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|
// file : libbuild2/diagnostics.hxx -*- C++ -*-
// license : MIT; see accompanying LICENSE file
#ifndef LIBBUILD2_DIAGNOSTICS_HXX
#define LIBBUILD2_DIAGNOSTICS_HXX
#include <libbutl/diagnostics.hxx>
#include <libbuild2/types.hxx>
#include <libbuild2/forward.hxx>
#include <libbuild2/utility.hxx>
#include <libbuild2/export.hxx>
namespace build2
{
struct diag_record;
// Throw this exception to terminate the build. The handler should
// assume that the diagnostics has already been issued.
//
class failed: public std::exception {};
// Print process commmand line. If the number of elements is specified (or
// the const cstrings& version is used), then it will print the piped multi-
// process command line, if present. In this case, the expected format is as
// follows:
//
// name1 arg arg ... nullptr
// name2 arg arg ... nullptr
// ...
// nameN arg arg ... nullptr nullptr
//
LIBBUILD2_SYMEXPORT void
print_process (diag_record&,
const char* const* args, size_t n = 0);
LIBBUILD2_SYMEXPORT void
print_process (const char* const* args, size_t n = 0);
inline void
print_process (diag_record& dr,
const cstrings& args, size_t n = 0)
{
print_process (dr, args.data (), n != 0 ? n : args.size ());
}
inline void
print_process (const cstrings& args, size_t n = 0)
{
print_process (args.data (), n != 0 ? n : args.size ());
}
// As above but with process_env.
//
LIBBUILD2_SYMEXPORT void
print_process (diag_record&,
const process_env&, const char* const* args, size_t n = 0);
LIBBUILD2_SYMEXPORT void
print_process (const process_env&, const char* const* args, size_t n = 0);
inline void
print_process (diag_record& dr,
const process_env& pe, const cstrings& args, size_t n = 0)
{
print_process (dr, pe, args.data (), n != 0 ? n : args.size ());
}
inline void
print_process (const process_env& pe, const cstrings& args, size_t n = 0)
{
print_process (pe, args.data (), n != 0 ? n : args.size ());
}
// Program verbosity level (-v/--verbose plus --silent).
//
// 0 - disabled
// 1 - high-level information messages
// 2 - essential underlying commands that are being executed
// 3 - all underlying commands that are being executed
// 4 - information helpful to the user (e.g., why a rule did not match)
// 5 - information helpful to the developer
// 6 - even more detailed information
//
// If silent is true, then the level must be 0 (silent is level 0 that
// cannot be relaxed in certain contexts).
//
// While uint8 is more than enough, use uint16 for the ease of printing.
//
// Forward-declarated in <libbuild2/utility.hxx>.
//
// const uint16_t verb_never = 7;
// extern uint16_t verb;
// extern bool silent;
template <typename F> inline void l1 (const F& f) {if (verb >= 1) f ();}
template <typename F> inline void l2 (const F& f) {if (verb >= 2) f ();}
template <typename F> inline void l3 (const F& f) {if (verb >= 3) f ();}
template <typename F> inline void l4 (const F& f) {if (verb >= 4) f ();}
template <typename F> inline void l5 (const F& f) {if (verb >= 5) f ();}
template <typename F> inline void l6 (const F& f) {if (verb >= 6) f ();}
// Stream verbosity level. Determined by the diagnostic type (e.g., trace
// always has maximum verbosity) as well as the program verbosity. It is
// used to decide whether to print relative/absolute paths and default
// target extensions.
//
// Currently we have the following program to stream verbosity mapping:
//
// fail/error/warn/info <2:{0,0} 2:{0,1} >2:{1,2}
// trace *:{1,2}
//
// A stream that hasn't been (yet) assigned any verbosity explicitly (e.g.,
// ostringstream) defaults to maximum.
//
struct stream_verbosity
{
union
{
struct
{
// 0 - print relative.
// 1 - print absolute.
//
uint16_t path: 1;
// 0 - don't print.
// 1 - print if specified.
// 2 - print as 'foo.?' if unspecified and 'foo.' if specified as
// "no extension" (empty).
//
uint16_t extension: 2;
};
uint16_t value_;
};
constexpr
stream_verbosity (uint16_t p, uint16_t e): path (p), extension (e) {}
explicit
stream_verbosity (uint16_t v = 0): value_ (v) {}
};
constexpr stream_verbosity stream_verb_max = {1, 2};
// Default program to stream verbosity mapping, as outlined above.
//
inline stream_verbosity
stream_verb_map ()
{
return
verb < 2 ? stream_verbosity (0, 0) :
verb > 2 ? stream_verbosity (1, 2) :
/* */ stream_verbosity (0, 1);
}
LIBBUILD2_SYMEXPORT extern const int stream_verb_index;
inline stream_verbosity
stream_verb (ostream& os)
{
long v (os.iword (stream_verb_index));
return v == 0
? stream_verb_max
: stream_verbosity (static_cast<uint16_t> (v - 1));
}
inline void
stream_verb (ostream& os, stream_verbosity v)
{
os.iword (stream_verb_index) = static_cast<long> (v.value_) + 1;
}
// Progress reporting.
//
using butl::diag_progress;
using butl::diag_progress_lock;
// Return true if progress is to be shown. The max_verb argument is the
// maximum verbosity level that this type of progress should be shown by
// default.
//
inline bool
show_progress (uint16_t max_verb)
{
return diag_progress_option
? *diag_progress_option
: stderr_term && verb >= 1 && verb <= max_verb;
}
// Diagnostic facility.
//
// Note that this is the "complex" case we we derive from (rather than
// alias) a number of butl::diag_* types and provide custom operator<<
// "overrides" in order to make ADL look in the build2 rather than butl
// namespace.
//
using butl::diag_stream_lock;
using butl::diag_stream;
using butl::diag_epilogue;
using butl::diag_frame;
template <typename> struct diag_prologue;
template <typename> struct diag_mark;
struct diag_record: butl::diag_record
{
template <typename T>
const diag_record&
operator<< (const T& x) const
{
os << x;
return *this;
}
diag_record () = default;
template <typename B>
explicit
diag_record (const diag_prologue<B>& p): diag_record () { *this << p;}
template <typename B>
explicit
diag_record (const diag_mark<B>& m): diag_record () { *this << m;}
};
template <typename B>
struct diag_prologue: butl::diag_prologue<B>
{
using butl::diag_prologue<B>::diag_prologue;
template <typename T>
diag_record
operator<< (const T& x) const
{
diag_record r;
r.append (this->indent, this->epilogue);
B::operator() (r);
r << x;
return r;
}
friend const diag_record&
operator<< (const diag_record& r, const diag_prologue& p)
{
r.append (p.indent, p.epilogue);
p (r);
return r;
}
};
template <typename B>
struct diag_mark: butl::diag_mark<B>
{
using butl::diag_mark<B>::diag_mark;
template <typename T>
diag_record
operator<< (const T& x) const
{
return B::operator() () << x;
}
friend const diag_record&
operator<< (const diag_record& r, const diag_mark& m)
{
return r << m ();
}
};
template <typename B>
struct diag_noreturn_end: butl::diag_noreturn_end<B>
{
diag_noreturn_end () {} // For Clang 3.7 (const needs user default ctor).
using butl::diag_noreturn_end<B>::diag_noreturn_end;
[[noreturn]] friend void
operator<< (const diag_record& r, const diag_noreturn_end& e)
{
assert (r.full ());
e.B::operator() (r);
}
};
template <typename F>
struct diag_frame_impl: diag_frame
{
explicit
diag_frame_impl (F f): diag_frame (&thunk), func_ (move (f)) {}
private:
static void
thunk (const diag_frame& f, const butl::diag_record& r)
{
static_cast<const diag_frame_impl&> (f).func_ (
static_cast<const diag_record&> (r));
}
const F func_;
};
template <typename F>
inline diag_frame_impl<F>
make_diag_frame (F f)
{
return diag_frame_impl<F> (move (f));
}
struct LIBBUILD2_SYMEXPORT simple_prologue_base
{
explicit
simple_prologue_base (const char* type,
const char* mod,
const char* name,
stream_verbosity sverb)
: type_ (type), mod_ (mod), name_ (name), sverb_ (sverb) {}
void
operator() (const diag_record& r) const;
private:
const char* type_;
const char* mod_;
const char* name_;
const stream_verbosity sverb_;
};
struct LIBBUILD2_SYMEXPORT location_prologue_base
{
location_prologue_base (const char* type,
const char* mod,
const char* name,
const location& l,
stream_verbosity sverb)
: type_ (type), mod_ (mod), name_ (name),
loc_ (l),
sverb_ (sverb) {}
location_prologue_base (const char* type,
const char* mod,
const char* name,
const path_name_view& f,
stream_verbosity sverb)
: type_ (type), mod_ (mod), name_ (name),
loc_ (f),
sverb_ (sverb) {}
location_prologue_base (const char* type,
const char* mod,
const char* name,
path&& f,
stream_verbosity sverb)
: type_ (type), mod_ (mod), name_ (name),
file_ (move (f)), loc_ (file_),
sverb_ (sverb) {}
void
operator() (const diag_record& r) const;
private:
const char* type_;
const char* mod_;
const char* name_;
const path file_;
const location loc_;
const stream_verbosity sverb_;
};
struct basic_mark_base
{
using simple_prologue = diag_prologue<simple_prologue_base>;
using location_prologue = diag_prologue<location_prologue_base>;
explicit
basic_mark_base (const char* type,
const void* data = nullptr,
diag_epilogue* epilogue = &diag_frame::apply,
stream_verbosity (*sverb) () = &stream_verb_map,
const char* mod = nullptr,
const char* name = nullptr)
: sverb_ (sverb),
type_ (type), mod_ (mod), name_ (name), data_ (data),
epilogue_ (epilogue) {}
simple_prologue
operator() () const
{
return simple_prologue (epilogue_, type_, mod_, name_, sverb_ ());
}
location_prologue
operator() (const location& l) const
{
return location_prologue (epilogue_, type_, mod_, name_, l, sverb_ ());
}
location_prologue
operator() (const location_value& l) const
{
return location_prologue (epilogue_, type_, mod_, name_, l, sverb_ ());
}
location_prologue
operator() (const path_name& f) const
{
return location_prologue (epilogue_, type_, mod_, name_, f, sverb_ ());
}
location_prologue
operator() (const path_name_view& f) const
{
return location_prologue (epilogue_, type_, mod_, name_, f, sverb_ ());
}
location_prologue
operator() (const path_name_value& f) const
{
return location_prologue (epilogue_, type_, mod_, name_, f, sverb_ ());
}
// fail (relative (src)) << ...
//
location_prologue
operator() (path&& f) const
{
return location_prologue (
epilogue_, type_, mod_, name_, move (f), sverb_ ());
}
template <typename L>
location_prologue
operator() (const L& l) const
{
return location_prologue (
epilogue_, type_, mod_, name_, get_location (l, data_), sverb_ ());
}
protected:
stream_verbosity (*sverb_) ();
const char* type_;
const char* mod_;
const char* name_;
const void* data_;
diag_epilogue* const epilogue_;
};
using basic_mark = diag_mark<basic_mark_base>;
LIBBUILD2_SYMEXPORT extern const basic_mark error;
LIBBUILD2_SYMEXPORT extern const basic_mark warn;
LIBBUILD2_SYMEXPORT extern const basic_mark info;
LIBBUILD2_SYMEXPORT extern const basic_mark text;
// trace
//
struct trace_mark_base: basic_mark_base
{
explicit
trace_mark_base (const char* name, const void* data = nullptr)
: trace_mark_base (nullptr, name, data) {}
trace_mark_base (const char* mod,
const char* name,
const void* data = nullptr)
: basic_mark_base ("trace",
data,
nullptr, // No diag stack.
[]() {return stream_verb_max;},
mod,
name) {}
};
using trace_mark = diag_mark<trace_mark_base>;
using tracer = trace_mark;
// fail
//
struct fail_mark_base: basic_mark_base
{
explicit
fail_mark_base (const char* type,
const void* data = nullptr)
: basic_mark_base (type,
data,
[](const butl::diag_record& r, butl::diag_writer* w)
{
diag_frame::apply (r);
r.flush (w);
throw failed ();
},
&stream_verb_map,
nullptr,
nullptr) {}
};
using fail_mark = diag_mark<fail_mark_base>;
struct fail_end_base
{
[[noreturn]] void
operator() (const diag_record& r) const
{
// If we just throw then the record's destructor will see an active
// exception and will not flush the record.
//
r.flush ();
throw failed ();
}
};
using fail_end = diag_noreturn_end<fail_end_base>;
LIBBUILD2_SYMEXPORT extern const fail_mark fail;
LIBBUILD2_SYMEXPORT extern const fail_end endf;
// Diagnostics buffer.
//
// The purpose of this class is to handle diagnostics from child processes,
// where handle can mean:
//
// - Buffer it (to avoid interleaving in parallel builds).
//
// - Stream it (if the input can be split into diagnostic records).
//
// - Do nothing (in serial builds or if requested not to buffer).
//
// In the future this class will also be responsible for converting the
// diagnostics into the structured form (which means it may need to buffer
// even in serial builds).
//
class LIBBUILD2_SYMEXPORT diag_buffer
{
public:
explicit
diag_buffer (context& c): is (ifdstream::badbit), ctx_ (c) {}
public:
// If buffering is necessary or force is true, open a pipe and return the
// child process end of it. Otherwise, return stderr. If mode is
// non_blocking, then make reading from the parent end of the pipe
// non-blocking.
//
// The args0 argument is the child process program name for diagnostics.
// It is expected to remain valid until the call to close() and should
// normally be the same as args[0] passed to close().
//
// The force flag is normally used if custom diagnostics processing is
// required (filter, split, etc; see read() below).
//
// Note that the same buffer can go through multiple open-read-close
// sequences, for example, to execute multiple commands.
//
// All the below functions handle io errors, issue suitable diagnostics,
// and throw failed. If an exception is thrown from any of them, then the
// instance should not be used any further.
//
// Note that when reading from multiple streams in the non-blocking mode,
// only the last stream to be destroyed can normally have the skip mode
// since in case of an exception, skipping will be blocking.
//
process::pipe
open (const char* args0,
bool force = false,
fdstream_mode mode = fdstream_mode::skip);
// Check whether the buffer has been opened with the open() call and
// hasn't yet been closed.
//
// Note that this function returning true does not mean that the pipe was
// opened (to check that, call is_open() on the stream member; see below).
//
bool
is_open () const
{
return state_ != state::closed;
}
// Read the diagnostics from the parent end of the pipe if one was opened
// and buffer/stream it as necessary or forced. Return true if there could
// be more diagnostics to read (only possible in the non-blocking mode)
// and false otherwise, in which case also close the stream.
//
// Instead of calling this function you can perform custom reading and, if
// necessary, buffering of the diagnostics by accessing the input stream
// (is) and underlying buffer (buf) directly. This can be used to filter,
// split the diagnostics into records according to a certain format, etc.
// Note that such custom processing implementation should maintain the
// overall semantics of diagnostics buffering in that it may only omit
// buffering in the serial case or if the diagnostics can be streamed in
// atomic records. See also write() below.
//
// The input stream is opened in the text mode and has the badbit but not
// failbit exception mask. The custom processing should also be compatible
// with the stream mode (blocking or non). If buffering is performed, then
// depending on the expected diagnostics the custom processing may want to
// reserve an appropriate initial buffer size to avoid unnecessary
// reallocation. As a convenience, in the blocking mode only, if the
// stream still contains some diagnostics, then it can be handled by
// calling read(). This is useful when needing to process only the inital
// part of the diagnostics. The custom processing may also close the
// stream manually before calling close().
//
bool
read (bool force = false);
// Close the parent end of the pipe if one was opened and write out any
// buffered diagnostics.
//
// If the child process exited abnormally or normally with non-0 code,
// then print the error diagnostics to this effect. Additionally, if the
// verbosity level is between 1 and the specified value, then print the
// command line as info after the error. If omit_normall is true, then
// don't print either for the normal exit (usually used when process
// failure can be tolerated).
//
// Normally the specified verbosity will be 1 and the command line args
// represent the verbosity level 2 (logical) command line. Note that args
// should only represent a single command in a pipe (see print_process()
// below for details).
//
// If the diag_buffer instance is destroyed before calling close(), then
// any buffered diagnostics is discarded.
//
// Note: see also run_finish(diag_buffer&).
//
// @@ TODO: need overload with process_env (see print_process).
//
void
close (const cstrings& args,
const process_exit& pe,
uint16_t verbosity = 1,
const location& loc = {},
bool omit_normall = false)
{
close (args.data (), pe, verbosity, loc, omit_normall);
}
void
close (const char* const* args,
const process_exit& pe,
uint16_t verbosity = 1,
const location& loc = {},
bool omit_normall = false);
// As above but with a custom diag record for the child exit diagnostics,
// if any.
//
// @@ TODO: currently cannot be used with the fail epilogue.
//
void
close (diag_record&& = {});
// Direct access to the underlying stream and buffer for custom processing
// (see read() above for details).
//
// If serial is true, then we are running serially. If nobuf is true,
// then we are running in parallel but diagnostics buffering has been
// disabled (--no-diag-buffer). Note that there is a difference: during
// the serial execution we are free to hold the diag_stream_lock for as
// long as convenient, for example, for the whole duration of child
// process execution. Doing the same during parallel execution is very
// bad idea and we should read/write the diagnostics in chunks, normally
// one line at a time.
//
public:
ifdstream is;
vector<char> buf;
const char* args0;
bool serial;
bool nobuf;
// Buffer or stream a fragment of diagnostics as necessary or forced. If
// newline is true, also add a trailing newline.
//
// This function is normally called from a custom diagnostics processing
// implementation (see read() above for details). If nobuf is true, then
// the fragment should end on the line boundary to avoid interleaving.
//
void
write (const string&, bool newline, bool force = false);
private:
// Note that we don't seem to need a custom destructor to achieve the
// desired semantics: we can assume the process has exited before we are
// destroyed (because we supply stderr to its constructor) which means
// closing fdstream without reading any futher should be ok.
//
enum class state {closed, opened, eof};
context& ctx_;
state state_ = state::closed;
};
// Action phrases, e.g., "configure update exe{foo}", "updating exe{foo}",
// and "updating exe{foo} is configured". Use like this:
//
// info << "while " << diag_doing (a, t);
//
struct diag_phrase
{
const action& a;
const target& t;
void (*f) (ostream&, const action&, const target&);
};
inline ostream&
operator<< (ostream& os, const diag_phrase& p)
{
p.f (os, p.a, p.t);
return os;
}
LIBBUILD2_SYMEXPORT string
diag_do (context&, const action&);
LIBBUILD2_SYMEXPORT void
diag_do (ostream&, const action&, const target&);
inline diag_phrase
diag_do (const action& a, const target& t)
{
return diag_phrase {a, t, &diag_do};
}
LIBBUILD2_SYMEXPORT string
diag_doing (context&, const action&);
LIBBUILD2_SYMEXPORT void
diag_doing (ostream&, const action&, const target&);
inline diag_phrase
diag_doing (const action& a, const target& t)
{
return diag_phrase {a, t, &diag_doing};
}
LIBBUILD2_SYMEXPORT string
diag_did (context&, const action&);
LIBBUILD2_SYMEXPORT void
diag_did (ostream&, const action&, const target&);
inline diag_phrase
diag_did (const action& a, const target& t)
{
return diag_phrase {a, t, &diag_did};
}
LIBBUILD2_SYMEXPORT void
diag_done (ostream&, const action&, const target&);
inline diag_phrase
diag_done (const action& a, const target& t)
{
return diag_phrase {a, t, &diag_done};
}
}
#endif // LIBBUILD2_DIAGNOSTICS_HXX
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