我想将两个(或更多)流组合成一个。我的目标是,定向到cout
,cerr
和clog
的任何输出也会与原始流一起输出到文件中。 (例如,当事情记录到控制台时。关闭后,我仍然希望能够返回并查看输出。)
我在考虑做这样的事情:
class stream_compose : public streambuf, private boost::noncopyable
{
public:
// take two streams, save them in stream_holder,
// this set their buffers to `this`.
stream_compose;
// implement the streambuf interface, routing to both
// ...
private:
// saves the streambuf of an ios class,
// upon destruction restores it, provides
// accessor to saved stream
class stream_holder;
stream_holder mStreamA;
stream_holder mStreamB;
};
这似乎很直截了当。然后,在main中的调用将是:
// anything that goes to cout goes to both cout and the file
stream_compose coutToFile(std::cout, theFile);
// and so on
我也看了boost::iostreams
,但没有看到任何相关内容。
还有其他更好/更简单的方法来实现这个目标吗?
答案 0 :(得分:13)
如果您想在stdlib中完全执行此操作,那么您确实拥有正确的设计。
有一件事:不是在每个输出上对每个streambuf进行切换,而是将其实现为使用与给定的streambuf相同的put区域,并在溢出和同步时复制到其他区域。这将最大限度地减少虚拟呼叫,这是streambufs如何工作的目标之一。
或者,如果你只想处理stdout& stderr(这是常见的),通过标准的Unix tee
程序(或平台上的等效程序)运行程序,或者通过在调用程序时自己执行,或者在程序中通过分叉,设置流来运行程序适当的等等。
编辑:你让我思考,我应该知道如何做到这一点。这是我的first approximation。 (当这个中断时,你可以保留两个部分。)
#ifndef INCLUDE_GUARD_A629F54A136C49C9938CB33EF8EDE676
#define INCLUDE_GUARD_A629F54A136C49C9938CB33EF8EDE676
#include <cassert>
#include <cstring>
#include <streambuf>
#include <map>
#include <vector>
template<class CharT, class Traits=std::char_traits<CharT> >
struct basic_streamtee : std::basic_streambuf<CharT, Traits> {
typedef std::basic_ios<CharT, Traits> Stream;
typedef std::basic_streambuf<CharT, Traits> StreamBuf;
typedef typename StreamBuf::char_type char_type;
typedef typename StreamBuf::traits_type traits_type;
typedef typename StreamBuf::int_type int_type;
typedef typename StreamBuf::pos_type pos_type;
typedef typename StreamBuf::off_type off_type;
basic_streamtee() : _key_buf(0) {}
basic_streamtee(Stream& a, Stream& b) : _key_buf(0) {
this->pubimbue(a.rdbuf()->getloc());
_set_key_buf(a.rdbuf());
insert(a);
insert(b);
}
~basic_streamtee() {
sync();
for (typename std::map<Stream*, StreamBuf*>::iterator i = _bufs.begin();
i != _bufs.end();
++i)
{
StreamBuf* old = i->first->rdbuf(i->second);
if (old != this) {
old->pubsync();
}
}
}
// add this functionality?
// streambufs would be unconnected with a stream
// easy to do by changing _bufs to a multimap
// and using null pointers for the keys
//void insert(StreamBuf* buf);
//void remove(StreamBuf* buf);
void insert(Stream& s) {
sync();
if (!_bufs.count(&s)) {
if (!_key_buf) {
_set_key_buf(s.rdbuf());
}
_bufs[&s] = s.rdbuf(this);
}
}
void remove(Stream& s) {
sync();
typename std::map<Stream*, StreamBuf*>::iterator i = _bufs.find(&s);
if (i != _bufs.end()) {
StreamBuf* old = i->second;
i->first->rdbuf(i->second);
_bufs.erase(i);
if (old == _key_buf) {
_set_key_buf(_bufs.empty() ? 0 : _bufs.begin()->second);
}
}
}
private:
basic_streamtee(basic_streamtee const&); // not defined
basic_streamtee& operator=(basic_streamtee const&); // not defined
StreamBuf* _key_buf;
std::map<Stream*, StreamBuf*> _bufs;
void _set_key_buf(StreamBuf* p) {
//NOTE: does not sync, requires synced already
_key_buf = p;
_update_put_area();
}
void _update_put_area() {
//NOTE: does not sync, requires synced already
if (!_key_buf) {
this->setp(0, 0);
}
else {
this->setp((_key_buf->*&basic_streamtee::pbase)(),
(_key_buf->*&basic_streamtee::epptr)());
}
}
#define FOREACH_BUF(var) \
for (typename std::map<Stream*, StreamBuf*>::iterator var = _bufs.begin(); \
var != _bufs.end(); ++var)
// 27.5.2.4.1 Locales
virtual void imbue(std::locale const& loc) {
FOREACH_BUF(iter) {
iter->second->pubimbue(loc);
}
}
// 27.5.2.4.2 Buffer management and positioning
//virtual StreamBuf* setbuf(char_type* s, std::streamsize n); // not required
//virtual pos_type seekoff(off_type off, std::ios_base::seekdir way,
// std::ios_base::openmode which); // not required
//virtual pos_type seekpos(pos_type sp, std::ios_base::openmode which); // not required
virtual int sync() {
if (!_key_buf) {
return -1;
}
char_type* data = this->pbase();
std::streamsize n = this->pptr() - data;
(_key_buf->*&basic_streamtee::pbump)(n);
FOREACH_BUF(iter) {
StreamBuf* buf = iter->second;
if (buf != _key_buf) {
buf->sputn(data, n); //BUG: ignores put errors
buf->pubsync(); //BUG: ignroes errors
}
}
_key_buf->pubsync(); //BUG: ignores errors
_update_put_area();
return 0;
}
// 27.5.2.4.3 Get area
// ignore input completely, teeing doesn't make sense
//virtual std::streamsize showmanyc();
//virtual std::streamsize xsgetn(char_type* s, std::streamsize n);
//virtual int_type underflow();
//virtual int_type uflow();
// 27.5.2.4.4 Putback
// ignore input completely, teeing doesn't make sense
//virtual int_type pbackfail(int_type c);
// 27.5.2.4.5 Put area
virtual std::streamsize xsputn(char_type const* s, std::streamsize n) {
assert(n >= 0);
if (!_key_buf) {
return 0;
}
// available room in put area? delay sync if so
if (this->epptr() - this->pptr() < n) {
sync();
}
// enough room now?
if (this->epptr() - this->pptr() >= n) {
std::memcpy(this->pptr(), s, n);
this->pbump(n);
}
else {
FOREACH_BUF(iter) {
iter->second->sputn(s, n);
//BUG: ignores put errors
}
_update_put_area();
}
return n;
}
virtual int_type overflow(int_type c) {
bool const c_is_eof = traits_type::eq_int_type(c, traits_type::eof());
int_type const success = c_is_eof ? traits_type::not_eof(c) : c;
sync();
if (!c_is_eof) {
char_type cc = traits_type::to_char_type(c);
xsputn(&cc, 1);
//BUG: ignores put errors
}
return success;
}
#undef FOREACH_BUF
};
typedef basic_streamtee<char> streamtee;
typedef basic_streamtee<wchar_t> wstreamtee;
#endif
现在,这个测试远未完成,但似乎有效:
#include "streamtee.hpp"
#include <cassert>
#include <iostream>
#include <sstream>
int main() {
using namespace std;
{
ostringstream a, b;
streamtee tee(a, b);
a << 42;
assert(a.str() == "42");
assert(b.str() == "42");
}
{
ostringstream a, b;
streamtee tee(cout, a);
tee.insert(b);
a << 42 << '\n';
assert(a.str() == "42\n");
assert(b.str() == "42\n");
}
return 0;
}
将它与文件放在一起:
#include "streamtee.hpp"
#include <iostream>
#include <fstream>
struct FileTee {
FileTee(std::ostream& stream, char const* filename)
: file(filename), buf(file, stream)
{}
std::ofstream file;
streamtee buf;
};
int main() {
using namespace std;
FileTee out(cout, "stdout.txt");
FileTee err(clog, "stderr.txt");
streambuf* old_cerr = cerr.rdbuf(&err.buf);
cout << "stdout\n";
clog << "stderr\n";
cerr.rdbuf(old_cerr);
// watch exception safety
return 0;
}
答案 1 :(得分:11)
我会写一个自定义流缓冲区,它只是将数据转发到所有链接流的缓冲区。
#include <iostream>
#include <fstream>
#include <vector>
#include <algorithm>
#include <functional>
class ComposeStream: public std::ostream
{
struct ComposeBuffer: public std::streambuf
{
void addBuffer(std::streambuf* buf)
{
bufs.push_back(buf);
}
virtual int overflow(int c)
{
std::for_each(bufs.begin(),bufs.end(),std::bind2nd(std::mem_fun(&std::streambuf::sputc),c));
return c;
}
private:
std::vector<std::streambuf*> bufs;
};
ComposeBuffer myBuffer;
public:
ComposeStream()
:std::ostream(NULL)
{
std::ostream::rdbuf(&myBuffer);
}
void linkStream(std::ostream& out)
{
out.flush();
myBuffer.addBuffer(out.rdbuf());
}
};
int main()
{
ComposeStream out;
out.linkStream(std::cout);
out << "To std::cout\n";
out.linkStream(std::clog);
out << "To: std::cout and std::clog\n";
std::ofstream file("Plop");
out.linkStream(file);
out << "To all three locations\n";
}
答案 2 :(得分:11)
你提到在Boost.IOStreams中没有找到任何东西。你考虑过tee_device吗?