::memchr(start_, 'E', len) != nullptr;
const bool has_dec_sep = std::memchr(start_, '.', len) != nullptr;
if (has_dec_sep || has_e)
nt_ = num_type::Floating_point;
else if (has_minus)
nt_ = num_type::Signed_integer;
else
nt_ = num_type::Unsigned_integer;
}
mutable char* start_;
mutable char* end_;
detail::r_string key_;
std::unique_ptr<rvalue[]> l_;
uint32_t lsize_;
uint16_t lremain_;
type t_;
num_type nt_{num_type::Null};
mutable uint8_t option_{0};
friend rvalue load_nocopy_internal(char* data, size_t size);
friend rvalue load(const char* data, size_t size);
friend std::ostream& operator<<(std::ostream& os, const rvalue& r)
{
switch (r.t_)
{
case type::Null: os << "null"; break;
case type::False: os << "false"; break;
case type::True: os << "true"; break;
case type::Number:
{
switch (r.nt())
{
case num_type::Floating_point: os << r.d(); break;
case num_type::Signed_integer: os << r.i(); break;
case num_type::Unsigned_integer: os << r.u(); break;
case num_type::Null: throw std::runtime_error("Number with num_type Null");
}
}
break;
case type::String: os << '"' << r.s() << '"'; break;
case type::List:
{
os << '[';
bool first = true;
for (auto& x : r)
{
if (!first)
os << ',';
first = false;
os << x;
}
os << ']';
}
break;
case type::Object:
{
os << '{';
bool first = true;
for (auto& x : r)
{
if (!first)
os << ',';
os << '"' << escape(x.key_) << "\":";
first = false;
os << x;
}
os << '}';
}
break;
case type::Function: os << "custom function"; break;
}
return os;
}
};
namespace detail
{
}
inline bool operator==(const rvalue& l, const std::string& r)
{
return l.s() == r;
}
inline bool operator==(const std::string& l, const rvalue& r)
{
return l == r.s();
}
inline bool operator!=(const rvalue& l, const std::string& r)
{
return l.s() != r;
}
inline bool operator!=(const std::string& l, const rvalue& r)
{
return l != r.s();
}
inline bool operator==(const rvalue& l, double r)
{
return l.d() == r;
}
inline bool operator==(double l, const rvalue& r)
{
return l == r.d();
}
inline bool operator!=(const rvalue& l, double r)
{
return l.d() != r;
}
inline bool operator!=(double l, const rvalue& r)
{
return l != r.d();
}
inline rvalue load_nocopy_internal(char* data, size_t size)
{
// Defend against excessive recursion
static constexpr unsigned max_depth = 10000;
//static const char* escaped = "\"\\/\b\f\n\r\t";
struct Parser
{
Parser(char* data, size_t /*size*/):
data(data)
{
}
bool consume(char c)
{
if (CROW_UNLIKELY(*data != c))
return false;
data++;
return true;
}
void ws_skip()
{
while (*data == ' ' || *data == '\t' || *data == '\r' || *data == '\n')
++data;
};
rvalue decode_string()
{
if (CROW_UNLIKELY(!consume('"')))
return {};
char* start = data;
uint8_t has_escaping = 0;
while (1)
{
if (CROW_LIKELY(*data != '"' && *data != '\\' && *data != '\0'))
{
data++;
}
else if (*data == '"')
{
*data = 0;
*(start - 1) = has_escaping;
data++;
return {type::String, start, data - 1};
}
else if (*data == '\\')
{
has_escaping = 1;
data++;
switch (*data)
{
case 'u':
{
auto check = [](char c) {
return ('0' <= c && c <= '9') ||
('a' <= c && c <= 'f') ||
('A' <= c && c <= 'F');
};
if (!(check(*(data + 1)) &&
check(*(data + 2)) &&
check(*(data + 3)) &&
check(*(data + 4))))
return {};
}
data += 5;
break;
case '"':
case '\\':
case '/':
case 'b':
case 'f':
case 'n':
case 'r':
case 't':
data++;
break;
default:
return {};
}
}
else
return {};
}
return {};
}
rvalue decode_list(unsigned depth)
{
rvalue ret(type::List);
if (CROW_UNLIKELY(!consume('[')) || CROW_UNLIKELY(depth > max_depth))
{
ret.set_error();
return ret;
}
ws_skip();
if (CROW_UNLIKELY(*data == ']'))
{
data++;
return ret;
}
while (1)
{
auto v = decode_value(depth + 1);
if (CROW_UNLIKELY(!v))
{
ret.set_error();
break;
}
ws_skip();
ret.emplace_back(std::move(v));
if (*data == ']')
{
data++;
break;
}
if (CROW_UNLIKELY(!consume(',')))
{
ret.set_error();
break;
}
ws_skip();
}
return ret;
}
rvalue decode_number()
{
char* start = data;
enum NumberParsingState
{
Minus,
AfterMinus,
ZeroFirst,
Digits,
DigitsAfterPoints,
E,
DigitsAfterE,
Invalid,
} state{Minus};
while (CROW_LIKELY(state != Invalid))
{
switch (*data)
{
case '0':
state = static_cast<NumberParsingState>("\2\2\7\3\4\6\6"[state]);
/*if (state == NumberParsingState::Minus || state == NumberParsingState::AfterMinus)
{
state = NumberParsingState::ZeroFirst;
}
else if (state == NumberParsingState::Digits ||
state == NumberParsingState::DigitsAfterE ||
state == NumberParsingState::DigitsAfterPoints)
{
// ok; pass
}
else if (state == NumberParsingState::E)
{
state = NumberParsingState::DigitsAfterE;
}
else
return {};*/
break;
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
state = static_cast<NumberParsingState>("\3\3\7\3\4\6\6"[state]);
while (*(data + 1) >= '0' && *(data + 1) <= '9')
data++;
/*if (state == NumberParsingState::Minus || state == NumberParsingState::AfterMinus)
{
state = NumberParsingState::Digits;
}
else if (state == NumberParsingState::Digits ||
state == NumberParsingState::DigitsAfterE ||
state == NumberParsingState::DigitsAfterPoints)
{
// ok; pass
}
else if (state == NumberParsingState::E)
{
state = NumberParsingState::DigitsAfterE;
}
else
return {};*/
break;
case '.':
state = static_cast<NumberParsingState>("\7\7\4\4\7\7\7"[state]);
/*
if (state == NumberParsingState::Digits || state == NumberParsingState::ZeroFirst)
{
state = NumberParsingState::DigitsAfterPoints;
}
else
return {};
*/
break;
case '-':
state = static_cast<NumberParsingState>("\1\7\7\7\7\6\7"[state]);
/*if (state == NumberParsingState::Minus)
{
state = NumberParsingState::AfterMinus;
}
else if (state == NumberParsingState::E)
{
state = NumberParsingState::DigitsAfterE;
}
else
return {};*/
break;
case '+':
state = static_cast<NumberParsingState>("\7\7\7\7\7\6\7"[state]);
/*if (state == NumberParsingState::E)
{
state = NumberParsingState::DigitsAfterE;
}
else
return {};*/
break;
case 'e':
case 'E':
state = static_cast<NumberParsingState>("\7\7\7\5\5\7\7"[state]);
/*if (state == NumberParsingState::Digits ||
state == NumberParsingState::DigitsAfterPoints)
{
state = NumberParsingState::E;
}
else
return {};*/
break;
default:
if (CROW_LIKELY(state == NumberParsingState::ZeroFirst ||
state == NumberParsingState::Digits ||
state == NumberParsingState::DigitsAfterPoints ||
state == NumberParsingState::DigitsAfterE))
return {type::Number, start, data};
else
return {};
}
data++;
}
return {};
}
rvalue decode_value(unsigned depth)
{
switch (*data)
{
case '[':
return decode_list(depth + 1);
case '{':
return decode_object(depth + 1);
case '"':
return decode_string();
case 't':
if ( //e-data >= 4 &&
data[1] == 'r' &&
data[2] == 'u' &&
data[3] == 'e')
{
data += 4;
return {type::True};
}
else
return {};
case 'f':
if ( //e-data >= 5 &&
data[1] == 'a' &&
data[2] == 'l' &&
data[3] == 's' &&
data[4] == 'e')
{
data += 5;
return {type::False};
}
else
return {};
case 'n':
if ( //e-data >= 4 &&
data[1] == 'u' &&
data[2] == 'l' &&
data[3] == 'l')
{
data += 4;
return {type::Null};
}
else
return {};
//case '1': case '2': case '3':
//case '4': case '5': case '6':
//case '7': case '8': case '9':
//case '0': case '-':
default:
return decode_number();
}
return {};
}
rvalue decode_object(unsigned depth)
{
rvalue ret(type::Object);
if (CROW_UNLIKELY(!consume('{')) || CROW_UNLIKELY(depth > max_depth))
{
ret.set_error();
return ret;
}
ws_skip();
if (CROW_UNLIKELY(*data == '}'))
{
data++;
return ret;
}
while (1)
{
auto t = decode_string();
if (CROW_UNLIKELY(!t))
{
ret.set_error();
break;
}
ws_skip();
if (CROW_UNLIKELY(!consume(':')))
{
ret.set_error();
break;
}
// TODO(ipkn) caching key to speed up (flyweight?)
// I have no idea how flyweight could apply here, but maybe some speedup can happen if we stopped checking type since decode_string returns a string anyway
auto key = t.s();
ws_skip();
auto v = decode_value(depth + 1);
if (CROW_UNLIKELY(!v))
{
ret.set_error();
break;
}
ws_skip();
v.key_ = std::move(key);
ret.emplace_back(std::move(v));
if (CROW_UNLIKELY(*data == '}'))
{
data++;
break;
}
if (CROW_UNLIKELY(!consume(',')))
{
ret.set_error();
break;
}
ws_skip();
}
return ret;
}
rvalue parse()
{
ws_skip();
auto ret = decode_value(0); // or decode object?
ws_skip();
if (ret && *data != '\0')
ret.set_error();
return ret;
}
char* data;
};
return Parser(data, size).parse();
}
inline rvalue load(const char* data, size_t size)
{
char* s = new char[size + 1];
memcpy(s, data, size);
s[size] = 0;
auto ret = load_nocopy_internal(s, size);
if (ret)
ret.key_.force(s, size);
else
delete[] s;
return ret;
}
inline rvalue load(const char* data)
{
return load(data, strlen(data));
}
inline rvalue load(const std::string& str)
{
return load(str.data(), str.size());
}
/// JSON write value.
///
/// Value can mean any json value, including a JSON object.<br>
/// Write means this class is used to primarily assemble JSON objects using keys and values and export those into a string.
class wvalue : public returnable
{
friend class crow::mustache::template_t;
public:
using object =
#ifdef CROW_JSON_USE_MAP
std::map<std::string, wvalue>;
#else
std::unordered_map<std::string, wvalue>;
#endif
using list = std::vector<wvalue>;
type t() const { return t_; }
private:
type t_{type::Null}; ///< The type of the value.
num_type nt{num_type::Null}; ///< The specific type of the number if \ref t_ is a number.
union number
{
double d;
int64_t si;
uint64_t ui;
public:
constexpr number() noexcept:
ui() {} /* default constructor initializes unsigned integer. */
constexpr number(std::uint64_t value) noexcept:
ui(value) {}
constexpr number(std::int64_t value) noexcept:
si(value) {}
constexpr number(double value) noexcept:
d(value) {}
} num; ///< Value if type is a number.
std::string s; ///< Value if type is a string.
std::unique_ptr<list> l; ///< Value if type is a list.
std::unique_ptr<object> o; ///< Value if type is a JSON object.
std::function<std::string(std::string&)> f; ///< Value if type is a function (C++ lambda)
public:
wvalue():
returnable("application/json") {}
wvalue(std::nullptr_t):
returnable("application/json"), t_(type::Null) {}
wvalue(bool value):
returnable("application/json"), t_(value ? type::True : type::False) {}
wvalue(std::uint8_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Unsigned_integer), num(static_cast<std::uint64_t>(value)) {}
wvalue(std::uint16_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Unsigned_integer), num(static_cast<std::uint64_t>(value)) {}
wvalue(std::uint32_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Unsigned_integer), num(static_cast<std::uint64_t>(value)) {}
wvalue(std::uint64_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Unsigned_integer), num(static_cast<std::uint64_t>(value)) {}
wvalue(std::int8_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Signed_integer), num(static_cast<std::int64_t>(value)) {}
wvalue(std::int16_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Signed_integer), num(static_cast<std::int64_t>(value)) {}
wvalue(std::int32_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Signed_integer), num(static_cast<std::int64_t>(value)) {}
wvalue(std::int64_t value):
returnable("application/json"), t_(type::Number), nt(num_type::Signed_integer), num(static_cast<std::int64_t>(value)) {}
wvalue(float value):
returnable("application/json"), t_(type::Number), nt(num_type::Floating_point), num(static_cast<double>(value)) {}
wvalue(double value):
returnable("application/json"), t_(type::Number), nt(num_type::Floating_point), num(static_cast<double>(value)) {}
wvalue(char const* value):
returnable("application/json"), t_(type::String), s(value) {}
wvalue(std::string const& value):
returnable("application/json"), t_(type::String), s(value) {}
wvalue(std::string&& value):
returnable("application/json"), t_(type::String), s(std::move(value)) {}
wvalue(std::initializer_list<std::pair<std::string const, wvalue>> initializer_list):
returnable("application/json"), t_(type::Object), o(new object(initializer_list)) {}
wvalue(object const& value):
returnable("application/json"), t_(type::Object), o(new object(value)) {}
wvalue(object&& value):
returnable("application/json"), t_(type::Object), o(new object(std::move(value))) {}
wvalue(const list& r):
returnable("application/json")
{
t_ = type::List;
l = std::unique_ptr<list>(new list{});
l->reserve(r.size());
for (auto it = r.begin(); it != r.end(); ++it)
l->emplace_back(*it);
}
wvalue(list& r):
returnable("application/json")
{
t_ = type::List;
l = std::unique_ptr<list>(new list{});
l->reserve(r.size());
for (auto it = r.begin(); it != r.end(); ++it)
l->emplace_back(*it);
}
/// Create a write value from a read value (useful for editing JSON strings).
wvalue(const rvalue& r):
returnable("application/json")
{
t_ = r.t();
switch (r.t())
{
case type::Null:
case type::False:
case type::True:
case type::Function:
return;
case type::Number:
nt = r.nt();
if (nt == num_type::Floating_point)
num.d = r.d();
else if (nt == num_type::Signed_integer)
num.si = r.i();
else
num.ui = r.u();
return;
case type::String:
s = r.s();
return;
case type::List:
l = std::unique_ptr<list>(new list{});
l->reserve(r.size());
for (auto it = r.begin(); it != r.end(); ++it)
l->emplace_back(*it);
return;
case type::Object:
o = std::unique_ptr<object>(new object{});
for (auto it = r.begin(); it != r.end(); ++it)
o->emplace(it->key(), *it);
return;
}
}
wvalue(const wvalue& r):
returnable("application/json")
{
t_ = r.t();
switch (r.t())
{
case type::Null:
case type::False:
case type::True:
return;
case type::Number:
nt = r.nt;
if (nt == num_type::Floating_point)
num.d = r.num.d;
else if (nt == num_type::Signed_integer)
num.si = r.num.si;
else
num.ui = r.num.ui;
return;
case type::String:
s = r.s;
return;
case type::List:
l = std::unique_ptr<list>(new list{});
l->reserve(r.size());
for (auto it = r.l->begin(); it != r.l->end(); ++it)
l->emplace_back(*it);
return;
case type::Object:
o = std::unique_ptr<object>(new object{});
o->insert(r.o->begin(), r.o->end());
return;
case type::Function:
f = r.f;
}
}
wvalue(wvalue&& r):
returnable("application/json")
{
*this = std::move(r);
}
wvalue& operator=(wvalue&& r)
{
t_ = r.t_;
num = r.num;
s = std::move(r.s);
l = std::move(r.l);
o = std::move(r.o);
return *this;
}
/// Used for compatibility, same as \ref reset()
void clear()
{
reset();
}
void reset()
{
t_ = type::Null;
l.reset();
o.reset();
}
wvalue& operator=(std::nullptr_t)
{
reset();
return *this;
}
wvalue& operator=(bool value)
{
reset();
if (value)
t_ = type::True;
else
t_ = type::False;
return *this;
}
wvalue& operator=(double value)
{
reset();
t_ = type::Number;
num.d = value;
nt = num_type::Floating_point;
return *this;
}
wvalue& operator=(unsigned short value)
{
reset();
t_ = type::Number;
num.ui = value;
nt = num_type::Unsigned_integer;
return *this;
}
wvalue& operator=(short value)
{
reset();
t_ = type::Number;
num.si = value;
nt = num_type::Signed_integer;
return *this;
}
wvalue& operator=(long long value)
{
reset();
t_ = type::Number;
num.si = value;
nt = num_type::Signed_integer;
return *this;
}
wvalue& operator=(long value)
{
reset();
t_ = type::Number;
num.si = value;
nt = num_type::Signed_integer;
return *this;
}
wvalue& operator=(int value)
{
reset();
t_ = type::Number;
num.si = value;
nt = num_type::Signed_integer;
return *this;
}
wvalue& operator=(unsigned long long value)
{
reset();
t_ = type::Number;
num.ui = value;
nt = num_type::Unsigned_integer;
return *this;
}
wvalue& operator=(unsigned long value)
{
reset();
t_ = type::Number;
num.ui = value;
nt = num_type::Unsigned_integer;
return *this;
}
wvalue& operator=(unsigned int value)
{
reset();
t_ = type::Number;
num.ui = value;
nt = num_type::Unsigned_integer;
return *this;
}
wvalue& operator=(const char* str)
{
reset();
t_ = type::String;
s = str;
return *this;
}
wvalue& operator=(const std::string& str)
{
reset();
t_ = type::String;
s = str;
return *this;
}
wvalue& operator=(list&& v)
{
if (t_ != type::List)
reset();
t_ = type::List;
if (!l)
l = std::unique_ptr<list>(new list{});
l->clear();
l->resize(v.size());
size_t idx = 0;
for (auto& x : v)
{
(*l)[idx++] = std::move(x);
}
return *this;
}
template<typename T>
wvalue& operator=(const std::vector<T>& v)
{
if (t_ != type::List)
reset();
t_ = type::List;
if (!l)
l = std::unique_ptr<list>(new list{});
l->clear();
l->resize(v.size());
size_t idx = 0;
for (auto& x : v)
{
(*l)[idx++] = x;
}
return *this;
}
wvalue& operator=(std::initializer_list<std::pair<std::string const, wvalue>> initializer_list)
{
if (t_ != type::Object)
{
reset();
t_ = type::Object;
o = std::unique_ptr<object>(new object(initializer_list));
}
else
{
#if defined(__APPLE__) || defined(__MACH__)
o = std::unique_ptr<object>(new object(initializer_list));
#else
(*o) = initializer_list;
#endif
}
return *this;
}
wvalue& operator=(object const& value)
{
if (t_ != type::Object)
{
reset();
t_ = type::Object;
o = std::unique_ptr<object>(new object(value));
}
else
{
#if defined(__APPLE__) || defined(__MACH__)
o = std::unique_ptr<object>(new object(value));
#else
(*o) = value;
#endif
}
return *this;
}
wvalue& operator=(object&& value)
{
if (t_ != type::Object)
{
reset();
t_ = type::Object;
o = std::unique_ptr<object>(new object(std::move(value)));
}
else
{
(*o) = std::move(value);
}
return *this;
}
wvalue& operator=(std::function<std::string(std::string&)>&& func)
{
reset();
t_ = type::Function;
f = std::move(func);
return *this;
}
wvalue& operator[](unsigned index)
{
if (t_ != type::List)
reset();
t_ = type::List;
if (!l)
l = std::unique_ptr<list>(new list{});
if (l->size() < index + 1)
l->resize(index + 1);
return (*l)[index];
}
int count(const std::string& str)
{
if (t_ != type::Object)
return 0;
if (!o)
return 0;
return o->count(str);
}
wvalue& operator[](const std::string& str)
{
if (t_ != type::Object)
reset();
t_ = type::Object;
if (!o)
o = std::unique_ptr<object>(new object{});
return (*o)[str];
}
std::vector<std::string> keys() const
{
if (t_ != type::Object)
return {};
std::vector<std::string> result;
for (auto& kv : *o)
{
result.push_back(kv.first);
}
return result;
}
std::string execute(std::string txt = "") const //Not using reference because it cannot be used with a default rvalue
{
if (t_ != type::Function)
return "";
return f(txt);
}
/// If the wvalue is a list, it returns the length of the list, otherwise it returns 1.
std::size_t size() const
{
if (t_ != type::List)
return 1;
return l->size();
}
/// Returns an estimated size of the value in bytes.
size_t estimate_length() const
{
switch (t_)
{
case type::Null: return 4;
case type::False: return 5;
case type::True: return 4;
case type::Number: return 30;
case type::String: return 2 + s.size() + s.size() / 2;
case type::List:
{
size_t sum{};
if (l)
{
for (auto& x : *l)
{
sum += 1;
sum += x.estimate_length();
}
}
return sum + 2;
}
case type::Object:
{
size_t sum{};
if (o)
{
for (auto& kv : *o)
{
sum += 2;
sum += 2 + kv.first.size() + kv.first.size() / 2;
sum += kv.second.estimate_length();
}
}
return sum + 2;
}
case type::Function:
return 0;
}
return 1;
}
private:
inline void dump_string(const std::string& str, std::string& out) const
{
out.push_back('"');
escape(str, out);
out.push_back('"');
}
inline void dump_internal(const wvalue& v, std::string& out) const
{
switch (v.t_)
{
case type::Null: out += "null"; break;
case type::False: out += "false"; break;
case type::True: out += "true"; break;
case type::Number:
{
if (v.nt == num_type::Floating_point)
{
if (isnan(v.num.d) || isinf(v.num.d))
{
out += "null";
CROW_LOG_WARNING << "Invalid JSON value detected (" << v.num.d << "), value set to null";
break;
}
#ifdef _MSC_VER
#define MSC_COMPATIBLE_SPRINTF(BUFFER_PTR, FORMAT_PTR, VALUE) sprintf_s((BUFFER_PTR), 128, (FORMAT_PTR), (VALUE))
#else
#define MSC_COMPATIBLE_SPRINTF(BUFFER_PTR, FORMAT_PTR, VALUE) sprintf((BUFFER_PTR), (FORMAT_PTR), (VALUE))
#endif
enum
{
start,
decp,
zero
} f_state;
char outbuf[128];
MSC_COMPATIBLE_SPRINTF(outbuf, "%f", v.num.d);
char *p = &outbuf[0], *o = nullptr;
f_state = start;
while (*p != '\0')
{
//std::cout << *p << std::endl;
char ch = *p;
switch (f_state)
{
case start:
if (ch == '.')
{
if (p + 1 && *(p + 1) == '0') p++;
f_state = decp;
}
p++;
break;
case decp:
if (ch == '0')
{
f_state = zero;
o = p;
}
p++;
break;
case zero:
if (ch != '0')
{
o = nullptr;
f_state = decp;
}
p++;
break;
}
}
if (o != nullptr)
*o = '\0';
out += outbuf;
#undef MSC_COMPATIBLE_SPRINTF
}
else if (v.nt == num_type::Signed_integer)
{
out += std::to_string(v.num.si);
}
else
{
out += std::to_string(v.num.ui);
}
}
break;
case type::String: dump_string(v.s, out); break;
case type::List:
{
out.push_back('[');
if (v.l)
{
bool first = true;
for (auto& x : *v.l)
{
if (!first)
{
out.push_back(',');
}
first = false;
dump_internal(x, out);
}
}
out.push_back(']');
}
break;
case type::Object:
{
out.push_back('{');
if (v.o)
{
bool first = true;
for (auto& kv : *v.o)
{
if (!first)
{
out.push_back(',');
}
first = false;
dump_string(kv.first, out);
out.push_back(':');
dump_internal(kv.second, out);
}
}
out.push_back('}');
}
break;
case type::Function:
out += "custom function";
break;
}
}
public:
std::string dump() const
{
std::string ret;
ret.reserve(estimate_length());
dump_internal(*this, ret);
return ret;
}
};
//std::vector<boost::asio::const_buffer> dump_ref(wvalue& v)
//{
//}
} // namespace json
} // namespace crow
#pragma once
#include <string>
#include <vector>
#include <fstream>
#include <iterator>
#include <functional>
namespace crow
{
namespace mustache
{
using context = json::wvalue;
template_t load(const std::string& filename);
class invalid_template_exception : public std::exception
{
public:
invalid_template_exception(const std::string& msg):
msg("crow::mustache error: " + msg)
{}
virtual const char* what() const throw()
{
return msg.c_str();
}
std::string msg;
};
struct rendered_template : returnable
{
rendered_template():
returnable("text/html") {}
rendered_template(std::string& body):
returnable("text/html"), body_(std::move(body)) {}
std::string body_;
std::string dump() const override
{
return body_;
}
};
enum class ActionType
{
Ignore,
Tag,
UnescapeTag,
OpenBlock,
CloseBlock,
ElseBlock,
Partial,
};
struct Action
{
int start;
int end;
int pos;
ActionType t;
Action(ActionType t, size_t start, size_t end, size_t pos = 0):
start(static_cast<int>(start)), end(static_cast<int>(end)), pos(static_cast<int>(pos)), t(t)
{
}
};
/// A mustache template object.
class template_t
{
public:
template_t(std::string body):
body_(std::move(body))
{
// {{ {{# {{/ {{^ {{! {{> {{=
parse();
}
private:
std::string tag_name(const Action& action) const
{
return body_.substr(action.start, action.end - action.start);
}
auto find_context(const std::string& name, const std::vector<context*>& stack, bool shouldUseOnlyFirstStackValue = false) const -> std::pair<bool, context&>
{
if (name == ".")
{
return {true, *stack.back()};
}
static json::wvalue empty_str;
empty_str = "";
int dotPosition = name.find(".");
if (dotPosition == static_cast<int>(name.npos))
{
for (auto it = stack.rbegin(); it != stack.rend(); ++it)
{
if ((*it)->t() == json::type::Object)
{
if ((*it)->count(name))
return {true, (**it)[name]};
}
}
}
else
{
std::vector<int> dotPositions;
dotPositions.push_back(-1);
while (dotPosition != static_cast<int>(name.npos))
{
dotPositions.push_back(dotPosition);
dotPosition = name.find(".", dotPosition + 1);
}
dotPositions.push_back(name.size());
std::vector<std::string> names;
names.reserve(dotPositions.size() - 1);
for (int i = 1; i < static_cast<int>(dotPositions.size()); i++)
names.emplace_back(name.substr(dotPositions[i - 1] + 1, dotPositions[i] - dotPositions[i - 1] - 1));
for (auto it = stack.rbegin(); it != stack.rend(); ++it)
{
context* view = *it;
bool found = true;
for (auto jt = names.begin(); jt != names.end(); ++jt)
{
if (view->t() == json::type::Object &&
view->count(*jt))
{
view = &(*view)[*jt];
}
else
{
if (shouldUseOnlyFirstStackValue)
{
return {false, empty_str};
}
found = false;
break;
}
}
if (found)
return {true, *view};
}
}
return {false, empty_str};
}
void escape(const std::string& in, std::string& out) const
{
out.reserve(out.size() + in.size());
for (auto it = in.begin(); it != in.end(); ++it)
{
switch (*it)
{
case '&': out += "&amp;"; break;
case '<': out += "&lt;"; break;
case '>': out += "&gt;"; break;
case '"': out += "&quot;"; break;
case '\'': out += "&#39;"; break;
case '/': out += "&#x2F;"; break;
case '`': out += "&#x60;"; break;
case '=': out += "&#x3D;"; break;
default: out += *it; break;
}
}
}
bool isTagInsideObjectBlock(const int& current, const std::vector<context*>& stack) const
{
int openedBlock = 0;
int totalBlocksBefore = 0;
for (int i = current; i > 0; --i)
{
++totalBlocksBefore;
auto& action = actions_[i - 1];
if (action.t == ActionType::OpenBlock)
{
if (openedBlock == 0 && (*stack.rbegin())->t() == json::type::Object)
{
return true;
}
--openedBlock;
}
else if (action.t == ActionType::CloseBlock)
{
++openedBlock;
}
}
return false;
}
void render_internal(int actionBegin, int actionEnd, std::vector<context*>& stack, std::string& out, int indent) const
{
int current = actionBegin;
if (indent)
out.insert(out.size(), indent, ' ');
while (current < actionEnd)
{
auto& fragment = fragments_[current];
auto& action = actions_[current];
render_fragment(fragment, indent, out);
switch (action.t)
{
case ActionType::Ignore:
// do nothing
break;
case ActionType::Partial:
{
std::string partial_name = tag_name(action);
auto partial_templ = load(partial_name);
int partial_indent = action.pos;
partial_templ.render_internal(0, partial_templ.fragments_.size() - 1, stack, out, partial_indent ? indent + partial_indent : 0);
}
break;
case ActionType::UnescapeTag:
case ActionType::Tag:
{
bool shouldUseOnlyFirstStackValue = false;
if (isTagInsideObjectBlock(current, stack))
{
shouldUseOnlyFirstStackValue = true;
}
auto optional_ctx = find_context(tag_name(action), stack, shouldUseOnlyFirstStackValue);
auto& ctx = optional_ctx.second;
switch (ctx.t())
{
case json::type::Number:
out += ctx.dump();
break;
case json::type::String:
if (action.t == ActionType::Tag)
escape(ctx.s, out);
else
out += ctx.s;
break;
case json::type::Function:
{
std::string execute_result = ctx.execute();
while (execute_result.find("{{") != std::string::npos)
{
template_t result_plug(execute_result);
execute_result = result_plug.render_string(*(stack[0]));
}
if (action.t == ActionType::Tag)
escape(execute_result, out);
else
out += execute_result;
}
break;
default:
throw std::runtime_error("not implemented tag type" + boost::lexical_cast<std::string>(static_cast<int>(ctx.t())));
}
}
break;
case ActionType::ElseBlock:
{
static context nullContext;
auto optional_ctx = find_context(tag_name(action), stack);
if (!optional_ctx.first)
{
stack.emplace_back(&nullContext);
break;
}
auto& ctx = optional_ctx.second;
switch (ctx.t())
{
case json::type::List:
if (ctx.l && !ctx.l->empty())
current = action.pos;
else
stack.emplace_back(&nullContext);
break;
case json::type::False:
case json::type::Null:
stack.emplace_back(&nullContext);
break;
default:
current = action.pos;
break;
}
break;
}
case ActionType::OpenBlock:
{
auto optional_ctx = find_context(tag_name(action), stack);
if (!optional_ctx.first)
{
current = action.pos;
break;
}
auto& ctx = optional_ctx.second;
switch (ctx.t())
{
case json::type::List:
if (ctx.l)
for (auto it = ctx.l->begin(); it != ctx.l->end(); ++it)
{
stack.push_back(&*it);
render_internal(current + 1, action.pos, stack, out, indent);
stack.pop_back();
}
current = action.pos;
break;
case json::type::Number:
case json::type::String:
case json::type::Object:
case json::type::True:
stack.push_back(&ctx);
break;
case json::type::False:
case json::type::Null:
current = action.pos;
break;
default:
throw std::runtime_error("{{#: not implemented context type: " + boost::lexical_cast<std::string>(static_cast<int>(ctx.t())));
break;
}
break;
}
case ActionType::CloseBlock:
stack.pop_back();
break;
default:
throw std::runtime_error("not implemented " + boost::lexical_cast<std::string>(static_cast<int>(action.t)));
}
current++;
}
auto& fragment = fragments_[actionEnd];
render_fragment(fragment, indent, out);
}
void render_fragment(const std::pair<int, int> fragment, int indent, std::string& out) const
{
if (indent)
{
for (int i = fragment.first; i < fragment.second; i++)
{
out += body_[i];
if (body_[i] == '\n' && i + 1 != static_cast<int>(body_.size()))
out.insert(out.size(), indent, ' ');
}
}
else
out.insert(out.size(), body_, fragment.first, fragment.second - fragment.first);
}
public:
/// Output a returnable template from this mustache template
rendered_template render() const
{
context empty_ctx;
std::vector<context*> stack;
stack.emplace_back(&empty_ctx);
std::string ret;
render_internal(0, fragments_.size() - 1, stack, ret, 0);
return rendered_template(ret);
}
/// Apply the values from the context provided and output a returnable template from this mustache template
rendered_template render(context& ctx) const
{
std::vector<context*> stack;
stack.emplace_back(&ctx);
std::string ret;
render_internal(0, fragments_.size() - 1, stack, ret, 0);
return rendered_template(ret);
}
/// Output a returnable template from this mustache template
std::string render_string() const
{
context empty_ctx;
std::vector<context*> stack;
stack.emplace_back(&empty_ctx);
std::string ret;
render_internal(0, fragments_.size() - 1, stack, ret, 0);
return ret;
}
/// Apply the values from the context provided and output a returnable template from this mustache template
std::string render_string(context& ctx) const
{
std::vector<context*> stack;
stack.emplace_back(&ctx);
std::string ret;
render_internal(0, fragments_.size() - 1, stack, ret, 0);
return ret;
}
private:
void parse()
{
std::string tag_open = "{{";
std::string tag_close = "}}";
std::vector<int> blockPositions;
size_t current = 0;
while (1)
{
size_t idx = body_.find(tag_open, current);
if (idx == body_.npos)
{
fragments_.emplace_back(static_cast<int>(current), static_cast<int>(body_.size()));
actions_.emplace_back(ActionType::Ignore, 0, 0);
break;
}
fragments_.emplace_back(static_cast<int>(current), static_cast<int>(idx));
idx += tag_open.size();
size_t endIdx = body_.find(tag_close, idx);
if (endIdx == idx)
{
throw invalid_template_exception("empty tag is not allowed");
}
if (endIdx == body_.npos)
{
// error, no matching tag
throw invalid_template_exception("not matched opening tag");
}
current = endIdx + tag_close.size();
switch (body_[idx])
{
case '#':
idx++;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
blockPositions.emplace_back(static_cast<int>(actions_.size()));
actions_.emplace_back(ActionType::OpenBlock, idx, endIdx);
break;
case '/':
idx++;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
{
auto& matched = actions_[blockPositions.back()];
if (body_.compare(idx, endIdx - idx,
body_, matched.start, matched.end - matched.start) != 0)
{
throw invalid_template_exception("not matched {{# {{/ pair: " +
body_.substr(matched.start, matched.end - matched.start) + ", " +
body_.substr(idx, endIdx - idx));
}
matched.pos = actions_.size();
}
actions_.emplace_back(ActionType::CloseBlock, idx, endIdx, blockPositions.back());
blockPositions.pop_back();
break;
case '^':
idx++;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
blockPositions.emplace_back(static_cast<int>(actions_.size()));
actions_.emplace_back(ActionType::ElseBlock, idx, endIdx);
break;
case '!':
// do nothing action
actions_.emplace_back(ActionType::Ignore, idx + 1, endIdx);
break;
case '>': // partial
idx++;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
actions_.emplace_back(ActionType::Partial, idx, endIdx);
break;
case '{':
if (tag_open != "{{" || tag_close != "}}")
throw invalid_template_exception("cannot use triple mustache when delimiter changed");
idx++;
if (body_[endIdx + 2] != '}')
{
throw invalid_template_exception("{{{: }}} not matched");
}
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
actions_.emplace_back(ActionType::UnescapeTag, idx, endIdx);
current++;
break;
case '&':
idx++;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
actions_.emplace_back(ActionType::UnescapeTag, idx, endIdx);
break;
case '=':
// tag itself is no-op
idx++;
actions_.emplace_back(ActionType::Ignore, idx, endIdx);
endIdx--;
if (body_[endIdx] != '=')
throw invalid_template_exception("{{=: not matching = tag: " + body_.substr(idx, endIdx - idx));
endIdx--;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx] == ' ')
endIdx--;
endIdx++;
{
bool succeeded = false;
for (size_t i = idx; i < endIdx; i++)
{
if (body_[i] == ' ')
{
tag_open = body_.substr(idx, i - idx);
while (body_[i] == ' ')
i++;
tag_close = body_.substr(i, endIdx - i);
if (tag_open.empty())
throw invalid_template_exception("{{=: empty open tag");
if (tag_close.empty())
throw invalid_template_exception("{{=: empty close tag");
if (tag_close.find(" ") != tag_close.npos)
throw invalid_template_exception("{{=: invalid open/close tag: " + tag_open + " " + tag_close);
succeeded = true;
break;
}
}
if (!succeeded)
throw invalid_template_exception("{{=: cannot find space between new open/close tags");
}
break;
default:
// normal tag case;
while (body_[idx] == ' ')
idx++;
while (body_[endIdx - 1] == ' ')
endIdx--;
actions_.emplace_back(ActionType::Tag, idx, endIdx);
break;
}
}
// removing standalones
for (int i = actions_.size() - 2; i >= 0; i--)
{
if (actions_[i].t == ActionType::Tag || actions_[i].t == ActionType::UnescapeTag)
continue;
auto& fragment_before = fragments_[i];
auto& fragment_after = fragments_[i + 1];
bool is_last_action = i == static_cast<int>(actions_.size()) - 2;
bool all_space_before = true;
int j, k;
for (j = fragment_before.second - 1; j >= fragment_before.first; j--)
{
if (body_[j] != ' ')
{
all_space_before = false;
break;
}
}
if (all_space_before && i > 0)
continue;
if (!all_space_before && body_[j] != '\n')
continue;
bool all_space_after = true;
for (k = fragment_after.first; k < static_cast<int>(body_.size()) && k < fragment_after.second; k++)
{
if (body_[k] != ' ')
{
all_space_after = false;
break;
}
}
if (all_space_after && !is_last_action)
continue;
if (!all_space_after &&
!(
body_[k] == '\n' ||
(body_[k] == '\r' &&
k + 1 < static_cast<int>(body_.size()) &&
body_[k + 1] == '\n')))
continue;
if (actions_[i].t == ActionType::Partial)
{
actions_[i].pos = fragment_before.second - j - 1;
}
fragment_before.second = j + 1;
if (!all_space_after)
{
if (body_[k] == '\n')
k++;
else
k += 2;
fragment_after.first = k;
}
}
}
std::vector<std::pair<int, int>> fragments_;
std::vector<Action> actions_;
std::string body_;
};
inline template_t compile(const std::string& body)
{
return template_t(body);
}
namespace detail
{
inline std::string& get_template_base_directory_ref()
{
static std::string template_base_directory = "templates";
return template_base_directory;
}
/// A base directory not related to any blueprint
inline std::string& get_global_template_base_directory_ref()
{
static std::string template_base_directory = "templates";
return template_base_directory;
}
} // namespace detail
inline std::string default_loader(const std::string& filename)
{
std::string path = detail::get_template_base_directory_ref();
if (!(path.back() == '/' || path.back() == '\\'))
path += '/';
path += filename;
std::ifstream inf(path);
if (!inf)
{
CROW_LOG_WARNING << "Template \"" << filename << "\" not found.";
return {};
}
return {std::istreambuf_iterator<char>(inf), std::istreambuf_iterator<char>()};
}
namespace detail
{
inline std::function<std::string(std::string)>& get_loader_ref()
{
static std::function<std::string(std::string)> loader = default_loader;
return loader;
}
} // namespace detail
inline void set_base(const std::string& path)
{
auto& base = detail::get_template_base_directory_ref();
base = path;
if (base.back() != '\\' &&
base.back() != '/')
{
base += '/';
}
}
inline void set_global_base(const std::string& path)
{
auto& base = detail::get_global_template_base_directory_ref();
base = path;
if (base.back() != '\\' &&
base.back() != '/')
{
base += '/';
}
}
inline void set_loader(std::function<std::string(std::string)> loader)
{
detail::get_loader_ref() = std::move(loader);
}
inline std::string load_text(const std::string& filename)
{
std::string filename_sanitized(filename);
utility::sanitize_filename(filename_sanitized);
return detail::get_loader_ref()(filename_sanitized);
}
inline std::string load_text_unsafe(const std::string& filename)
{
return detail::get_loader_ref()(filename);
}
inline template_t load(const std::string& filename)
{
std::string filename_sanitized(filename);
utility::sanitize_filename(filename_sanitized);
return compile(detail::get_loader_ref()(filename_sanitized));
}
inline template_t load_unsafe(const std::string& filename)
{
return compile(detail::get_loader_ref()(filename));
}
} // namespace mustache
} // namespace crow
#pragma once
#include <cstdint>
#include <utility>
#include <tuple>
#include <unordered_map>
#include <memory>
#include <boost/lexical_cast.hpp>
#include <vector>
namespace crow
{
constexpr const uint16_t INVALID_BP_ID{((uint16_t)-1)};
/// A base class for all rules.
///
/// Used to provide a common interface for code dealing with different types of rules.<br>
/// A Rule provides a URL, allowed HTTP methods, and handlers.
class BaseRule
{
public:
BaseRule(std::string rule):
rule_(std::move(rule))
{}
virtual ~BaseRule()
{}
virtual void validate() = 0;
std::unique_ptr<BaseRule> upgrade()
{
if (rule_to_upgrade_)
return std::move(rule_to_upgrade_);
return {};
}
virtual void handle(request&, response&, const routing_params&) = 0;
virtual void handle_upgrade(const request&, response& res, SocketAdaptor&&)
{
res = response(404);
res.end();
}
#ifdef CROW_ENABLE_SSL
virtual void handle_upgrade(const request&, response& res, SSLAdaptor&&)
{
res = response(404);
res.end();
}
#endif
uint32_t get_methods()
{
return methods_;
}
template<typename F>
void foreach_method(F f)
{
for (uint32_t method = 0, method_bit = 1; method < static_cast<uint32_t>(HTTPMethod::InternalMethodCount); method++, method_bit <<= 1)
{
if (methods_ & method_bit)
f(method);
}
}
std::string custom_templates_base;
const std::string& rule() { return rule_; }
protected:
uint32_t methods_{1 << static_cast<int>(HTTPMethod::Get)};
std::string rule_;
std::string name_;
std::unique_ptr<BaseRule> rule_to_upgrade_;
friend class Router;
friend class Blueprint;
template<typename T>
friend struct RuleParameterTraits;
};
namespace detail
{
namespace routing_handler_call_helper
{
template<typename T, int Pos>
struct call_pair
{
using type = T;
static const int pos = Pos;
};
template<typename H1>
struct call_params
{
H1& handler;
const routing_params& params;
request& req;
response& res;
};
template<typename F, int NInt, int NUint, int NDouble, int NString, typename S1, typename S2>
struct call
{};
template<typename F, int NInt, int NUint, int NDouble, int NString, typename... Args1, typename... Args2>
struct call<F, NInt, NUint, NDouble, NString, black_magic::S<int64_t, Args1...>, black_magic::S<Args2...>>
{
void operator()(F cparams)
{
using pushed = typename black_magic::S<Args2...>::template push_back<call_pair<int64_t, NInt>>;
call<F, NInt + 1, NUint, NDouble, NString, black_magic::S<Args1...>, pushed>()(cparams);
}
};
template<typename F, int NInt, int NUint, int NDouble, int NString, typename... Args1, typename... Args2>
struct call<F, NInt, NUint, NDouble, NString, black_magic::S<uint64_t, Args1...>, black_magic::S<Args2...>>
{
void operator()(F cparams)
{
using pushed = typename black_magic::S<Args2...>::template push_back<call_pair<uint64_t, NUint>>;
call<F, NInt, NUint + 1, NDouble, NString, black_magic::S<Args1...>, pushed>()(cparams);
}
};
template<typename F, int NInt, int NUint, int NDouble, int NString, typename... Args1, typename... Args2>
struct call<F, NInt, NUint, NDouble, NString, black_magic::S<double, Args1...>, black_magic::S<Args2...>>
{
void operator()(F cparams)
{
using pushed = typename black_magic::S<Args2...>::template push_back<call_pair<double, NDouble>>;
call<F, NInt, NUint, NDouble + 1, NString, black_magic::S<Args1...>, pushed>()(cparams);
}
};
template<typename F, int NInt, int NUint, int NDouble, int NString, typename... Args1, typename... Args2>
struct call<F, NInt, NUint, NDouble, NString, black_magic::S<std::string, Args1...>, black_magic::S<Args2...>>
{
void operator()(F cparams)
{
using pushed = typename black_magic::S<Args2...>::template push_back<call_pair<std::string, NString>>;
call<F, NInt, NUint, NDouble, NString + 1, black_magic::S<Args1...>, pushed>()(cparams);
}
};
template<typename F, int NInt, int NUint, int NDouble, int NString, typename... Args1>
struct call<F, NInt, NUint, NDouble, NString, black_magic::S<>, black_magic::S<Args1...>>
{
void operator()(F cparams)
{
cparams.handler(
cparams.req,
cparams.res,
cparams.params.template get<typename Args1::type>(Args1::pos)...);
}
};
template<typename Func, typename... ArgsWrapped>
struct Wrapped
{
template<typename... Args>
void set_(Func f, typename std::enable_if<!std::is_same<typename std::tuple_element<0, std::tuple<Args..., void>>::type, const request&>::value, int>::type = 0)
{
handler_ = (
#ifdef CROW_CAN_USE_CPP14
[f = std::move(f)]
#else
[f]
#endif
(const request&, response& res, Args... args) {
res = response(f(args...));
res.end();
});
}
template<typename Req, typename... Args>
struct req_handler_wrapper
{
req_handler_wrapper(Func f):
f(std::move(f))
{
}
void operator()(const request& req, response& res, Args... args)
{
res = response(f(req, args...));
res.end();
}
Func f;
};
template<typename... Args>
void set_(Func f, typename std::enable_if<
std::is_same<typename std::tuple_element<0, std::tuple<Args..., void>>::type, const request&>::value &&
!std::is_same<typename std::tuple_element<1, std::tuple<Args..., void, void>>::type, response&>::value,
int>::type = 0)
{
handler_ = req_handler_wrapper<Args...>(std::move(f));
/*handler_ = (
[f = std::move(f)]
(const request& req, response& res, Args... args){
res = response(f(req, args...));
res.end();
});*/
}
template<typename... Args>
void set_(Func f, typename std::enable_if<
std::is_same<typename std::tuple_element<0, std::tuple<Args..., void>>::type, const request&>::value &&
std::is_same<typename std::tuple_element<1, std::tuple<Args..., void, void>>::type, response&>::value,
int>::type = 0)
{
handler_ = std::move(f);
}
template<typename... Args>
struct handler_type_helper
{
using type = std::function<void(const crow::request&, crow::response&, Args...)>;
using args_type = black_magic::S<typename black_magic::promote_t<Args>...>;
};
template<typename... Args>
struct handler_type_helper<const request&, Args...>
{
using type = std::function<void(const crow::request&, crow::response&, Args...)>;
using args_type = black_magic::S<typename black_magic::promote_t<Args>...>;
};
template<typename... Args>
struct handler_type_helper<const request&, response&, Args...>
{
using type = std::function<void(const crow::request&, crow::response&, Args...)>;
using args_type = black_magic::S<typename black_magic::promote_t<Args>...>;
};
typename handler_type_helper<ArgsWrapped...>::type handler_;
void operator()(request& req, response& res, const routing_params& params)
{
detail::routing_handler_call_helper::call<
detail::routing_handler_call_helper::call_params<
decltype(handler_)>,
0, 0, 0, 0,
typename handler_type_helper<ArgsWrapped...>::args_type,
black_magic::S<>>()(
detail::routing_handler_call_helper::call_params<
decltype(handler_)>{handler_, params, req, res});
}
};
} // namespace routing_handler_call_helper
} // namespace detail
class CatchallRule
{
public:
/// @cond SKIP
CatchallRule() {}
template<typename Func>
typename std::enable_if<black_magic::CallHelper<Func, black_magic::S<>>::value, void>::type
operator()(Func&& f)
{
static_assert(!std::is_same<void, decltype(f())>::value,
"Handler function cannot have void return type; valid return types: string, int, crow::response, crow::returnable");
handler_ = (
#ifdef CROW_CAN_USE_CPP14
[f = std::move(f)]
#else
[f]
#endif
(const request&, response& res) {
res = response(f());
res.end();
});
}
template<typename Func>
typename std::enable_if<
!black_magic::CallHelper<Func, black_magic::S<>>::value &&
black_magic::CallHelper<Func, black_magic::S<crow::request>>::value,
void>::type
operator()(Func&& f)
{
static_assert(!std::is_same<void, decltype(f(std::declval<crow::request>()))>::value,
"Handler function cannot have void return type; valid return types: string, int, crow::response, crow::returnable");
handler_ = (
#ifdef CROW_CAN_USE_CPP14
[f = std::move(f)]
#else
[f]
#endif
(const crow::request& req, crow::response& res) {
res = response(f(req));
res.end();
});
}
template<typename Func>
typename std::enable_if<
!black_magic::CallHelper<Func, black_magic::S<>>::value &&
!black_magic::CallHelper<Func, black_magic::S<crow::request>>::value &&
black_magic::CallHelper<Func, black_magic::S<crow::response&>>::value,
void>::type
operator()(Func&& f)
{
static_assert(std::is_same<void, decltype(f(std::declval<crow::response&>()))>::value,
"Handler function with response argument should have void return type");
handler_ = (
#ifdef CROW_CAN_USE_CPP14
[f = std::move(f)]
#else
[f]
#endif
(const crow::request&, crow::response& res) {
f(res);
});
}
template<typename Func>
typename std::enable_if<
!black_magic::CallHelper<Func, black_magic::S<>>::value &&
!black_magic::CallHelper<Func, black_magic::S<crow::request>>::value &&
!black_magic::CallHelper<Func, black_magic::S<crow::response&>>::value,
void>::type
operator()(Func&& f)
{
static_assert(std::is_same<void, decltype(f(std::declval<crow::request>(), std::declval<crow::response&>()))>::value,
"Handler function with response argument should have void return type");
handler_ = std::move(f);
}
/// @endcond
bool has_handler()
{
return (handler_ != nullptr);
}
protected:
friend class Router;
private:
std::function<void(const crow::request&, crow::response&)> handler_;
};
/// A rule dealing with websockets.
///
/// Provides the interface for the user to put in the necessary handlers for a websocket to work.
class WebSocketRule : public BaseRule
{
using self_t = WebSocketRule;
public:
WebSocketRule(std::string rule):
BaseRule(std::move(rule))
{}
void validate() override
{}
void handle(request&, response& res, const routing_params&) override
{
res = response(404);
res.end();
}
void handle_upgrade(const request& req, response&, SocketAdaptor&& adaptor) override
{
new crow::websocket::Connection<SocketAdaptor>(req, std::move(adaptor), open_handler_, message_handler_, close_handler_, error_handler_, accept_handler_);
}
#ifdef CROW_ENABLE_SSL
void handle_upgrade(const request& req, response&, SSLAdaptor&& adaptor) override
{
new crow::websocket::Connection<SSLAdaptor>(req, std::move(adaptor), open_handler_, message_handler_, close_handler_, error_handler_, accept_handler_);
}
#endif
template<typename Func>
self_t& onopen(Func f)
{
open_handler_ = f;
return *this;
}
template<typename Func>
self_t& onmessage(Func f)
{
message_handler_ = f;
return *this;
}
template<typename Func>
self_t& onclose(Func f)
{
close_handler_ = f;
return *this;
}
template<typename Func>
self_t& onerror(Func f)
{
error_handler_ = f;
return *this;
}
template<typename Func>
self_t& onaccept(Func f)
{
accept_handler_ = f;
return *this;
}
protected:
std::function<void(crow::websocket::connection&)> open_handler_;
std::function<void(crow::websocket::connection&, const std::string&, bool)> message_handler_;
std::function<void(crow::websocket::connection&, const std::string&)> close_handler_;
std::function<void(crow::websocket::connection&)> error_handler_;
std::function<bool(const crow::request&)> accept_handler_;
};
/// Allows the user to assign parameters using functions.
///
/// `rule.name("name").methods(HTTPMethod::POST)`
template<typename T>
struct RuleParameterTraits
{
using self_t = T;
WebSocketRule& websocket()
{
auto p = new WebSocketRule(static_cast<self_t*>(this)->rule_);
static_cast<self_t*>(this)->rule_to_upgrade_.reset(p);
return *p;
}
self_t& name(std::string name) noexcept
{
static_cast<self_t*>(this)->name_ = std::move(name);
return static_cast<self_t&>(*this);
}
self_t& methods(HTTPMethod method)
{
static_cast<self_t*>(this)->methods_ = 1 << static_cast<int>(method);
return static_cast<self_t&>(*this);
}
template<typename... MethodArgs>
self_t& methods(HTTPMethod method, MethodArgs... args_method)
{
methods(args_method...);
static_cast<self_t*>(this)->methods_ |= 1 << static_cast<int>(method);
return static_cast<self_t&>(*this);
}
};
/// A rule that can change its parameters during runtime.
class DynamicRule : public BaseRule, public RuleParameterTraits<DynamicRule>
{
public:
DynamicRule(std::string rule):
BaseRule(std::move(rule))
{}
void validate() override
{
if (!erased_handler_)
{
throw std::runtime_error(name_ + (!name_.empty() ? ": " : "") + "no handler for url " + rule_);
}
}
void handle(request& req, response& res, const routing_params& params) override
{
if (!custom_templates_base.empty())
mustache::set_base(custom_templates_base);
else if (mustache::detail::get_template_base_directory_ref() != "templates")
mustache::set_base("templates");
erased_handler_(req, res, params);
}
template<typename Func>
void operator()(Func f)
{
#ifdef CROW_MSVC_WORKAROUND
using function_t = utility::function_traits<decltype(&Func::operator())>;
#else
using function_t = utility::function_traits<Func>;
#endif
erased_handler_ = wrap(std::move(f), black_magic::gen_seq<function_t::arity>());
}
// enable_if Arg1 == request && Arg2 == response
// enable_if Arg1 == request && Arg2 != resposne
// enable_if Arg1 != request
#ifdef CROW_MSVC_WORKAROUND
template<typename Func, size_t... Indices>
#else
template<typename Func, unsigned... Indices>
#endif
std::function<void(request&, response&, const routing_params&)>
wrap(Func f, black_magic::seq<Indices...>)
{
#ifdef CROW_MSVC_WORKAROUND
using function_t = utility::function_traits<decltype(&Func::operator())>;
#else
using function_t = utility::function_traits<Func>;
#endif
if (!black_magic::is_parameter_tag_compatible(
black_magic::get_parameter_tag_runtime(rule_.c_str()),
black_magic::compute_parameter_tag_from_args_list<
typename function_t::template arg<Indices>...>::value))
{
throw std::runtime_error("route_dynamic: Handler type is mismatched with URL parameters: " + rule_);
}
auto ret = detail::routing_handler_call_helper::Wrapped<Func, typename function_t::template arg<Indices>...>();
ret.template set_<
typename function_t::template arg<Indices>...>(std::move(f));
return ret;
}
template<typename Func>
void operator()(std::string name, Func&& f)
{
name_ = std::move(name);
(*this).template operator()<Func>(std::forward(f));
}
private:
std::function<void(request&, response&, const routing_params&)> erased_handler_;
};
/// Default rule created when CROW_ROUTE is called.
template<typename... Args>
class TaggedRule : public BaseRule, public RuleParameterTraits<TaggedRule<Args...>>
{
public:
using self_t = TaggedRule<Args...>;
TaggedRule(std::string rule):
BaseRule(std::move(rule))
{}
void validate() override
{
if (!handler_)
{
throw std::runtime_error(name_ + (!name_.empty() ? ": " : "") + "no handler for url " + rule_);
}
}
template<typename Func>
void operator()(Func&& f)
{
handler_ = (
#ifdef CROW_CAN_USE_CPP14
[f = std::move(f)]
#else
[f]
#endif
(crow::request& req, crow::response& res, Args... args) {
detail::wrapped_handler_call(req, res, f, std::forward<Args>(args)...);
});
}
template<typename Func>
void operator()(std::string name, Func&& f)
{
name_ = std::move(name);
(*this).template operator()<Func>(std::forward(f));
}
void handle(request& req, response& res, const routing_params& params) override
{
if (!custom_templates_base.empty())
mustache::set_base(custom_templates_base);
else if (mustache::detail::get_template_base_directory_ref() != mustache::detail::get_global_template_base_directory_ref())
mustache::set_base(mustache::detail::get_global_template_base_directory_ref());
detail::routing_handler_call_helper::call<
detail::routing_handler_call_helper::call_params<decltype(handler_)>,
0, 0, 0, 0,
black_magic::S<Args...>,
black_magic::S<>>()(
detail::routing_handler_call_helper::call_params<decltype(handler_)>{handler_, params, req, res});
}
/// Enable local middleware for this handler
template<typename App, typename... Middlewares>
crow::detail::handler_call_bridge<TaggedRule<Args...>, App, Middlewares...>
middlewares()
{
// the handler_call_bridge allows the functor to be placed directly after this function
// instead of wrapping it with more parentheses
return {this};
}
private:
std::function<void(crow::request&, crow::response&, Args...)> handler_;
};
const int RULE_SPECIAL_REDIRECT_SLASH = 1;
/// A search tree.
class Trie
{
public:
struct Node
{
uint16_t rule_index{};
// Assign the index to the maximum 32 unsigned integer value by default so that any other number (specifically 0) is a valid BP id.
uint16_t blueprint_index{INVALID_BP_ID};
std::string key;
ParamType param = ParamType::MAX; // MAX = No param.
std::vector<Node*> children;
bool IsSimpleNode() const
{
return !rule_index &&
blueprint_index == INVALID_BP_ID &&
children.size() < 2 &&
param == ParamType::MAX &&
std::all_of(std::begin(children), std::end(children), [](Node* x) {
return x->param == ParamType::MAX;
});
}
};
Trie()
{}
/// Check whether or not the trie is empty.
bool is_empty()
{
return head_.children.empty();
}
void optimize()
{
for (auto child : head_.children)
{
optimizeNode(child);
}
}
private:
void optimizeNode(Node* node)
{
if (node->children.empty())
return;
if (node->IsSimpleNode())
{
Node* child_temp = node->children[0];
node->key = node->key + child_temp->key;
node->rule_index = child_temp->rule_index;
node->blueprint_index = child_temp->blueprint_index;
node->children = std::move(child_temp->children);
delete (child_temp);
optimizeNode(node);
}
else
{
for (auto& child : node->children)
{
optimizeNode(child);
}
}
}
void debug_node_print(Node* node, int level)
{
if (node->param != ParamType::MAX)
{
switch (node->param)
{
case ParamType::INT:
CROW_LOG_DEBUG << std::string(2 * level, ' ') << "<int>";
break;
case ParamType::UINT:
CROW_LOG_DEBUG << std::string(2 * level, ' ') << "<uint>";
break;
case ParamType::DOUBLE:
CROW_LOG_DEBUG << std::string(2 * level, ' ') << "<double>";
break;
case ParamType::STRING:
CROW_LOG_DEBUG << std::string(2 * level, ' ') << "<string>";
break;
case ParamType::PATH:
CROW_LOG_DEBUG << std::string(2 * level, ' ') << "<path>";
break;
default:
CROW_LOG_DEBUG << std::string(2 * level, ' ') << "<ERROR>";
break;
}
}
else
CROW_LOG_DEBUG << std::string(2 * level, ' ') << node->key;
for (auto& child : node->children)
{
debug_node_print(child, level + 1);
}
}
public:
void debug_print()
{
CROW_LOG_DEBUG << "HEAD";
for (auto& child : head_.children)
debug_node_print(child, 1);
}
void validate()
{
if (!head_.IsSimpleNode())
throw std::runtime_error("Internal error: Trie header should be simple!");
optimize();
}
//Rule_index, Blueprint_index, routing_params
std::tuple<uint16_t, std::vector<uint16_t>, routing_params> find(const std::string& req_url, const Node* node = nullptr, unsigned pos = 0, routing_params* params = nullptr, std::vector<uint16_t>* blueprints = nullptr) const
{
//start params as an empty struct
routing_params empty;
if (params == nullptr)
params = &empty;
//same for blueprint vector
std::vector<uint16_t> MT;
if (blueprints == nullptr)
blueprints = &MT;
uint16_t found{}; //The rule index to be found
std::vector<uint16_t> found_BP; //The Blueprint indices to be found
routing_params match_params; //supposedly the final matched parameters
//start from the head node
if (node == nullptr)
node = &head_;
auto update_found = [&found, &found_BP, &match_params](std::tuple<uint16_t, std::vector<uint16_t>, routing_params>& ret) {
found_BP = std::move(std::get<1>(ret));
if (std::get<0>(ret) && (!found || found > std::get<0>(ret)))
{
found = std::get<0>(ret);
match_params = std::move(std::get<2>(ret));
}
};
//if the function was called on a node at the end of the string (the last recursion), return the nodes rule index, and whatever params were passed to the function
if (pos == req_url.size())
{
found_BP = std::move(*blueprints);
return std::tuple<uint16_t, std::vector<uint16_t>, routing_params>{node->rule_index, *blueprints, *params};
}
bool found_fragment = false;
for (auto& child : node->children)
{
if (child->param != ParamType::MAX)
{
if (child->param == ParamType::INT)
{
char c = req_url[pos];
if ((c >= '0' && c <= '9') || c == '+' || c == '-')
{
char* eptr;
errno = 0;
long long int value = strtoll(req_url.data() + pos, &eptr, 10);
if (errno != ERANGE && eptr != req_url.data() + pos)
{
found_fragment = true;
params->int_params.push_back(value);
if (child->blueprint_index != INVALID_BP_ID) blueprints->push_back(child->blueprint_index);
auto ret = find(req_url, child, eptr - req_url.data(), params, blueprints);
update_found(ret);
params->int_params.pop_back();
if (!blueprints->empty()) blueprints->pop_back();
}
}
}
else if (child->param == ParamType::UINT)
{
char c = req_url[pos];
if ((c >= '0' && c <= '9') || c == '+')
{
char* eptr;
errno = 0;
unsigned long long int value = strtoull(req_url.data() + pos, &eptr, 10);
if (errno != ERANGE && eptr != req_url.data() + pos)
{
found_fragment = true;
params->uint_params.push_back(value);
if (child->blueprint_index != INVALID_BP_ID) blueprints->push_back(child->blueprint_index);
auto ret = find(req_url, child, eptr - req_url.data(), params, blueprints);
update_found(ret);
params->uint_params.pop_back();
if (!blueprints->empty()) blueprints->pop_back();
}
}
}
else if (child->param == ParamType::DOUBLE)
{
char c = req_url[pos];
if ((c >= '0' && c <= '9') || c == '+' || c == '-' || c == '.')
{
char* eptr;
errno = 0;
double value = strtod(req_url.data() + pos, &eptr);
if (errno != ERANGE && eptr != req_url.data() + pos)
{
found_fragment = true;
params->double_params.push_back(value);
if (child->blueprint_index != INVALID_BP_ID) blueprints->push_back(child->blueprint_index);
auto ret = find(req_url, child, eptr - req_url.data(), params, blueprints);
update_found(ret);
params->double_params.pop_back();
if (!blueprints->empty()) blueprints->pop_back();
}
}
}
else if (child->param == ParamType::STRING)
{
size_t epos = pos;
for (; epos < req_url.size(); epos++)
{
if (req_url[epos] == '/')
break;
}
if (epos != pos)
{
found_fragment = true;
params->string_params.push_back(req_url.substr(pos, epos - pos));
if (child->blueprint_index != INVALID_BP_ID) blueprints->push_back(child->blueprint_index);
auto ret = find(req_url, child, epos, params, blueprints);
update_found(ret);
params->string_params.pop_back();
if (!blueprints->empty()) blueprints->pop_back();
}
}
else if (child->param == ParamType::PATH)
{
size_t epos = req_url.size();
if (epos != pos)
{
found_fragment = true;
params->string_params.push_back(req_url.substr(pos, epos - pos));
if (child->blueprint_index != INVALID_BP_ID) blueprints->push_back(child->blueprint_index);
auto ret = find(req_url, child, epos, params, blueprints);
update_found(ret);
params->string_params.pop_back();
if (!blueprints->empty()) blueprints->pop_back();
}
}
}
else
{
const std::string& fragment = child->key;
if (req_url.compare(pos, fragment.size(), fragment) == 0)
{
found_fragment = true;
if (child->blueprint_index != INVALID_BP_ID) blueprints->push_back(child->blueprint_index);
auto ret = find(req_url, child, pos + fragment.size(), params, blueprints);
update_found(ret);
if (!blueprints->empty()) blueprints->pop_back();
}
}
}
if (!found_fragment)
found_BP = std::move(*blueprints);
return std::tuple<uint16_t, std::vector<uint16_t>, routing_params>{found, found_BP, match_params}; //Called after all the recursions have been done
}
//This functions assumes any blueprint info passed is valid
void add(const std::string& url, uint16_t rule_index, unsigned bp_prefix_length = 0, uint16_t blueprint_index = INVALID_BP_ID)
{
Node* idx = &head_;
bool has_blueprint = bp_prefix_length != 0 && blueprint_index != INVALID_BP_ID;
for (unsigned i = 0; i < url.size(); i++)
{
char c = url[i];
if (c == '<')
{
static struct ParamTraits
{
ParamType type;
std::string name;
} paramTraits[] =
{
{ParamType::INT, "<int>"},
{ParamType::UINT, "<uint>"},
{ParamType::DOUBLE, "<float>"},
{ParamType::DOUBLE, "<double>"},
{ParamType::STRING, "<str>"},
{ParamType::STRING, "<string>"},
{ParamType::PATH, "<path>"},
};
for (auto& x : paramTraits)
{
if (url.compare(i, x.name.size(), x.name) == 0)
{
bool found = false;
for (Node* child : idx->children)
{
if (child->param == x.type)
{
idx = child;
i += x.name.size();
found = true;
break;
}
}
if (found)
break;
auto new_node_idx = new_node(idx);
new_node_idx->param = x.type;
idx = new_node_idx;
i += x.name.size();
break;
}
}
i--;
}
else
{
//This part assumes the tree is unoptimized (every node has a max 1 character key)
bool piece_found = false;
for (auto& child : idx->children)
{
if (child->key[0] == c)
{
idx = child;
piece_found = true;
break;
}
}
if (!piece_found)
{
auto new_node_idx = new_node(idx);
new_node_idx->key = c;
//The assumption here is that you'd only need to add a blueprint index if the tree didn't have the BP prefix.
if (has_blueprint && i == bp_prefix_length)
new_node_idx->blueprint_index = blueprint_index;
idx = new_node_idx;
}
}
}
//check if the last node already has a value (exact url already in Trie)
if (idx->rule_index)
throw std::runtime_error("handler already exists for " + url);
idx->rule_index = rule_index;
}
size_t get_size()
{
return get_size(&head_);
}
size_t get_size(Node* node)
{
unsigned size = 5; //rule_index, blueprint_index, and param
size += (node->key.size()); //each character in the key is 1 byte
for (auto child : node->children)
{
size += get_size(child);
}
return size;
}
private:
Node* new_node(Node* parent)
{
auto& children = parent->children;
children.resize(children.size() + 1);
children[children.size() - 1] = new Node();
return children[children.size() - 1];
}
Node head_;
};
/// A blueprint can be considered a smaller section of a Crow app, specifically where the router is conecerned.
///
/// You can use blueprints to assign a common prefix to rules' prefix, set custom static and template folders, and set a custom catchall route.
/// You can also assign nest blueprints for maximum Compartmentalization.
class Blueprint
{
public:
Blueprint(const std::string& prefix):
prefix_(prefix){};
Blueprint(const std::string& prefix, const std::string& static_dir):
prefix_(prefix), static_dir_(static_dir){};
Blueprint(const std::string& prefix, const std::string& static_dir, const std::string& templates_dir):
prefix_(prefix), static_dir_(static_dir), templates_dir_(templates_dir){};
/*
Blueprint(Blueprint& other)
{
prefix_ = std::move(other.prefix_);
all_rules_ = std::move(other.all_rules_);
}
Blueprint(const Blueprint& other)
{
prefix_ = other.prefix_;
all_rules_ = other.all_rules_;
}
*/
Blueprint(Blueprint&& value)
{
*this = std::move(value);
}
Blueprint& operator=(const Blueprint& value) = delete;
Blueprint& operator=(Blueprint&& value) noexcept
{
prefix_ = std::move(value.prefix_);
all_rules_ = std::move(value.all_rules_);
catchall_rule_ = std::move(value.catchall_rule_);
return *this;
}
bool operator==(const Blueprint& value)
{
return value.prefix() == prefix_;
}
bool operator!=(const Blueprint& value)
{
return value.prefix() != prefix_;
}
std::string prefix() const
{
return prefix_;
}
std::string static_dir() const
{
return static_dir_;
}
DynamicRule& new_rule_dynamic(std::string&& rule)
{
std::string new_rule = std::move(rule);
new_rule = '/' + prefix_ + new_rule;
auto ruleObject = new DynamicRule(new_rule);
ruleObject->custom_templates_base = templates_dir_;
all_rules_.emplace_back(ruleObject);
return *ruleObject;
}
template<uint64_t N>
typename black_magic::arguments<N>::type::template rebind<TaggedRule>& new_rule_tagged(std::string&& rule)
{
std::string new_rule = std::move(rule);
new_rule = '/' + prefix_ + new_rule;
using RuleT = typename black_magic::arguments<N>::type::template rebind<TaggedRule>;
auto ruleObject = new RuleT(new_rule);
ruleObject->custom_templates_base = templates_dir_;
all_rules_.emplace_back(ruleObject);
return *ruleObject;
}
void register_blueprint(Blueprint& blueprint)
{
if (blueprints_.empty() || std::find(blueprints_.begin(), blueprints_.end(), &blueprint) == blueprints_.end())
{
apply_blueprint(blueprint);
blueprints_.emplace_back(&blueprint);
}
else
throw std::runtime_error("blueprint \"" + blueprint.prefix_ + "\" already exists in blueprint \"" + prefix_ + '\"');
}
CatchallRule& catchall_rule()
{
return catchall_rule_;
}
private:
void apply_blueprint(Blueprint& blueprint)
{
blueprint.prefix_ = prefix_ + '/' + blueprint.prefix_;
blueprint.static_dir_ = static_dir_ + '/' + blueprint.static_dir_;
blueprint.templates_dir_ = templates_dir_ + '/' + blueprint.templates_dir_;
for (auto& rule : blueprint.all_rules_)
{
std::string new_rule = '/' + prefix_ + rule->rule_;
rule->rule_ = new_rule;
}
for (Blueprint* bp_child : blueprint.blueprints_)
{
Blueprint& bp_ref = *bp_child;
apply_blueprint(bp_ref);
}
}
std::string prefix_;
std::string static_dir_;
std::string templates_dir_;
std::vector<std::unique_ptr<BaseRule>> all_rules_;
CatchallRule catchall_rule_;
std::vector<Blueprint*> blueprints_;
friend class Router;
};
/// Handles matching requests to existing rules and upgrade requests.
class Router
{
public:
Router()
{}
DynamicRule& new_rule_dynamic(const std::string& rule)
{
auto ruleObject = new DynamicRule(rule);
all_rules_.emplace_back(ruleObject);
return *ruleObject;
}
template<uint64_t N>
typename black_magic::arguments<N>::type::template rebind<TaggedRule>& new_rule_tagged(const std::string& rule)
{
using RuleT = typename black_magic::arguments<N>::type::template rebind<TaggedRule>;
auto ruleObject = new RuleT(rule);
all_rules_.emplace_back(ruleObject);
return *ruleObject;
}
CatchallRule& catchall_rule()
{
return catchall_rule_;
}
void internal_add_rule_object(const std::string& rule, BaseRule* ruleObject, const uint16_t& BP_index, std::vector<Blueprint*>& blueprints)
{
bool has_trailing_slash = false;
std::string rule_without_trailing_slash;
if (rule.size() > 1 && rule.back() == '/')
{
has_trailing_slash = true;
rule_without_trailing_slash = rule;
rule_without_trailing_slash.pop_back();
}
ruleObject->foreach_method([&](int method) {
per_methods_[method].rules.emplace_back(ruleObject);
per_methods_[method].trie.add(rule, per_methods_[method].rules.size() - 1, BP_index != INVALID_BP_ID ? blueprints[BP_index]->prefix().length() : 0, BP_index);
// directory case:
// request to '/about' url matches '/about/' rule
if (has_trailing_slash)
{
per_methods_[method].trie.add(rule_without_trailing_slash, RULE_SPECIAL_REDIRECT_SLASH, BP_index != INVALID_BP_ID ? blueprints_[BP_index]->prefix().length() : 0, BP_index);
}
});
}
void register_blueprint(Blueprint& blueprint)
{
if (std::find(blueprints_.begin(), blueprints_.end(), &blueprint) == blueprints_.end())
{
blueprints_.emplace_back(&blueprint);
}
else
throw std::runtime_error("blueprint \"" + blueprint.prefix_ + "\" already exists in router");
}
void get_recursive_child_methods(Blueprint* blueprint, std::vector<HTTPMethod>& methods)
{
//we only need to deal with children if the blueprint has absolutely no methods (meaning its index won't be added to the trie)
if (blueprint->static_dir_.empty() && blueprint->all_rules_.empty())
{
for (Blueprint* bp : blueprint->blueprints_)
{
get_recursive_child_methods(bp, methods);
}
}
else if (!blueprint->static_dir_.empty())
methods.emplace_back(HTTPMethod::Get);
for (auto& rule : blueprint->all_rules_)
{
rule->foreach_method([&methods](unsigned method) {
HTTPMethod method_final = static_cast<HTTPMethod>(method);
if (std::find(methods.begin(), methods.end(), method_final) == methods.end())
methods.emplace_back(method_final);
});
}
}
void validate_bp(std::vector<Blueprint*> blueprints)
{
for (unsigned i = 0; i < blueprints.size(); i++)
{
Blueprint* blueprint = blueprints[i];
if (blueprint->static_dir_ == "" && blueprint->all_rules_.empty())
{
std::vector<HTTPMethod> methods;
get_recursive_child_methods(blueprint, methods);
for (HTTPMethod x : methods)
{
int i = static_cast<int>(x);
per_methods_[i].trie.add(blueprint->prefix(), 0, blueprint->prefix().length(), i);
}
}
for (auto& rule : blueprint->all_rules_)
{
if (rule)
{
auto upgraded = rule->upgrade();
if (upgraded)
rule = std::move(upgraded);
rule->validate();
internal_add_rule_object(rule->rule(), rule.get(), i, blueprints);
}
}
validate_bp(blueprint->blueprints_);
}
}
void validate()
{
//Take all the routes from the registered blueprints and add them to `all_rules_` to be processed.
validate_bp(blueprints_);
for (auto& rule : all_rules_)
{
if (rule)
{
auto upgraded = rule->upgrade();
if (upgraded)
rule = std::move(upgraded);
rule->validate();
internal_add_rule_object(rule->rule(), rule.get(), INVALID_BP_ID, blueprints_);
}
}
for (auto& per_method : per_methods_)
{
per_method.trie.validate();
}
}
// TODO maybe add actual_method
template<typename Adaptor>
void handle_upgrade(const request& req, response& res, Adaptor&& adaptor)
{
if (req.method >= HTTPMethod::InternalMethodCount)
return;
auto& per_method = per_methods_[static_cast<int>(req.method)];
auto& rules = per_method.rules;
unsigned rule_index = std::get<0>(per_method.trie.find(req.url));
if (!rule_index)
{
for (auto& per_method : per_methods_)
{
if (std::get<0>(per_method.trie.find(req.url)))
{
CROW_LOG_DEBUG << "Cannot match method " << req.url << " " << method_name(req.method);
res = response(405);
res.end();
return;
}
}
CROW_LOG_INFO << "Cannot match rules " << req.url;
res = response(404);
res.end();
return;
}
if (rule_index >= rules.size())
throw std::runtime_error("Trie internal structure corrupted!");
if (rule_index == RULE_SPECIAL_REDIRECT_SLASH)
{
CROW_LOG_INFO << "Redirecting to a url with trailing slash: " << req.url;
res = response(301);
// TODO(ipkn) absolute url building
if (req.get_header_value("Host").empty())
{
res.add_header("Location", req.url + "/");
}
else
{
res.add_header("Location", "http://" + req.get_header_value("Host") + req.url + "/");
}
res.end();
return;
}
CROW_LOG_DEBUG << "Matched rule (upgrade) '" << rules[rule_index]->rule_ << "' " << static_cast<uint32_t>(req.method) << " / " << rules[rule_index]->get_methods();
// any uncaught exceptions become 500s
try
{
rules[rule_index]->handle_upgrade(req, res, std::move(adaptor));
}
catch (std::exception& e)
{
CROW_LOG_ERROR << "An uncaught exception occurred: " << e.what();
res = response(500);
res.end();
return;
}
catch (...)
{
CROW_LOG_ERROR << "An uncaught exception occurred. The type was unknown so no information was available.";
res = response(500);
res.end();
return;
}
}
void get_found_bp(std::vector<uint16_t>& bp_i, std::vector<Blueprint*>& blueprints, std::vector<Blueprint*>& found_bps, uint16_t index = 0)
{
// This statement makes 3 assertions:
// 1. The index is above 0.
// 2. The index does not lie outside the given blueprint list.
// 3. The next blueprint we're adding has a prefix that starts the same as the already added blueprint + a slash (the rest is irrelevant).
//
// This is done to prevent a blueprint that has a prefix of "bp_prefix2" to be assumed as a child of one that has "bp_prefix".
//
// If any of the assertions is untrue, we delete the last item added, and continue using the blueprint list of the blueprint found before, the topmost being the router's list
auto verify_prefix = [&bp_i, &index, &blueprints, &found_bps]() {
return index > 0 &&
bp_i[index] < blueprints.size() &&
blueprints[bp_i[index]]->prefix().substr(0, found_bps[index - 1]->prefix().length() + 1).compare(std::string(found_bps[index - 1]->prefix() + '/')) == 0;
};
if (index < bp_i.size())
{
if (verify_prefix())
{
found_bps.push_back(blueprints[bp_i[index]]);
get_found_bp(bp_i, found_bps.back()->blueprints_, found_bps, ++index);
}
else
{
if (found_bps.size() < 2)
{
found_bps.clear();
found_bps.push_back(blueprints_[bp_i[index]]);
}
else
{
found_bps.pop_back();
Blueprint* last_element = found_bps.back();
found_bps.push_back(last_element->blueprints_[bp_i[index]]);
}
get_found_bp(bp_i, found_bps.back()->blueprints_, found_bps, ++index);
}
}
}
/// Is used to handle errors, you insert the error code, found route, request, and response. and it'll either call the appropriate catchall route (considering the blueprint system) and send you a status string (which is mainly used for debug messages), or just set the response code to the proper error code.
std::string get_error(unsigned short code, std::tuple<uint16_t, std::vector<uint16_t>, routing_params>& found, const request& req, response& res)
{
res.code = code;
std::vector<Blueprint*> bps_found;
get_found_bp(std::get<1>(found), blueprints_, bps_found);
for (int i = bps_found.size() - 1; i > 0; i--)
{
std::vector<uint16_t> bpi = std::get<1>(found);
if (bps_found[i]->catchall_rule().has_handler())
{
bps_found[i]->catchall_rule().handler_(req, res);
#ifdef CROW_ENABLE_DEBUG
return std::string("Redirected to Blueprint \"" + bps_found[i]->prefix() + "\" Catchall rule");
#else
return std::string();
#endif
}
}
if (catchall_rule_.has_handler())
{
catchall_rule_.handler_(req, res);
#ifdef CROW_ENABLE_DEBUG
return std::string("Redirected to global Catchall rule");
#else
return std::string();
#endif
}
return std::string();
}
void handle(request& req, response& res)
{
HTTPMethod method_actual = req.method;
if (req.method >= HTTPMethod::InternalMethodCount)
return;
else if (req.method == HTTPMethod::Head)
{
method_actual = HTTPMethod::Get;
res.skip_body = true;
}
else if (req.method == HTTPMethod::Options)
{
std::string allow = "OPTIONS, HEAD, ";
if (req.url == "/*")
{
for (int i = 0; i < static_cast<int>(HTTPMethod::InternalMethodCount); i++)
{
if (!per_methods_[i].trie.is_empty())
{
allow += method_name(static_cast<HTTPMethod>(i)) + ", ";
}
}
allow = allow.substr(0, allow.size() - 2);
res = response(204);
res.set_header("Allow", allow);
res.end();
return;
}
else
{
for (int i = 0; i < static_cast<int>(HTTPMethod::InternalMethodCount); i++)
{
if (std::get<0>(per_methods_[i].trie.find(req.url)))
{
allow += method_name(static_cast<HTTPMethod>(i)) + ", ";
}
}
if (allow != "OPTIONS, HEAD, ")
{
allow = allow.substr(0, allow.size() - 2);
res = response(204);
res.set_header("Allow", allow);
res.end();
return;
}
else
{
CROW_LOG_DEBUG << "Cannot match rules " << req.url;
res = response(404);
res.end();
return;
}
}
}
auto& per_method = per_methods_[static_cast<int>(method_actual)];
auto& trie = per_method.trie;
auto& rules = per_method.rules;
auto found = trie.find(req.url);
unsigned rule_index = std::get<0>(found);
if (!rule_index)
{
for (auto& per_method : per_methods_)
{
if (std::get<0>(per_method.trie.find(req.url))) //Route found, but in another method
{
const std::string error_message(get_error(405, found, req, res));
CROW_LOG_DEBUG << "Cannot match method " << req.url << " " << method_name(method_actual) << ". " << error_message;
res.end();
return;
}
}
//Route does not exist anywhere
const std::string error_message(get_error(404, found, req, res));
CROW_LOG_DEBUG << "Cannot match rules " << req.url << ". " << error_message;
res.end();
return;
}
if (rule_index >= rules.size())
throw std::runtime_error("Trie internal structure corrupted!");
if (rule_index == RULE_SPECIAL_REDIRECT_SLASH)
{
CROW_LOG_INFO << "Redirecting to a url with trailing slash: " << req.url;
res = response(301);
// TODO(ipkn) absolute url building
if (req.get_header_value("Host").empty())
{
res.add_header("Location", req.url + "/");
}
else
{
res.add_header("Location", "http://" + req.get_header_value("Host") + req.url + "/");
}
res.end();
return;
}
CROW_LOG_DEBUG << "Matched rule '" << rules[rule_index]->rule_ << "' " << static_cast<uint32_t>(req.method) << " / " << rules[rule_index]->get_methods();
// any uncaught exceptions become 500s
try
{
rules[rule_index]->handle(req, res, std::get<2>(found));
}
catch (std::exception& e)
{
CROW_LOG_ERROR << "An uncaught exception occurred: " << e.what();
res = response(500);
res.end();
return;
}
catch (...)
{
CROW_LOG_ERROR << "An uncaught exception occurred. The type was unknown so no information was available.";
res = response(500);
res.end();
return;
}
}
void debug_print()
{
for (int i = 0; i < static_cast<int>(HTTPMethod::InternalMethodCount); i++)
{
CROW_LOG_DEBUG << method_name(static_cast<HTTPMethod>(i));
per_methods_[i].trie.debug_print();
}
}
std::vector<Blueprint*>& blueprints()
{
return blueprints_;
}
private:
CatchallRule catchall_rule_;
struct PerMethod
{
std::vector<BaseRule*> rules;
Trie trie;
// rule index 0, 1 has special meaning; preallocate it to avoid duplication.
PerMethod():
rules(2) {}
};
std::array<PerMethod, static_cast<int>(HTTPMethod::InternalMethodCount)> per_methods_;
std::vector<std::unique_ptr<BaseRule>> all_rules_;
std::vector<Blueprint*> blueprints_;
};
} // namespace crow
#pragma once
namespace crow
{
struct CORSHandler;
/// Used for tuning CORS policies
struct CORSRules
{
friend struct crow::CORSHandler;
/// Set Access-Control-Allow-Origin. Default is "*"
CORSRules& origin(const std::string& origin)
{
origin_ = origin;
return *this;
}
/// Set Access-Control-Allow-Methods. Default is "*"
CORSRules& methods(crow::HTTPMethod method)
{
add_list_item(methods_, crow::method_name(method));
return *this;
}
/// Set Access-Control-Allow-Methods. Default is "*"
template<typename... Methods>
CORSRules& methods(crow::HTTPMethod method, Methods... method_list)
{
add_list_item(methods_, crow::method_name(method));
methods(method_list...);
return *this;
}
/// Set Access-Control-Allow-Headers. Default is "*"
CORSRules& headers(const std::string& header)
{
add_list_item(headers_, header);
return *this;
}
/// Set Access-Control-Allow-Headers. Default is "*"
template<typename... Headers>
CORSRules& headers(const std::string& header, Headers... header_list)
{
add_list_item(headers_, header);
headers(header_list...);
return *this;
}
/// Set Access-Control-Max-Age. Default is none
CORSRules& max_age(int max_age)
{
max_age_ = std::to_string(max_age);
return *this;
}
/// Enable Access-Control-Allow-Credentials
CORSRules& allow_credentials()
{
allow_credentials_ = true;
return *this;
}
/// Ignore CORS and don't send any headers
void ignore()
{
ignore_ = true;
}
/// Handle CORS on specific prefix path
CORSRules& prefix(const std::string& prefix);
/// Handle CORS for specific blueprint
CORSRules& blueprint(const Blueprint& bp);
/// Global CORS policy
CORSRules& global();
private:
CORSRules() = delete;
CORSRules(CORSHandler* handler):
handler_(handler) {}
/// build comma separated list
void add_list_item(std::string& list, const std::string& val)
{
if (list == "*") list = "";
if (list.size() > 0) list += ", ";
list += val;
}
/// Set header `key` to `value` if it is not set
void set_header_no_override(const std::string& key, const std::string& value, crow::response& res)
{
if (value.size() == 0) return;
if (!get_header_value(res.headers, key).empty()) return;
res.add_header(key, value);
}
/// Set response headers
void apply(crow::response& res)
{
if (ignore_) return;
set_header_no_override("Access-Control-Allow-Origin", origin_, res);
set_header_no_override("Access-Control-Allow-Methods", methods_, res);
set_header_no_override("Access-Control-Allow-Headers", headers_, res);
set_header_no_override("Access-Control-Max-Age", max_age_, res);
if (allow_credentials_) set_header_no_override("Access-Control-Allow-Credentials", "true", res);
}
bool ignore_ = false;
// TODO: support multiple origins that are dynamically selected
std::string origin_ = "*";
std::string methods_ = "*";
std::string headers_ = "*";
std::string max_age_;
bool allow_credentials_ = false;
CORSHandler* handler_;
};
/// CORSHandler is a global middleware for setting CORS headers.
///
/// By default, it sets Access-Control-Allow-Origin/Methods/Headers to "*".
/// The default behaviour can be changed with the `global()` cors rule.
/// Additional rules for prexies can be added with `prefix()`.
struct CORSHandler
{
struct context
{};
void before_handle(crow::request& /*req*/, crow::response& /*res*/, context& /*ctx*/)
{}
void after_handle(crow::request& req, crow::response& res, context& /*ctx*/)
{
auto& rule = find_rule(req.url);
rule.apply(res);
}
/// Handle CORS on a specific prefix path
CORSRules& prefix(const std::string& prefix)
{
rules.emplace_back(prefix, CORSRules(this));
return rules.back().second;
}
/// Handle CORS for a specific blueprint
CORSRules& blueprint(const Blueprint& bp)
{
rules.emplace_back(bp.prefix(), CORSRules(this));
return rules.back().second;
}
/// Get the global CORS policy
CORSRules& global()
{
return default_;
}
private:
CORSRules& find_rule(const std::string& path)
{
// TODO: use a trie in case of many rules
for (auto& rule : rules)
{
// Check if path starts with a rules prefix
if (path.rfind(rule.first, 0) == 0)
{
return rule.second;
}
}
return default_;
}
std::vector<std::pair<std::string, CORSRules>> rules;
CORSRules default_ = CORSRules(this);
};
inline CORSRules& CORSRules::prefix(const std::string& prefix)
{
return handler_->prefix(prefix);
}
inline CORSRules& CORSRules::blueprint(const Blueprint& bp)
{
return handler_->blueprint(bp);
}
inline CORSRules& CORSRules::global()
{
return handler_->global();
}
} // namespace crow
#ifdef CROW_ENABLE_COMPRESSION
#pragma once
#include <string>
#include <zlib.h>
// http://zlib.net/manual.html
namespace crow
{
namespace compression
{
// Values used in the 'windowBits' parameter for deflateInit2.
enum algorithm
{
// 15 is the default value for deflate
DEFLATE = 15,
// windowBits can also be greater than 15 for optional gzip encoding.
// Add 16 to windowBits to write a simple gzip header and trailer around the compressed data instead of a zlib wrapper.
GZIP = 15 | 16,
};
inline std::string compress_string(std::string const& str, algorithm algo)
{
std::string compressed_str;
z_stream stream{};
// Initialize with the default values
if (::deflateInit2(&stream, Z_DEFAULT_COMPRESSION, Z_DEFLATED, algo, 8, Z_DEFAULT_STRATEGY) == Z_OK)
{
char buffer[8192];
stream.avail_in = str.size();
// zlib does not take a const pointer. The data is not altered.
stream.next_in = const_cast<Bytef*>(reinterpret_cast<const Bytef*>(str.c_str()));
int code = Z_OK;
do
{
stream.avail_out = sizeof(buffer);
stream.next_out = reinterpret_cast<Bytef*>(&buffer[0]);
code = ::deflate(&stream, Z_FINISH);
// Successful and non-fatal error code returned by deflate when used with Z_FINISH flush
if (code == Z_OK || code == Z_STREAM_END)
{
std::copy(&buffer[0], &buffer[sizeof(buffer) - stream.avail_out], std::back_inserter(compressed_str));
}
} while (code == Z_OK);
if (code != Z_STREAM_END)
compressed_str.clear();
::deflateEnd(&stream);
}
return compressed_str;
}
inline std::string decompress_string(std::string const& deflated_string)
{
std::string inflated_string;
Bytef tmp[8192];
z_stream zstream{};
zstream.avail_in = deflated_string.size();
// Nasty const_cast but zlib won't alter its contents
zstream.next_in = const_cast<Bytef*>(reinterpret_cast<Bytef const*>(deflated_string.c_str()));
// Initialize with automatic header detection, for gzip support
if (::inflateInit2(&zstream, MAX_WBITS | 32) == Z_OK)
{
do
{
zstream.avail_out = sizeof(tmp);
zstream.next_out = &tmp[0];
auto ret = ::inflate(&zstream, Z_NO_FLUSH);
if (ret == Z_OK || ret == Z_STREAM_END)
{
std::copy(&tmp[0], &tmp[sizeof(tmp) - zstream.avail_out], std::back_inserter(inflated_string));
}
else
{
// Something went wrong with inflate; make sure we return an empty string
inflated_string.clear();
break;
}
} while (zstream.avail_out == 0);
// Free zlib's internal memory
::inflateEnd(&zstream);
}
return inflated_string;
}
} // namespace compression
} // namespace crow
#endif
#pragma once
#include <boost/asio.hpp>
#include <boost/algorithm/string/predicate.hpp>
#include <boost/lexical_cast.hpp>
#include <boost/array.hpp>
#include <atomic>
#include <chrono>
#include <vector>
namespace crow
{
using namespace boost;
using tcp = asio::ip::tcp;
#ifdef CROW_ENABLE_DEBUG
static std::atomic<int> connectionCount;
#endif
/// An HTTP connection.
template<typename Adaptor, typename Handler, typename... Middlewares>
class Connection
{
friend struct crow::response;
public:
Connection(
boost::asio::io_service& io_service,
Handler* handler,
const std::string& server_name,
std::tuple<Middlewares...>* middlewares,
std::function<std::string()>& get_cached_date_str_f,
detail::task_timer& task_timer,
typename Adaptor::context* adaptor_ctx_,
std::atomic<unsigned int>& queue_length):
adaptor_(io_service, adaptor_ctx_),
handler_(handler),
parser_(this),
server_name_(server_name),
middlewares_(middlewares),
get_cached_date_str(get_cached_date_str_f),
task_timer_(task_timer),
res_stream_threshold_(handler->stream_threshold()),
queue_length_(queue_length)
{
#ifdef CROW_ENABLE_DEBUG
connectionCount++;
CROW_LOG_DEBUG << "Connection (" << this << ") allocated, total: " << connectionCount;
#endif
}
~Connection()
{
res.complete_request_handler_ = nullptr;
cancel_deadline_timer();
#ifdef CROW_ENABLE_DEBUG
connectionCount--;
CROW_LOG_DEBUG << "Connection (" << this << ") freed, total: " << connectionCount;
#endif
}
/// The TCP socket on top of which the connection is established.
decltype(std::declval<Adaptor>().raw_socket())& socket()
{
return adaptor_.raw_socket();
}
void start()
{
adaptor_.start([this](const boost::system::error_code& ec) {
if (!ec)
{
start_deadline();
parser_.clear();
do_read();
}
else
{
CROW_LOG_ERROR << "Could not start adaptor: " << ec.message();
check_destroy();
}
});
}
void handle_header()
{
// HTTP 1.1 Expect: 100-continue
if (parser_.http_major == 1 && parser_.http_minor == 1 && get_header_value(parser_.headers, "expect") == "100-continue") // Using the parser because the request isn't made yet.
{
buffers_.clear();
static std::string expect_100_continue = "HTTP/1.1 100 Continue\r\n\r\n";
buffers_.emplace_back(expect_100_continue.data(), expect_100_continue.size());
do_write();
}
}
void handle()
{
cancel_deadline_timer();
bool is_invalid_request = false;
add_keep_alive_ = false;
req_ = std::move(parser_.to_request());
request& req = req_;
req.remote_ip_address = adaptor_.remote_endpoint().address().to_string();
add_keep_alive_ = req.keep_alive;
close_connection_ = req.close_connection;
if (req.check_version(1, 1)) // HTTP/1.1
{
if (!req.headers.count("host"))
{
is_invalid_request = true;
res = response(400);
}
else if (req.upgrade)
{
// h2 or h2c headers
if (req.get_header_value("upgrade").substr(0, 2) == "h2")
{
// TODO(ipkn): HTTP/2
// currently, ignore upgrade header
}
else
{
close_connection_ = true;
handler_->handle_upgrade(req, res, std::move(adaptor_));
return;
}
}
}
CROW_LOG_INFO << "Request: " << boost::lexical_cast<std::string>(adaptor_.remote_endpoint()) << " " << this << " HTTP/" << (char)(req.http_ver_major + '0') << "." << (char)(req.http_ver_minor + '0') << ' ' << method_name(req.method) << " " << req.url;
need_to_call_after_handlers_ = false;
if (!is_invalid_request)
{
res.complete_request_handler_ = [] {};
res.is_alive_helper_ = [this]() -> bool {
return adaptor_.is_open();
};
ctx_ = detail::context<Middlewares...>();
req.middleware_context = static_cast<void*>(&ctx_);
req.middleware_container = static_cast<void*>(middlewares_);
req.io_service = &adaptor_.get_io_service();
detail::middleware_call_helper<detail::middleware_call_criteria_only_global,
0, decltype(ctx_), decltype(*middlewares_)>(*middlewares_, req, res, ctx_);
if (!res.completed_)
{
res.complete_request_handler_ = [this] {
this->complete_request();
};
need_to_call_after_handlers_ = true;
handler_->handle(req, res);
if (add_keep_alive_)
res.set_header("connection", "Keep-Alive");
}
else
{
complete_request();
}
}
else
{
complete_request();
}
}
/// Call the after handle middleware and send the write the response to the connection.
void complete_request()
{
CROW_LOG_INFO << "Response: " << this << ' ' << req_.raw_url << ' ' << res.code << ' ' << close_connection_;
if (need_to_call_after_handlers_)
{
need_to_call_after_handlers_ = false;
// call all after_handler of middlewares
detail::after_handlers_call_helper<
detail::middleware_call_criteria_only_global,
(static_cast<int>(sizeof...(Middlewares)) - 1),
decltype(ctx_),
decltype(*middlewares_)>(*middlewares_, ctx_, req_, res);
}
#ifdef CROW_ENABLE_COMPRESSION
if (handler_->compression_used())
{
std::string accept_encoding = req_.get_header_value("Accept-Encoding");
if (!accept_encoding.empty() && res.compressed)
{
switch (handler_->compression_algorithm())
{
case compression::DEFLATE:
if (accept_encoding.find("deflate") != std::string::npos)
{
res.body = compression::compress_string(res.body, compression::algorithm::DEFLATE);
res.set_header("Content-Encoding", "deflate");
}
break;
case compression::GZIP:
if (accept_encoding.find("gzip") != std::string::npos)
{
res.body = compression::compress_string(res.body, compression::algorithm::GZIP);
res.set_header("Content-Encoding", "gzip");
}
break;
default:
break;
}
}
}
#endif
//if there is a redirection with a partial URL, treat the URL as a route.
std::string location = res.get_header_value("Location");
if (!location.empty() && location.find("://", 0) == std::string::npos)
{
#ifdef CROW_ENABLE_SSL
if (handler_->ssl_used())
location.insert(0, "https://" + req_.get_header_value("Host"));
else
#endif
location.insert(0, "http://" + req_.get_header_value("Host"));
res.set_header("location", location);
}
prepare_buffers();
if (res.is_static_type())
{
do_write_static();
}
else
{
do_write_general();
}
}
private:
void prepare_buffers()
{
//auto self = this->shared_from_this();
res.complete_request_handler_ = nullptr;
if (!adaptor_.is_open())
{
//CROW_LOG_DEBUG << this << " delete (socket is closed) " << is_reading << ' ' << is_writing;
//delete this;
return;
}
// TODO(EDev): HTTP version in status codes should be dynamic
// Keep in sync with common.h/status
static std::unordered_map<int, std::string> statusCodes = {
{status::CONTINUE, "HTTP/1.1 100 Continue\r\n"},
{status::SWITCHING_PROTOCOLS, "HTTP/1.1 101 Switching Protocols\r\n"},
{status::OK, "HTTP/1.1 200 OK\r\n"},
{status::CREATED, "HTTP/1.1 201 Created\r\n"},
{status::ACCEPTED, "HTTP/1.1 202 Accepted\r\n"},
{status::NON_AUTHORITATIVE_INFORMATION, "HTTP/1.1 203 Non-Authoritative Information\r\n"},
{status::NO_CONTENT, "HTTP/1.1 204 No Content\r\n"},
{status::RESET_CONTENT, "HTTP/1.1 205 Reset Content\r\n"},
{status::PARTIAL_CONTENT, "HTTP/1.1 206 Partial Content\r\n"},
{status::MULTIPLE_CHOICES, "HTTP/1.1 300 Multiple Choices\r\n"},
{status::MOVED_PERMANENTLY, "HTTP/1.1 301 Moved Permanently\r\n"},
{status::FOUND, "HTTP/1.1 302 Found\r\n"},
{status::SEE_OTHER, "HTTP/1.1 303 See Other\r\n"},
{status::NOT_MODIFIED, "HTTP/1.1 304 Not Modified\r\n"},
{status::TEMPORARY_REDIRECT, "HTTP/1.1 307 Temporary Redirect\r\n"},
{status::PERMANENT_REDIRECT, "HTTP/1.1 308 Permanent Redirect\r\n"},
{status::BAD_REQUEST, "HTTP/1.1 400 Bad Request\r\n"},
{status::UNAUTHORIZED, "HTTP/1.1 401 Unauthorized\r\n"},
{status::FORBIDDEN, "HTTP/1.1 403 Forbidden\r\n"},
{status::NOT_FOUND, "HTTP/1.1 404 Not Found\r\n"},
{status::METHOD_NOT_ALLOWED, "HTTP/1.1 405 Method Not Allowed\r\n"},
{status::PROXY_AUTHENTICATION_REQUIRED, "HTTP/1.1 407 Proxy Authentication Required\r\n"},
{status::CONFLICT, "HTTP/1.1 409 Conflict\r\n"},
{status::GONE, "HTTP/1.1 410 Gone\r\n"},
{status::PAYLOAD_TOO_LARGE, "HTTP/1.1 413 Payload Too Large\r\n"},
{status::UNSUPPORTED_MEDIA_TYPE, "HTTP/1.1 415 Unsupported Media Type\r\n"},
{status::RANGE_NOT_SATISFIABLE, "HTTP/1.1 416 Range Not Satisfiable\r\n"},
{status::EXPECTATION_FAILED, "HTTP/1.1 417 Expectation Failed\r\n"},
{status::PRECONDITION_REQUIRED, "HTTP/1.1 428 Precondition Required\r\n"},
{status::TOO_MANY_REQUESTS, "HTTP/1.1 429 Too Many Requests\r\n"},
{status::UNAVAILABLE_FOR_LEGAL_REASONS, "HTTP/1.1 451 Unavailable For Legal Reasons\r\n"},
{status::INTERNAL_SERVER_ERROR, "HTTP/1.1 500 Internal Server Error\r\n"},
{status::NOT_IMPLEMENTED, "HTTP/1.1 501 Not Implemented\r\n"},
{status::BAD_GATEWAY, "HTTP/1.1 502 Bad Gateway\r\n"},
{status::SERVICE_UNAVAILABLE, "HTTP/1.1 503 Service Unavailable\r\n"},
{status::GATEWAY_TIMEOUT, "HTTP/1.1 504 Gateway Timeout\r\n"},
{status::VARIANT_ALSO_NEGOTIATES, "HTTP/1.1 506 Variant Also Negotiates\r\n"},
};
static const std::string seperator = ": ";
buffers_.clear();
buffers_.reserve(4 * (res.headers.size() + 5) + 3);
if (!statusCodes.count(res.code))
res.code = 500;
{
auto& status = statusCodes.find(res.code)->second;
buffers_.emplace_back(status.data(), status.size());
}
if (res.code >= 400 && res.body.empty())
res.body = statusCodes[res.code].substr(9);
for (auto& kv : res.headers)
{
buffers_.emplace_back(kv.first.data(), kv.first.size());
buffers_.emplace_back(seperator.data(), seperator.size());
buffers_.emplace_back(kv.second.data(), kv.second.size());
buffers_.emplace_back(crlf.data(), crlf.size());
}
if (!res.manual_length_header && !res.headers.count("content-length"))
{
content_length_ = std::to_string(res.body.size());
static std::string content_length_tag = "Content-Length: ";
buffers_.emplace_back(content_length_tag.data(), content_length_tag.size());
buffers_.emplace_back(content_length_.data(), content_length_.size());
buffers_.emplace_back(crlf.data(), crlf.size());
}
if (!res.headers.count("server"))
{
static std::string server_tag = "Server: ";
buffers_.emplace_back(server_tag.data(), server_tag.size());
buffers_.emplace_back(server_name_.data(), server_name_.size());
buffers_.emplace_back(crlf.data(), crlf.size());
}
if (!res.headers.count("date"))
{
static std::string date_tag = "Date: ";
date_str_ = get_cached_date_str();
buffers_.emplace_back(date_tag.data(), date_tag.size());
buffers_.emplace_back(date_str_.data(), date_str_.size());
buffers_.emplace_back(crlf.data(), crlf.size());
}
if (add_keep_alive_)
{
static std::string keep_alive_tag = "Connection: Keep-Alive";
buffers_.emplace_back(keep_alive_tag.data(), keep_alive_tag.size());
buffers_.emplace_back(crlf.data(), crlf.size());
}
buffers_.emplace_back(crlf.data(), crlf.size());
}
void do_write_static()
{
is_writing = true;
boost::asio::write(adaptor_.socket(), buffers_);
if (res.file_info.statResult == 0)
{
std::ifstream is(res.file_info.path.c_str(), std::ios::in | std::ios::binary);
std::vector<boost::asio::const_buffer> buffers{1};
char buf[16384];
is.read(buf, sizeof(buf));
while (is.gcount() > 0)
{
buffers[0] = boost::asio::buffer(buf, is.gcount());
do_write_sync(buffers);
is.read(buf, sizeof(buf));
}
}
is_writing = false;
if (close_connection_)
{
adaptor_.shutdown_readwrite();
adaptor_.close();
CROW_LOG_DEBUG << this << " from write (static)";
check_destroy();
}
res.end();
res.clear();
buffers_.clear();
parser_.clear();
}
void do_write_general()
{
if (res.body.length() < res_stream_threshold_)
{
res_body_copy_.swap(res.body);
buffers_.emplace_back(res_body_copy_.data(), res_body_copy_.size());
do_write();
if (need_to_start_read_after_complete_)
{
need_to_start_read_after_complete_ = false;
start_deadline();
do_read();
}
}
else
{
is_writing = true;
boost::asio::write(adaptor_.socket(), buffers_); // Write the response start / headers
if (res.body.length() > 0)
{
std::string buf;
std::vector<asio::const_buffer> buffers;
while (res.body.length() > 16384)
{
//buf.reserve(16385);
buf = res.body.substr(0, 16384);
res.body = res.body.substr(16384);
buffers.clear();
buffers.push_back(boost::asio::buffer(buf));
do_write_sync(buffers);
}
// Collect whatever is left (less than 16KB) and send it down the socket
// buf.reserve(is.length());
buf = res.body;
res.body.clear();
buffers.clear();
buffers.push_back(boost::asio::buffer(buf));
do_write_sync(buffers);
}
is_writing = false;
if (close_connection_)
{
adaptor_.shutdown_readwrite();
adaptor_.close();
CROW_LOG_DEBUG << this << " from write (res_stream)";
check_destroy();
}
res.end();
res.clear();
buffers_.clear();
parser_.clear();
}
}
void do_read()
{
//auto self = this->shared_from_this();
is_reading = true;
adaptor_.socket().async_read_some(
boost::asio::buffer(buffer_),
[this](const boost::system::error_code& ec, std::size_t bytes_transferred) {
bool error_while_reading = true;
if (!ec)
{
bool ret = parser_.feed(buffer_.data(), bytes_transferred);
if (ret && adaptor_.is_open())
{
error_while_reading = false;
}
}
if (error_while_reading)
{
cancel_deadline_timer();
parser_.done();
adaptor_.shutdown_read();
adaptor_.close();
is_reading = false;
CROW_LOG_DEBUG << this << " from read(1) with description: \"" << http_errno_description(static_cast<http_errno>(parser_.http_errno)) << '\"';
check_destroy();
}
else if (close_connection_)
{
cancel_deadline_timer();
parser_.done();
is_reading = false;
check_destroy();
// adaptor will close after write
}
else if (!need_to_call_after_handlers_)
{
start_deadline();
do_read();
}
else
{
// res will be completed later by user
need_to_start_read_after_complete_ = true;
}
});
}
void do_write()
{
//auto self = this->shared_from_this();
is_writing = true;
boost::asio::async_write(
adaptor_.socket(), buffers_,
[&](const boost::system::error_code& ec, std::size_t /*bytes_transferred*/) {
is_writing = false;
res.clear();
res_body_copy_.clear();
parser_.clear();
if (!ec)
{
if (close_connection_)
{
adaptor_.shutdown_write();
adaptor_.close();
CROW_LOG_DEBUG << this << " from write(1)";
check_destroy();
}
}
else
{
CROW_LOG_DEBUG << this << " from write(2)";
check_destroy();
}
});
}
inline void do_write_sync(std::vector<asio::const_buffer>& buffers)
{
boost::asio::write(adaptor_.socket(), buffers, [&](std::error_code ec, std::size_t) {
if (!ec)
{
return false;
}
else
{
CROW_LOG_ERROR << ec << " - happened while sending buffers";
CROW_LOG_DEBUG << this << " from write (sync)(2)";
check_destroy();
return true;
}
});
}
void check_destroy()
{
CROW_LOG_DEBUG << this << " is_reading " << is_reading << " is_writing " << is_writing;
if (!is_reading && !is_writing)
{
queue_length_--;
CROW_LOG_DEBUG << this << " delete (idle) (queue length: " << queue_length_ << ')';
delete this;
}
}
void cancel_deadline_timer()
{
CROW_LOG_DEBUG << this << " timer cancelled: " << &task_timer_ << ' ' << task_id_;
task_timer_.cancel(task_id_);
}
void start_deadline(/*int timeout = 5*/)
{
cancel_deadline_timer();
task_id_ = task_timer_.schedule([this] {
if (!adaptor_.is_open())
{
return;
}
adaptor_.shutdown_readwrite();
adaptor_.close();
});
CROW_LOG_DEBUG << this << " timer added: " << &task_timer_ << ' ' << task_id_;
}
private:
Adaptor adaptor_;
Handler* handler_;
boost::array<char, 4096> buffer_;
HTTPParser<Connection> parser_;
request req_;
response res;
bool close_connection_ = false;
const std::string& server_name_;
std::vector<boost::asio::const_buffer> buffers_;
std::string content_length_;
std::string date_str_;
std::string res_body_copy_;
detail::task_timer::identifier_type task_id_;
bool is_reading{};
bool is_writing{};
bool need_to_call_after_handlers_{};
bool need_to_start_read_after_complete_{};
bool add_keep_alive_{};
std::tuple<Middlewares...>* middlewares_;
detail::context<Middlewares...> ctx_;
std::function<std::string()>& get_cached_date_str;
detail::task_timer& task_timer_;
size_t res_stream_threshold_;
std::atomic<unsigned int>& queue_length_;
};
} // namespace crow
#pragma once
#include <chrono>
#include <boost/date_time/posix_time/posix_time.hpp>
#include <boost/asio.hpp>
#ifdef CROW_ENABLE_SSL
#include <boost/asio/ssl.hpp>
#endif
#include <cstdint>
#include <atomic>
#include <future>
#include <vector>
#include <memory>
namespace crow
{
using namespace boost;
using tcp = asio::ip::tcp;
template<typename Handler, typename Adaptor = SocketAdaptor, typename... Middlewares>
class Server
{
public:
Server(Handler* handler, std::string bindaddr, uint16_t port, std::string server_name = std::string("Crow/") + VERSION, std::tuple<Middlewares...>* middlewares = nullptr, uint16_t concurrency = 1, uint8_t timeout = 5, typename Adaptor::context* adaptor_ctx = nullptr):
acceptor_(io_service_, tcp::endpoint(boost::asio::ip::address::from_string(bindaddr), port)),
signals_(io_service_),
tick_timer_(io_service_),
handler_(handler),
concurrency_(concurrency),
timeout_(timeout),
server_name_(server_name),
port_(port),
bindaddr_(bindaddr),
task_queue_length_pool_(concurrency_ - 1),
middlewares_(middlewares),
adaptor_ctx_(adaptor_ctx)
{}
void set_tick_function(std::chrono::milliseconds d, std::function<void()> f)
{
tick_interval_ = d;
tick_function_ = f;
}
void on_tick()
{
tick_function_();
tick_timer_.expires_from_now(boost::posix_time::milliseconds(tick_interval_.count()));
tick_timer_.async_wait([this](const boost::system::error_code& ec) {
if (ec)
return;
on_tick();
});
}
void run()
{
uint16_t worker_thread_count = concurrency_ - 1;
for (int i = 0; i < worker_thread_count; i++)
io_service_pool_.emplace_back(new boost::asio::io_service());
get_cached_date_str_pool_.resize(worker_thread_count);
task_timer_pool_.resize(worker_thread_count);
std::vector<std::future<void>> v;
std::atomic<int> init_count(0);
for (uint16_t i = 0; i < worker_thread_count; i++)
v.push_back(
std::async(
std::launch::async, [this, i, &init_count] {
// thread local date string get function
auto last = std::chrono::steady_clock::now();
std::string date_str;
auto update_date_str = [&] {
auto last_time_t = time(0);
tm my_tm;
#if defined(_MSC_VER) || defined(__MINGW32__)
gmtime_s(&my_tm, &last_time_t);
#else
gmtime_r(&last_time_t, &my_tm);
#endif
date_str.resize(100);
size_t date_str_sz = strftime(&date_str[0], 99, "%a, %d %b %Y %H:%M:%S GMT", &my_tm);
date_str.resize(date_str_sz);
};
update_date_str();
get_cached_date_str_pool_[i] = [&]() -> std::string {
if (std::chrono::steady_clock::now() - last >= std::chrono::seconds(1))
{
last = std::chrono::steady_clock::now();
update_date_str();
}
return date_str;
};
// initializing task timers
detail::task_timer task_timer(*io_service_pool_[i]);
task_timer.set_default_timeout(timeout_);
task_timer_pool_[i] = &task_timer;
task_queue_length_pool_[i] = 0;
init_count++;
while (1)
{
try
{
if (io_service_pool_[i]->run() == 0)
{
// when io_service.run returns 0, there are no more works to do.
break;
}
}
catch (std::exception& e)
{
CROW_LOG_ERROR << "Worker Crash: An uncaught exception occurred: " << e.what();
}
}
}));
if (tick_function_ && tick_interval_.count() > 0)
{
tick_timer_.expires_from_now(boost::posix_time::milliseconds(tick_interval_.count()));
tick_timer_.async_wait(
[this](const boost::system::error_code& ec) {
if (ec)
return;
on_tick();
});
}
port_ = acceptor_.local_endpoint().port();
handler_->port(port_);
CROW_LOG_INFO << server_name_ << " server is running at " << (handler_->ssl_used() ? "https://" : "http://") << bindaddr_ << ":" << acceptor_.local_endpoint().port() << " using " << concurrency_ << " threads";
CROW_LOG_INFO << "Call `app.loglevel(crow::LogLevel::Warning)` to hide Info level logs.";
signals_.async_wait(
[&](const boost::system::error_code& /*error*/, int /*signal_number*/) {
stop();
});
while (worker_thread_count != init_count)
std::this_thread::yield();
do_accept();
std::thread(
[this] {
io_service_.run();
CROW_LOG_INFO << "Exiting.";
})
.join();
}
void stop()
{
io_service_.stop();
for (auto& io_service : io_service_pool_)
io_service->stop();
}
void signal_clear()
{
signals_.clear();
}
void signal_add(int signal_number)
{
signals_.add(signal_number);
}
private:
uint16_t pick_io_service_idx()
{
uint16_t min_queue_idx = 0;
// TODO improve load balancing
for (uint16_t i = 1; i < task_queue_length_pool_.size() && task_queue_length_pool_[min_queue_idx] > 0; i++)
// No need to check other io_services if the current one has no tasks
{
if (task_queue_length_pool_[i] < task_queue_length_pool_[min_queue_idx])
min_queue_idx = i;
}
return min_queue_idx;
}
void do_accept()
{
uint16_t service_idx = pick_io_service_idx();
asio::io_service& is = *io_service_pool_[service_idx];
task_queue_length_pool_[service_idx]++;
CROW_LOG_DEBUG << &is << " {" << service_idx << "} queue length: " << task_queue_length_pool_[service_idx];
auto p = new Connection<Adaptor, Handler, Middlewares...>(
is, handler_, server_name_, middlewares_,
get_cached_date_str_pool_[service_idx], *task_timer_pool_[service_idx], adaptor_ctx_, task_queue_length_pool_[service_idx]);
acceptor_.async_accept(
p->socket(),
[this, p, &is, service_idx](boost::system::error_code ec) {
if (!ec)
{
is.post(
[p] {
p->start();
});
}
else
{
task_queue_length_pool_[service_idx]--;
CROW_LOG_DEBUG << &is << " {" << service_idx << "} queue length: " << task_queue_length_pool_[service_idx];
delete p;
}
do_accept();
});
}
private:
asio::io_service io_service_;
std::vector<std::unique_ptr<asio::io_service>> io_service_pool_;
std::vector<detail::task_timer*> task_timer_pool_;
std::vector<std::function<std::string()>> get_cached_date_str_pool_;
tcp::acceptor acceptor_;
boost::asio::signal_set signals_;
boost::asio::deadline_timer tick_timer_;
Handler* handler_;
uint16_t concurrency_{2};
std::uint8_t timeout_;
std::string server_name_;
uint16_t port_;
std::string bindaddr_;
std::vector<std::atomic<unsigned int>> task_queue_length_pool_;
std::chrono::milliseconds tick_interval_;
std::function<void()> tick_function_;
std::tuple<Middlewares...>* middlewares_;
typename Adaptor::context* adaptor_ctx_;
};
} // namespace crow
#pragma once
#include <chrono>
#include <string>
#include <functional>
#include <memory>
#include <future>
#include <cstdint>
#include <type_traits>
#include <thread>
#include <condition_variable>
#ifdef CROW_ENABLE_COMPRESSION
#endif
#ifdef CROW_MSVC_WORKAROUND
#define CROW_ROUTE(app, url) app.route_dynamic(url)
#define CROW_BP_ROUTE(blueprint, url) blueprint.new_rule_dynamic(url)
#else
#define CROW_ROUTE(app, url) app.route<crow::black_magic::get_parameter_tag(url)>(url)
#define CROW_BP_ROUTE(blueprint, url) blueprint.new_rule_tagged<crow::black_magic::get_parameter_tag(url)>(url)
#define CROW_MIDDLEWARES(app, ...) middlewares<std::remove_reference<decltype(app)>::type, __VA_ARGS__>()
#endif
#define CROW_CATCHALL_ROUTE(app) app.catchall_route()
#define CROW_BP_CATCHALL_ROUTE(blueprint) blueprint.catchall_rule()
namespace crow
{
#ifdef CROW_ENABLE_SSL
using ssl_context_t = boost::asio::ssl::context;
#endif
/// The main server application
///
/// Use `SimpleApp` or `App<Middleware1, Middleware2, etc...>`
template<typename... Middlewares>
class Crow
{
public:
/// This crow application
using self_t = Crow;
/// The HTTP server
using server_t = Server<Crow, SocketAdaptor, Middlewares...>;
#ifdef CROW_ENABLE_SSL
/// An HTTP server that runs on SSL with an SSLAdaptor
using ssl_server_t = Server<Crow, SSLAdaptor, Middlewares...>;
#endif
Crow()
{}
/// Process an Upgrade request
///
/// Currently used to upgrade an HTTP connection to a WebSocket connection
template<typename Adaptor>
void handle_upgrade(const request& req, response& res, Adaptor&& adaptor)
{
router_.handle_upgrade(req, res, adaptor);
}
/// Process the request and generate a response for it
void handle(request& req, response& res)
{
router_.handle(req, res);
}
/// Create a dynamic route using a rule (**Use CROW_ROUTE instead**)
DynamicRule& route_dynamic(std::string&& rule)
{
return router_.new_rule_dynamic(std::move(rule));
}
///Create a route using a rule (**Use CROW_ROUTE instead**)
template<uint64_t Tag>
#ifdef CROW_GCC83_WORKAROUND
auto& route(std::string&& rule)
#else
auto route(std::string&& rule)
#endif
#if defined CROW_CAN_USE_CPP17 && !defined CROW_GCC83_WORKAROUND
-> typename std::invoke_result<decltype(&Router::new_rule_tagged<Tag>), Router, std::string&&>::type
#elif !defined CROW_GCC83_WORKAROUND
-> typename std::result_of<decltype (&Router::new_rule_tagged<Tag>)(Router, std::string&&)>::type
#endif
{
return router_.new_rule_tagged<Tag>(std::move(rule));
}
/// Create a route for any requests without a proper route (**Use CROW_CATCHALL_ROUTE instead**)
CatchallRule& catchall_route()
{
return router_.catchall_rule();
}
self_t& signal_clear()
{
signals_.clear();
return *this;
}
self_t& signal_add(int signal_number)
{
signals_.push_back(signal_number);
return *this;
}
/// Set the port that Crow will handle requests on
self_t& port(std::uint16_t port)
{
port_ = port;
return *this;
}
/// Get the port that Crow will handle requests on
std::uint16_t port()
{
return port_;
}
/// Set the connection timeout in seconds (default is 5)
self_t& timeout(std::uint8_t timeout)
{
timeout_ = timeout;
return *this;
}
/// Set the server name
self_t& server_name(std::string server_name)
{
server_name_ = server_name;
return *this;
}
/// The IP address that Crow will handle requests on (default is 0.0.0.0)
self_t& bindaddr(std::string bindaddr)
{
bindaddr_ = bindaddr;
return *this;
}
/// Run the server on multiple threads using all available threads
self_t& multithreaded()
{
return concurrency(std::thread::hardware_concurrency());
}
/// Run the server on multiple threads using a specific number
self_t& concurrency(std::uint16_t concurrency)
{
if (concurrency < 2) // Crow can have a minimum of 2 threads running
concurrency = 2;
concurrency_ = concurrency;
return *this;
}
/// Set the server's log level
///
/// Possible values are:<br>
/// crow::LogLevel::Debug (0)<br>
/// crow::LogLevel::Info (1)<br>
/// crow::LogLevel::Warning (2)<br>
/// crow::LogLevel::Error (3)<br>
/// crow::LogLevel::Critical (4)<br>
self_t& loglevel(LogLevel level)
{
crow::logger::setLogLevel(level);
return *this;
}
/// Set the response body size (in bytes) beyond which Crow automatically streams responses (Default is 1MiB)
///
/// Any streamed response is unaffected by Crow's timer, and therefore won't timeout before a response is fully sent.
self_t& stream_threshold(size_t threshold)
{
res_stream_threshold_ = threshold;
return *this;
}
/// Get the response body size (in bytes) beyond which Crow automatically streams responses
size_t& stream_threshold()
{
return res_stream_threshold_;
}
self_t& register_blueprint(Blueprint& blueprint)
{
router_.register_blueprint(blueprint);
return *this;
}
/// Set a custom duration and function to run on every tick
template<typename Duration, typename Func>
self_t& tick(Duration d, Func f)
{
tick_interval_ = std::chrono::duration_cast<std::chrono::milliseconds>(d);
tick_function_ = f;
return *this;
}
#ifdef CROW_ENABLE_COMPRESSION
self_t& use_compression(compression::algorithm algorithm)
{
comp_algorithm_ = algorithm;
compression_used_ = true;
return *this;
}
compression::algorithm compression_algorithm()
{
return comp_algorithm_;
}
bool compression_used() const
{
return compression_used_;
}
#endif
/// A wrapper for `validate()` in the router
///
/// Go through the rules, upgrade them if possible, and add them to the list of rules
void validate()
{
if (!validated_)
{
#ifndef CROW_DISABLE_STATIC_DIR
route<crow::black_magic::get_parameter_tag(CROW_STATIC_ENDPOINT)>(CROW_STATIC_ENDPOINT)([](crow::response& res, std::string file_path_partial) {
utility::sanitize_filename(file_path_partial);
res.set_static_file_info_unsafe(CROW_STATIC_DIRECTORY + file_path_partial);
res.end();
});
#if defined(__APPLE__) || defined(__MACH__)
if (!router_.blueprints().empty())
#endif
{
for (Blueprint* bp : router_.blueprints())
{
if (!bp->static_dir().empty())
{
bp->new_rule_tagged<crow::black_magic::get_parameter_tag(CROW_STATIC_ENDPOINT)>(CROW_STATIC_ENDPOINT)([bp](crow::response& res, std::string file_path_partial) {
utility::sanitize_filename(file_path_partial);
res.set_static_file_info_unsafe(bp->static_dir() + '/' + file_path_partial);
res.end();
});
}
}
}
#endif
router_.validate();
validated_ = true;
}
}
/// Notify anything using `wait_for_server_start()` to proceed
void notify_server_start()
{
std::unique_lock<std::mutex> lock(start_mutex_);
server_started_ = true;
cv_started_.notify_all();
}
/// Run the server
void run()
{
validate();
#ifdef CROW_ENABLE_SSL
if (ssl_used_)
{
ssl_server_ = std::move(std::unique_ptr<ssl_server_t>(new ssl_server_t(this, bindaddr_, port_, server_name_, &middlewares_, concurrency_, timeout_, &ssl_context_)));
ssl_server_->set_tick_function(tick_interval_, tick_function_);
ssl_server_->signal_clear();
for (auto snum : signals_)
{
ssl_server_->signal_add(snum);
}
notify_server_start();
ssl_server_->run();
}
else
#endif
{
server_ = std::move(std::unique_ptr<server_t>(new server_t(this, bindaddr_, port_, server_name_, &middlewares_, concurrency_, timeout_, nullptr)));
server_->set_tick_function(tick_interval_, tick_function_);
server_->signal_clear();
for (auto snum : signals_)
{
server_->signal_add(snum);
}
notify_server_start();
server_->run();
}
}
/// Non-blocking version of \ref run()
std::future<void> run_async()
{
return std::async(std::launch::async, [&] {
this->run();
});
}
/// Stop the server
void stop()
{
#ifdef CROW_ENABLE_SSL
if (ssl_used_)
{
if (ssl_server_) { ssl_server_->stop(); }
}
else
#endif
{
if (server_) { server_->stop(); }
}
}
/// Print the routing paths defined for each HTTP method
void debug_print()
{
CROW_LOG_DEBUG << "Routing:";
router_.debug_print();
}
#ifdef CROW_ENABLE_SSL
/// Use certificate and key files for SSL
self_t& ssl_file(const std::string& crt_filename, const std::string& key_filename)
{
ssl_used_ = true;
ssl_context_.set_verify_mode(boost::asio::ssl::verify_peer);
ssl_context_.set_verify_mode(boost::asio::ssl::verify_client_once);
ssl_context_.use_certificate_file(crt_filename, ssl_context_t::pem);
ssl_context_.use_private_key_file(key_filename, ssl_context_t::pem);
ssl_context_.set_options(
boost::asio::ssl::context::default_workarounds | boost::asio::ssl::context::no_sslv2 | boost::asio::ssl::context::no_sslv3);
return *this;
}
/// Use .pem file for SSL
self_t& ssl_file(const std::string& pem_filename)
{
ssl_used_ = true;
ssl_context_.set_verify_mode(boost::asio::ssl::verify_peer);
ssl_context_.set_verify_mode(boost::asio::ssl::verify_client_once);
ssl_context_.load_verify_file(pem_filename);
ssl_context_.set_options(
boost::asio::ssl::context::default_workarounds | boost::asio::ssl::context::no_sslv2 | boost::asio::ssl::context::no_sslv3);
return *this;
}
/// Use certificate chain and key files for SSL
self_t& ssl_chainfile(const std::string& crt_filename, const std::string& key_filename)
{
ssl_used_ = true;
ssl_context_.set_verify_mode(boost::asio::ssl::verify_peer);
ssl_context_.set_verify_mode(boost::asio::ssl::verify_client_once);
ssl_context_.use_certificate_chain_file(crt_filename);
ssl_context_.use_private_key_file(key_filename, ssl_context_t::pem);
ssl_context_.set_options(
boost::asio::ssl::context::default_workarounds | boost::asio::ssl::context::no_sslv2 | boost::asio::ssl::context::no_sslv3);
return *this;
}
self_t& ssl(boost::asio::ssl::context&& ctx)
{
ssl_used_ = true;
ssl_context_ = std::move(ctx);
return *this;
}
bool ssl_used() const
{
return ssl_used_;
}
#else
template<typename T, typename... Remain>
self_t& ssl_file(T&&, Remain&&...)
{
// We can't call .ssl() member function unless CROW_ENABLE_SSL is defined.
static_assert(
// make static_assert dependent to T; always false
std::is_base_of<T, void>::value,
"Define CROW_ENABLE_SSL to enable ssl support.");
return *this;
}
template<typename T, typename... Remain>
self_t& ssl_chainfile(T&&, Remain&&...)
{
// We can't call .ssl() member function unless CROW_ENABLE_SSL is defined.
static_assert(
// make static_assert dependent to T; always false
std::is_base_of<T, void>::value,
"Define CROW_ENABLE_SSL to enable ssl support.");
return *this;
}
template<typename T>
self_t& ssl(T&&)
{
// We can't call .ssl() member function unless CROW_ENABLE_SSL is defined.
static_assert(
// make static_assert dependent to T; always false
std::is_base_of<T, void>::value,
"Define CROW_ENABLE_SSL to enable ssl support.");
return *this;
}
bool ssl_used() const
{
return false;
}
#endif
// middleware
using context_t = detail::context<Middlewares...>;
using mw_container_t = std::tuple<Middlewares...>;
template<typename T>
typename T::context& get_context(const request& req)
{
static_assert(black_magic::contains<T, Middlewares...>::value, "App doesn't have the specified middleware type.");
auto& ctx = *reinterpret_cast<context_t*>(req.middleware_context);
return ctx.template get<T>();
}
template<typename T>
T& get_middleware()
{
return utility::get_element_by_type<T, Middlewares...>(middlewares_);
}
/// Wait until the server has properly started
void wait_for_server_start()
{
std::unique_lock<std::mutex> lock(start_mutex_);
if (server_started_)
return;
cv_started_.wait(lock);
}
private:
std::uint8_t timeout_{5};
uint16_t port_ = 80;
uint16_t concurrency_ = 2;
bool validated_ = false;
std::string server_name_ = std::string("Crow/") + VERSION;
std::string bindaddr_ = "0.0.0.0";
size_t res_stream_threshold_ = 1048576;
Router router_;
#ifdef CROW_ENABLE_COMPRESSION
compression::algorithm comp_algorithm_;
bool compression_used_{false};
#endif
std::chrono::milliseconds tick_interval_;
std::function<void()> tick_function_;
std::tuple<Middlewares...> middlewares_;
#ifdef CROW_ENABLE_SSL
std::unique_ptr<ssl_server_t> ssl_server_;
bool ssl_used_{false};
ssl_context_t ssl_context_{boost::asio::ssl::context::sslv23};
#endif
std::unique_ptr<server_t> server_;
std::vector<int> signals_{SIGINT, SIGTERM};
bool server_started_{false};
std::condition_variable cv_started_;
std::mutex start_mutex_;
};
template<typename... Middlewares>
using App = Crow<Middlewares...>;
using SimpleApp = Crow<>;
} // namespace crow
#pragma once
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