Here are some up-to-date albeit narrow findings of mine with GCC 4.7.2
and Clang 3.2 for C++.
UPDATE: GCC 4.8.1 v clang 3.3 comparison is down at the bottom...
I maintain an OSS tool that is built for Linux with both GCC and Clang,
and with Microsoft's compiler for Windows. The tool, coan, is a preprocessor
and analyser of C/C++ source files and codelines of such: its
computational profile majors on recursive-descent parsing and file-handling.
The development branch (to which these results pertain)
comprises at present around 11K LOC in about 90 files. It is coded,
now, in C++ that is rich in polymorphism and templates and but is still
mired in many patches by its not-so-distant past in hacked-together C.
Move semantics are not expressly exploited. It is single-threaded. I
have devoted no serious effort to optimizing it, while the "architecture"
remains so largely ToDo.
I employed Clang prior to 3.2 only as an experimental compiler
because, despite its superior compilation speed and diagnostics, its
C++11 standard support lagged the contemporary GCC version in the
respects exercised by coan. With 3.2, this gap has been closed.
My Linux test harness for current coan development processes roughly
70K sources files in a mixture of one-file parser test-cases, stress
tests consuming 1000s of files and scenario tests consuming < 1K files.
As well as reporting the test results, the harness accumulates and
displays the totals of files consumed and the runtime consumed in coan
(it just passes each coan commandline to the linux
time command and
captures and addes up the reported numbers). The timings are flattered
by the fact that any number of tests which take 0 measurable time will
all add up to 0, but the contribution of such tests is negligible. The
timing stats are displayed at the end of
make check like this:
coan_test_timer: info: Coan processed 70844 input_files.
coan_test_timer: info: runtime in coan: 16.4 secs.
coan_test_timer: info: Average processing time per input file: 0.000231 secs.
I compared the test harness performance as between GCC 4.7.2 and
Clang 3.2, all things being equal except the compilers. As of Clang 3.2,
I no longer require any preprocessor differentiation between code
tracts that GCC will compile and Clang alternatives. I built to the
same C++ library (GCC's) in each case and ran all the comparisons
consecutively in the same terminal session.
The default optimization level for my release build is -O2. I also
successfully tested builds at -O3. I tested each configuration 3
times back-to-back and averaged the 3 outcomes, with the following
results. The number in a data-cell is the average number of
microseconds consumed by the coan executable to process each of
the ~70K input files (read, parse and write output and diagnostics)
| -O2 | -O3 |O2/O3|
GCC-4.7.2 | 231 | 237 |0.97 |
Clang-3.2 | 234 | 186 |1.25 |
GCC/Clang |0.99 | 1.27|
Any particular application is very likely to have traits that play
unfairly to a compiler's strengths or weaknesses. Rigorous benchmarking
employs diverse applications. With that well in mind, the noteworthy
features of these data are:
- 1 -O3 optimization was marginally detrimental to GCC
- 2 -O3 optimization was importantly beneficial to Clang
- 3 At -O2 optimization, GCC was faster than Clang by just a whisker.
- 4 At -O3 optimization, Clang was importantly faster than GCC
A further interesting comparison of the two compilers emerged by accident
shortly after those findings. Coan liberally employes smart pointers and
one such is heavily exercised in the file handling. This particular
smart-pointer type had been typedefed in prior releases for the sake of
compiler-differentiation, to be an
std::unique_ptr<X> if the
configured compiler had sufficiently mature support for its usage as
that, and otherwise an
std::shared_ptr<X>. The bias to
foolish, since these pointers were in fact transferred around,
std::unique_ptr looked like the fitter option for replacing
std::auto_ptr at a point when the C++11 variants were novel to me.
In the course of experimental builds to gauge Clang 3.2's continued need
for this and similar differentiation, I inadvertently built
std::shared_ptr<X> when I had intended to build
and was surprised to observe that the resulting executable, with default -O2
optimization, was the fastest I had seen, sometimes achieving 184
msecs. per input file. With this one change to the source code,
the corresponding results were these;
| -O2 | -O3 |O2/O3|
GCC-4.7.2 | 234 | 234 |1.00 |
Clang-3.2 | 188 | 187 |1.00 |
GCC/Clang |1.24 |1.25 |
The points of note here are:
- 1) Neither compiler now benefits at all from -O3 optimization.
- 2) Clang beats GCC just as importantly at each level of optimization.
- 3) GCC's performance is only marginally affected by the smart-pointer type
- 4) Clang's -O2 performance is importantly affected by the smart-pointer type
Before and after the smart-pointer type change, Clang is able to build a
substantially faster coan executable at -O3 optimisation, and it can
build an equally faster executable at -O2 and -O3 when that
pointer-type is the best one -
std::shared_ptr<X> - for the job.
An obvious question that I am not competent to comment upon is why
Clang should be able to find a 25% -O2 speed-up in my application when
a heavily used smart-pointer-type is changed from unique to shared,
while GCC is indifferent to the same change. Nor do I know whether I should
cheer or boo the discovery that Clang's -O2 optimization harbours
such huge sensitivity to the wisdom of my smart-pointer choices.
UPDATE: GCC 4.8.1 v clang 3.3
The corresponding results now are:
| -O2 | -O3 |O2/O3|
GCC-4.8.1 | 442 | 443 |1.00 |
Clang-3.3 | 374 | 370 |1.01 |
GCC/Clang |1.18 |1.20 |
The fact that all four executables now take a much greater average time than previously to process
1 file does not reflect on the latest compilers' performance. It is due to the
fact that the later development branch of the test application has taken on lot of
parsing sophistication in the meantime and pays for it in speed. Only the ratios are
The points of note now are not arrestingly novel:
- GCC is indifferent to -O3 optimization
- clang benefits very marginally from -O3 optimization
- clang beats GCC by a similarly important margin at each level of optimization.
Comparing these results with those for GCC 4.7.2 and clang 3.2, it stands out that
GCC has clawed back about a quarter of clang's lead at each optimization level. But
since the test application has been heavily developed in the meantime one cannot
confidently attribute this to a catch-up in GCC's code-generation.
(This time, I have noted the application snapshot from which the timings were obtained
and can use it again.)