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// file : build2/test/script/runner.cxx -*- C++ -*-
// copyright : Copyright (c) 2014-2016 Code Synthesis Ltd
// license : MIT; see accompanying LICENSE file
#include <build2/test/script/runner>
#include <iostream> // cerr
#include <build2/filesystem>
using namespace std;
namespace build2
{
namespace test
{
namespace script
{
// Check if the file exists and is not empty.
//
static bool
non_empty (const path& p)
{
if (!exists (p))
return false;
try
{
ifdstream is (p);
return is.peek () != ifdstream::traits_type::eof ();
}
catch (const io_error& e)
{
error << "unable to read " << p << ": " << e.what ();
throw failed ();
}
}
// Check if the test command output matches the expected result (redirect
// value).
//
static void
check_output (const process_path& pr,
const char* nm,
const path& op,
const redirect& rd,
const location& cl,
scope& sp)
{
if (rd.type == redirect_type::none)
{
// Check that there is no output produced.
//
if (non_empty (op))
fail (cl) << pr << " unexpectedly writes to " << nm <<
info << nm << " is saved to " << op;
}
else if (rd.type == redirect_type::here_string ||
rd.type == redirect_type::here_document)
{
path orp (op + ".orig");
try
{
ofdstream os (orp);
sp.rm_paths.emplace_back (orp);
os << rd.value;
os.close ();
}
catch (const io_error& e)
{
fail << "unable to write " << orp << ": " << e.what ();
}
// Use diff utility to compare the output with the expected result.
//
path dp ("diff");
process_path pp (run_search (dp, true));
cstrings args {
pp.recall_string (),
"--strip-trailing-cr",
"-u",
orp.string ().c_str (),
op.string ().c_str (),
nullptr};
if (verb >= 2)
print_process (args);
try
{
// Diff utility prints the differences to stdout. But for the user
// it is a part of the test failure diagnostics so let's redirect
// stdout to stderr.
//
process p (pp, args.data (), 0, 2);
try
{
if (p.wait ())
return;
// Output doesn't match the expected result.
//
diag_record d (error (cl));
d << pr << " " << nm << " doesn't match the expected output";
auto output_info = [&d, &nm] (const path& p, const char* prefix)
{
if (non_empty (p))
d << info << prefix << nm << " is saved to " << p;
else
d << info << prefix << nm << " is empty";
};
output_info (op, "");
output_info (orp, "expected ");
// Fall through.
//
}
catch (const io_error&)
{
// Child exit status doesn't matter. Assume the child process
// issued diagnostics. Just wait for the process completion.
//
p.wait (); // Check throw.
error (cl) << "failed to compare " << nm
<< " with the expected output";
}
// Fall through.
//
}
catch (const process_error& e)
{
error (cl) << "unable to execute " << pp << ": " << e.what ();
if (e.child ())
exit (1);
}
throw failed ();
}
}
void concurrent_runner::
enter (scope& sp, const location&)
{
if (!exists (sp.wd_path))
mkdir (sp.wd_path, 2);
else if (!empty (sp.wd_path))
// @@ Shouldn't we have --wipe or smth?
//
fail << "directory " << sp.wd_path << " is not empty" <<
info << "clean it up and rerun";
sp.rm_paths.emplace_back (sp.wd_path);
}
void concurrent_runner::
leave (scope& sp, const location& cl)
{
for (const auto& p: reverse_iterate (sp.rm_paths))
{
if (p.to_directory ())
{
dir_path d (path_cast<dir_path> (p));
rmdir_status r (rmdir (d, 2));
if (r != rmdir_status::success)
fail (cl) << "registered for cleanup directory " << d
<< (r == rmdir_status::not_empty
? " not empty"
: " does not exist");
}
else if (rmfile (p, 2) == rmfile_status::not_exist)
fail (cl) << "registered for cleanup file " << p
<< " does not exist";
}
}
void concurrent_runner::
run (scope& sp, const command& c, size_t ci, const location& cl)
{
if (verb >= 3)
text << c;
// Pre-search the program path so it is reflected in the failure
// diagnostics. The user can see the original path running the test
// operation with the verbosity level > 2.
//
process_path pp (run_search (c.program, true));
cstrings args {pp.recall_string ()};
for (const auto& a: c.arguments)
args.push_back (a.c_str ());
args.push_back (nullptr);
try
{
// For stdin 'none' redirect type we somehow need to make sure that
// the child process doesn't read from stdin. That is tricky to do in
// a portable way. Here we suppose that the program which
// (erroneously) tries to read some data from stdin being redirected
// to /dev/null fails not being able to read the expected data, and
// so the test doesn't pass through.
//
// @@ Obviously doesn't cover the case when the process reads
// whatever available.
// @@ Another approach could be not to redirect stdin and let the
// process to hang which can be interpreted as a test failure.
// @@ Both ways are quite ugly. Is there some better way to do this?
//
int in;
switch (c.in.type)
{
case redirect_type::pass: in = 0; break;
case redirect_type::here_string:
case redirect_type::here_document: in = -1; break;
case redirect_type::null:
case redirect_type::none: in = -2; break;
}
// Dealing with stdout and stderr redirect types other than 'null'
// using pipes is tricky in the general case. Going this path we
// would need to read both streams in non-blocking manner which we
// can't (easily) do in a portable way. Using diff utility to get a
// nice-looking actual/expected outputs difference would complicate
// things further.
//
// So the approach is the following. Child standard streams are
// redirected to files. When the child exits and the exit status is
// validated we just sequentially compare each file content with the
// expected output. The positive side-effect of this approach is that
// the output of a faulty test command can be provided for
// troubleshooting.
//
auto opath = [sp, ci] (const char* nm) -> path
{
path r (sp.wd_path / path (nm));
if (ci > 0)
r += "-" + to_string (ci + 1); // Start from first line.
return r;
};
auto open = [&sp] (ofdstream& os, const path& p) -> int
{
try
{
os.open (p);
sp.rm_paths.emplace_back (p);
}
catch (const io_error& e)
{
fail << "unable to write " << p << ": " << e.what ();
}
return os.fd ();
};
ofdstream so;
path stdout (opath ("stdout"));
int out (c.out.type == redirect_type::pass
? 1
: c.out.type == redirect_type::null
? -2
: open (so, stdout));
ofdstream se;
path stderr (opath ("stderr"));
int err (c.err.type == redirect_type::pass
? 2
: c.err.type == redirect_type::null
? -2
: open (se, stderr));
if (verb >= 2)
print_process (args);
process pr (sp.wd_path.string ().c_str (),
pp,
args.data (),
in, out, err);
try
{
so.close ();
se.close ();
if (c.in.type == redirect_type::here_string ||
c.in.type == redirect_type::here_document)
{
ofdstream os (pr.out_fd);
os << c.in.value;
os.close ();
}
// Just wait. The program failure can mean the test success.
//
pr.wait ();
// If there is no correct exit status by whatever reason then dump
// stderr (if cached), print the proper diagnostics and fail.
//
optional<process::status_type> status (move (pr.status));
bool valid_status (status && *status >= 0 && *status < 256);
bool eq (c.exit.comparison == exit_comparison::eq);
bool correct_status (valid_status &&
(*status == c.exit.status) == eq);
if (!correct_status)
{
// Dump cached stderr.
//
if (exists (stderr))
{
try
{
ifdstream is (stderr);
if (is.peek () != ifdstream::traits_type::eof ())
cerr << is.rdbuf ();
}
catch (const io_error& e)
{
fail << "unable to read " << stderr << ": " << e.what ();
}
}
// Fail with a proper diagnostics.
//
diag_record d (fail (cl));
if (!status)
d << pp << " terminated abnormally";
else if (!valid_status)
d << pp << " exit status " << *status << " is invalid" <<
info << "must be an unsigned integer < 256";
else if (!correct_status)
d << pp << " exit status " << *status
<< (eq ? " != " : " == ")
<< static_cast<uint16_t> (c.exit.status);
else
assert (false);
if (non_empty (stdout))
d << info << "stdout is saved to " << stdout;
if (non_empty (stderr))
d << info << "stderr is saved to " << stderr;
}
// Check if the standard outputs match expectations.
//
check_output (pp, "stdout", stdout, c.out, cl, sp);
check_output (pp, "stderr", stderr, c.err, cl, sp);
}
catch (const io_error& e)
{
// Child exit status doesn't matter. Just wait for the process
// completion.
//
pr.wait (); // Check throw.
fail (cl) << "IO operation failed for " << pp << ": " << e.what ();
}
}
catch (const process_error& e)
{
error (cl) << "unable to execute " << pp << ": " << e.what ();
if (e.child ())
exit (1);
throw failed ();
}
}
}
}
}
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