Yaron Keren via llvm-dev
2015-Aug-12 05:53 UTC
[llvm-dev] SmallString + raw_svector_ostream combination should be more efficient
+llvm-dev at lists.llvm.org The impact should be small as all the other streamers usually write directly to the memory buffer and only when out of buffer they call write(). OTOH, raw_svector_ostream (without a buffer) goes though write for every character or block it writes. It can work without virtual write() by overriding the existing virtual write_impl() but this is a slower code path for raw_svector_ostream. Even though the attached raw_svector_ostream patch without virtual write() is still significantly faster then the current raw_svector_ostream since it avoids the double buffering. With this patch, on my system the example runs at 750ms compared with about 1000ms for the current raw_svector_ostream. Would you prefer to continue review on Phabricator? 2015-07-11 20:48 GMT+03:00 Rafael Espíndola <rafael.espindola at gmail.com>:> This makes write virtual. What is the impact of that on the other > streamers? > > > > On 22 May 2015 at 10:17, Yaron Keren <yaron.keren at gmail.com> wrote: > > Here's a performance testcase for the raw_svector_ostream patch. On my > > WIndows x64 machine it runs in 1010ms with the current code and in 440ms > > with the patch applies. Is this OK to commit? > > > > > > 2015-05-02 21:31 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >> > >> Following a hint from Duncan in http://llvm.org/pr23395, here is a > revised > >> patch. Rather then introduce the raw_char_ostream adapter, this version > >> improves raw_svector_ostream. > >> > >> raw_svector_ostream is now a very lightweight adapter, running without a > >> buffer and fowarding almost anything to the SmallString. This solves > both > >> the performance issue and the information duplication issue. The > SmallString > >> is always up-to-date and can be used at any time. flush() does nothing > and > >> is not required. resync() was kept in this patch as a no-op and will be > >> removed with its users in a follow-up patch. I'll also try to remove the > >> superfluous flush calls() along the way. > >> > >> > >> > >> 2015-05-02 7:41 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >>> > >>> +update diff > >>> > >>> > >>> 2015-05-02 7:38 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >>>> > >>>> I outlined (is that the right word?) raw_char_ostream::grow, > >>>> raw_char_ostream::write (both) into raw_ostream.cpp with less than 10% > >>>> difference in performance. > >>>> > >>>> Profiling reveals that the real culprit is the code line > >>>> > >>>> OS.reserve(OS.size() + 64); > >>>> > >>>> called from raw_svector_ostream::write_impl called from > >>>> raw_svector_ostream::~raw_svector_ostream. > >>>> The issue is already documented: > >>>> > >>>> raw_svector_ostream::~raw_svector_ostream() { > >>>> // FIXME: Prevent resizing during this flush(). > >>>> flush(); > >>>> } > >>>> > >>>> And a solution is provided in raw_svector_ostream::init(): > >>>> > >>>> // Set up the initial external buffer. We make sure that the buffer > >>>> has at > >>>> // least 128 bytes free; raw_ostream itself only requires 64, but we > >>>> want to > >>>> // make sure that we don't grow the buffer unnecessarily on > >>>> destruction (when > >>>> // the data is flushed). See the FIXME below. > >>>> OS.reserve(OS.size() + 128); > >>>> > >>>> This solution may be worse than the problem. In total: > >>>> > >>>> * If the SmallString was less than 128 bytes init() will always(!) > heap > >>>> allocate. > >>>> * If it's more or equal to 128 bytes but upon destruction less than 64 > >>>> bytes are left unused it will heap allocate for no reason. > >>>> > >>>> A careful programmer who did size the SmallString to match its use + > >>>> small reserve will find either of these heap allocations surprising, > >>>> negating the SmallString advantage and then paying memcpy cost. > >>>> > >>>> I filed http://llvm.org/pr23395 about this. To temporarly avoid this > >>>> issue, in addition to the outline methods change I commented the > OS.reserve > >>>> line in flush(). (This change of course requires further review.) > >>>> > >>>> With reserve being out of the way, the gap now is smaller but still > >>>> significant: raw_char_ostream is about 20% faster than > raw_svector_ostream > >>>> in Release=optimized configuration. > >>>> > >>>> > >>>> 2015-05-02 4:39 GMT+03:00 Sean Silva <chisophugis at gmail.com>: > >>>>> > >>>>> > >>>>> Could you dig into why: > >>>>> + raw_ostream &write(unsigned char C) override { > >>>>> + grow(1); > >>>>> + *OutBufCur++ = C; > >>>>> + return *this; > >>>>> + } > >>>>> > >>>>> Is 3 times as fast as raw_svector_ostream? I don't see a good reason > >>>>> why that should be any faster than: > >>>>> > >>>>> raw_ostream &operator<<(char C) { > >>>>> if (OutBufCur >= OutBufEnd) > >>>>> return write(C); > >>>>> *OutBufCur++ = C; > >>>>> return *this; > >>>>> } > >>>>> > >>>>> > >>>>> You might just be seeing the difference between having write inlined > >>>>> vs. non-inlined, in which case your patch might be a complicated way > to pull > >>>>> the likely cases of some raw_ostream methods into the header. > >>>>> > >>>>> > >>>>> -- Sean Silva > >>>> > >>>> > >>>> On Thu, Apr 30, 2015 at 8:02 PM, Yaron Keren <yaron.keren at gmail.com> > >>>> wrote: > >>>>> > >>>>> Yes, we should do without virtual flush. The problem was > >>>>> raw_char_ostream should not be flushed - it's always current - so I > >>>>> overloaded flush to a no-op. A cleaner solution is attached, adding a > >>>>> DirectBuffer mode to the raw_ostream. > >>>>> > >>>>> Also added a simple performance comparison project between > >>>>> raw_char_ostream and raw_svector_ostream. On Window 7 x64 machine, > >>>>> raw_char_ostream was three times faster than raw_svector_ostream > when the > >>>>> provided buffer size is large enough and two times as fast with one > dynamic > >>>>> allocation resize. > >>>>> > >>>>> > >>>>> 2015-04-30 22:48 GMT+03:00 Rafael Espíndola > >>>>> <rafael.espindola at gmail.com>: > >>>>>> > >>>>>> I don't think we should make flush virtual. Why do you need to do > it? > >>>>>> Can't you set up the base class to write to use the tail of the > memory > >>>>>> region as the buffer? > >>>>>> > >>>>>> > >>>>>> > >>>>>> On 24 April 2015 at 06:46, Yaron Keren <yaron.keren at gmail.com> > wrote: > >>>>>> > Hi, > >>>>>> > > >>>>>> > Is this what you're thinking about? > >>>>>> > The code is not tested yet, I'd like to know if the overall > >>>>>> > direction and > >>>>>> > design are correct. > >>>>>> > > >>>>>> > Yaron > >>>>>> > > >>>>>> > > >>>>>> > 2015-04-21 0:10 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >>>>>> >> > >>>>>> >> Sean, thanks for reminding this, Alp did commit a class derived > >>>>>> >> from > >>>>>> >> raw_svector_ostream conatining an internal SmallString he called > >>>>>> >> small_string_ostream. The commit was reverted after a day due to > a > >>>>>> >> disagreement about the commit approval and apparently abandoned. > >>>>>> >> > >>>>>> >> > >>>>>> >> > >>>>>> >> > http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140623/223393.html > >>>>>> >> > >>>>>> >> > >>>>>> >> > http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140623/223557.html > >>>>>> >> > >>>>>> >> > >>>>>> >> > http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140630/223986.html > >>>>>> >> > >>>>>> >> The class Alp comitted did solve the possible mismatch between > the > >>>>>> >> SmallString and the stream by making the SmallString private to > the > >>>>>> >> class. > >>>>>> >> This however did not treat the root problem, the duplication of > the > >>>>>> >> information about the buffer between SmallString and the stream. > >>>>>> >> > >>>>>> >> I can make performance measurements but even if the performance > >>>>>> >> difference > >>>>>> >> is neglible (and looking at all the code paths and conditionals > of > >>>>>> >> non-inlined functions at raw_ostream.cpp that's hard to believe), > >>>>>> >> the > >>>>>> >> current SmallString-raw_svector_ostream is simply wrong. > >>>>>> >> > >>>>>> >> Personally, after the previous "Alp" discussion I found and fixed > >>>>>> >> several > >>>>>> >> such issues in my out-of-tree code only to make new similar new > >>>>>> >> error > >>>>>> >> earlier this year, which I caught only months after, when Rafael > >>>>>> >> committed > >>>>>> >> the pwrite which reminded me the issue. Due ot the information > >>>>>> >> duplication > >>>>>> >> Rafael commit also had a bug and Mehdi reports similar > experience. > >>>>>> >> Back then > >>>>>> >> Alp reported similar problems he found in LLVM code which were > >>>>>> >> hopefully > >>>>>> >> fixed otherwise. > >>>>>> >> > >>>>>> >> In addition to the information duplication, the design is quite > >>>>>> >> confusing > >>>>>> >> to use > >>>>>> >> > >>>>>> >> - Should one use the stream.str() function or the SmallString > >>>>>> >> itself? > >>>>>> >> - flush or str? > >>>>>> >> - How do you properly clear the combination for reuse (that was > my > >>>>>> >> mistake, I forgot to resync after OS.clear())? > >>>>>> >> > >>>>>> >> It's safe to say this design pattern is very easy to get wrong > one > >>>>>> >> way or > >>>>>> >> another, we got burned by it multiple times and it should be > >>>>>> >> replaced. > >>>>>> >> > >>>>>> >> Alp suggested a derived class containing its own SmallString. > >>>>>> >> That's a > >>>>>> >> simple and effective approach to avoid the bugs mentioned but > does > >>>>>> >> not fix > >>>>>> >> the memory or runtime issues. Small as they may be, why have them > >>>>>> >> at a > >>>>>> >> fundemental data structure? > >>>>>> >> > >>>>>> >> I was thinking about going further avoiding all duplication with > a > >>>>>> >> templated class derived with its own internal buffer storage. > >>>>>> >> > >>>>>> >> Rafael suggested a more modular approach, a derived adpater class > >>>>>> >> adapter > >>>>>> >> to a *simple* buffer (or nullptr for fully-dynamic operation) > which > >>>>>> >> also > >>>>>> >> won't duplicate any information the buffer is dumb and has no > >>>>>> >> state. > >>>>>> >> > >>>>>> >> That solution sounds simple, efficient and safe to use. The > >>>>>> >> implementation > >>>>>> >> would be actually simpler then raw_svector_ostream since all the > >>>>>> >> coordination logic is not required anymore. > >>>>>> >> > >>>>>> >> > >>>>>> >> 2015-04-20 22:17 GMT+03:00 Sean Silva <chisophugis at gmail.com>: > >>>>>> >>> > >>>>>> >>> > >>>>>> >>> > >>>>>> >>> On Sun, Apr 19, 2015 at 7:40 AM, Yaron Keren > >>>>>> >>> <yaron.keren at gmail.com> > >>>>>> >>> wrote: > >>>>>> >>>> > >>>>>> >>>> A very common code pattern in LLVM is > >>>>>> >>>> > >>>>>> >>>> SmallString<128> S; > >>>>>> >>>> raw_svector_ostream OS(S); > >>>>>> >>>> OS<< ... > >>>>>> >>>> Use OS.str() > >>>>>> >>>> > >>>>>> >>>> While raw_svector_ostream is smart to share the text buffer > >>>>>> >>>> itself, it's > >>>>>> >>>> inefficient keeping two sets of pointers to the same buffer: > >>>>>> >>>> > >>>>>> >>>> In SmallString: void *BeginX, *EndX, *CapacityX > >>>>>> >>>> In raw_ostream: char *OutBufStart, *OutBufEnd, *OutBufCur > >>>>>> >>>> > >>>>>> >>>> Moreover, at runtime the two sets of pointers need to be > >>>>>> >>>> coordinated > >>>>>> >>>> between the SmallString and raw_svector_ostream using > >>>>>> >>>> raw_svector_ostream::init, raw_svector_ostream::pwrite, > >>>>>> >>>> raw_svector_ostream::resync and > raw_svector_ostream::write_impl. > >>>>>> >>>> All these functions have non-inlined implementations in > >>>>>> >>>> raw_ostream.cpp. > >>>>>> >>>> > >>>>>> >>>> Finally, this may cause subtle bugs if S is modified without > >>>>>> >>>> calling > >>>>>> >>>> OS::resync(). This is too easy to do by mistake. > >>>>>> >>>> > >>>>>> >>>> In this frequent case usage the client does not really care > about > >>>>>> >>>> S > >>>>>> >>>> being a SmallString with its many useful string helper > function. > >>>>>> >>>> It's just > >>>>>> >>>> boilerplate code for raw_svector_ostream. But it does cost > three > >>>>>> >>>> extra > >>>>>> >>>> pointers, some runtime performance and possible bugs. > >>>>>> >>> > >>>>>> >>> > >>>>>> >>> I agree the bugs are real (Alp proposed something a while back > >>>>>> >>> regarding > >>>>>> >>> this?), but you will need to provide measurements to justify the > >>>>>> >>> cost in > >>>>>> >>> runtime performance. One technique I have used in the past to > >>>>>> >>> measure these > >>>>>> >>> sorts of things I call "stuffing": take the operation that you > >>>>>> >>> want to > >>>>>> >>> measure, then essentially change the logic so that you pay the > >>>>>> >>> cost 2 times, > >>>>>> >>> 3 times, etc. You can then look at the trend in performance as N > >>>>>> >>> varies and > >>>>>> >>> extrapolate back to the case where N = 0 (i.e. you don't pay the > >>>>>> >>> cost). > >>>>>> >>> > >>>>>> >>> For example, in one situation where I used this method it was to > >>>>>> >>> measure > >>>>>> >>> the cost of stat'ing files (sys::fs::status) across a holistic > >>>>>> >>> build, using > >>>>>> >>> only "time" on the command line (it was on Windows and I didn't > >>>>>> >>> have any > >>>>>> >>> tools like DTrace available that can directly measure this). In > >>>>>> >>> order to do > >>>>>> >>> this, I changed sys::fs::status to call stat N times instead of > 1, > >>>>>> >>> and > >>>>>> >>> measured with N=1 N=2 N=3 etc. The result was that the > difference > >>>>>> >>> between > >>>>>> >>> the N and N+1 versions was about 1-2% across N=1..10 (or > whatever > >>>>>> >>> I > >>>>>> >>> measured). In order to negate caching and other confounding > >>>>>> >>> effects, it is > >>>>>> >>> important to try different distributions of stats; e.g. the > extra > >>>>>> >>> stats are > >>>>>> >>> on the same file as the "real" stat vs. the extra stats are on > >>>>>> >>> nonexistent > >>>>>> >>> files in the same directory as the "real" file vs. parent > >>>>>> >>> directories of the > >>>>>> >>> "real" file; if these match up fairly well (they did), then you > >>>>>> >>> have some > >>>>>> >>> indication that the "stuffing" is measuring what you want to > >>>>>> >>> measure. > >>>>>> >>> > >>>>>> >>> So e.g. if you think the cost of 3 extra pointers is > significant, > >>>>>> >>> then > >>>>>> >>> "stuff" the struct with 3, 6, 9, ... extra pointers and measure > >>>>>> >>> the > >>>>>> >>> difference in performance (e.g. measure the time building a real > >>>>>> >>> project). > >>>>>> >>> > >>>>>> >>> -- Sean Silva > >>>>>> >>> > >>>>>> >>>> > >>>>>> >>>> > >>>>>> >>>> To solve all three issues, would it make sense to have > >>>>>> >>>> raw_ostream-derived container with a its own SmallString like > >>>>>> >>>> templated-size > >>>>>> >>>> built-in buffer? > >>>>>> >>>> > >>>>>> >>> > >>>>>> > > >>>>> > >>>>> > >>>> > > >-------------- next part -------------- An HTML attachment was scrubbed... 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Rafael Espíndola via llvm-dev
2015-Aug-12 23:59 UTC
[llvm-dev] SmallString + raw_svector_ostream combination should be more efficient
Given that it is faster, I am OK with it. I get 0.774371631s with master and 0.649787169s with your patch. Why move all virtual functions to the header? LGTM with them still in the .cpp file. On 12 August 2015 at 01:53, Yaron Keren <yaron.keren at gmail.com> wrote:> +llvm-dev at lists.llvm.org > > The impact should be small as all the other streamers usually write directly > to the memory buffer and only when out of buffer they call write(). > > OTOH, raw_svector_ostream (without a buffer) goes though write for every > character or block it writes. It can work without virtual write() by > overriding the existing virtual write_impl() but this is a slower code path > for raw_svector_ostream. > > Even though the attached raw_svector_ostream patch without virtual write() > is still significantly faster then the current raw_svector_ostream since it > avoids the double buffering. With this patch, on my system the example runs > at 750ms compared with about 1000ms for the current raw_svector_ostream. > > Would you prefer to continue review on Phabricator? > > 2015-07-11 20:48 GMT+03:00 Rafael Espíndola <rafael.espindola at gmail.com>: >> >> This makes write virtual. What is the impact of that on the other >> streamers? >> >> >> >> On 22 May 2015 at 10:17, Yaron Keren <yaron.keren at gmail.com> wrote: >> > Here's a performance testcase for the raw_svector_ostream patch. On my >> > WIndows x64 machine it runs in 1010ms with the current code and in 440ms >> > with the patch applies. Is this OK to commit? >> > >> > >> > 2015-05-02 21:31 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: >> >> >> >> Following a hint from Duncan in http://llvm.org/pr23395, here is a >> >> revised >> >> patch. Rather then introduce the raw_char_ostream adapter, this version >> >> improves raw_svector_ostream. >> >> >> >> raw_svector_ostream is now a very lightweight adapter, running without >> >> a >> >> buffer and fowarding almost anything to the SmallString. This solves >> >> both >> >> the performance issue and the information duplication issue. The >> >> SmallString >> >> is always up-to-date and can be used at any time. flush() does nothing >> >> and >> >> is not required. resync() was kept in this patch as a no-op and will be >> >> removed with its users in a follow-up patch. I'll also try to remove >> >> the >> >> superfluous flush calls() along the way. >> >> >> >> >> >> >> >> 2015-05-02 7:41 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: >> >>> >> >>> +update diff >> >>> >> >>> >> >>> 2015-05-02 7:38 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: >> >>>> >> >>>> I outlined (is that the right word?) raw_char_ostream::grow, >> >>>> raw_char_ostream::write (both) into raw_ostream.cpp with less than >> >>>> 10% >> >>>> difference in performance. >> >>>> >> >>>> Profiling reveals that the real culprit is the code line >> >>>> >> >>>> OS.reserve(OS.size() + 64); >> >>>> >> >>>> called from raw_svector_ostream::write_impl called from >> >>>> raw_svector_ostream::~raw_svector_ostream. >> >>>> The issue is already documented: >> >>>> >> >>>> raw_svector_ostream::~raw_svector_ostream() { >> >>>> // FIXME: Prevent resizing during this flush(). >> >>>> flush(); >> >>>> } >> >>>> >> >>>> And a solution is provided in raw_svector_ostream::init(): >> >>>> >> >>>> // Set up the initial external buffer. We make sure that the buffer >> >>>> has at >> >>>> // least 128 bytes free; raw_ostream itself only requires 64, but >> >>>> we >> >>>> want to >> >>>> // make sure that we don't grow the buffer unnecessarily on >> >>>> destruction (when >> >>>> // the data is flushed). See the FIXME below. >> >>>> OS.reserve(OS.size() + 128); >> >>>> >> >>>> This solution may be worse than the problem. In total: >> >>>> >> >>>> * If the SmallString was less than 128 bytes init() will always(!) >> >>>> heap >> >>>> allocate. >> >>>> * If it's more or equal to 128 bytes but upon destruction less than >> >>>> 64 >> >>>> bytes are left unused it will heap allocate for no reason. >> >>>> >> >>>> A careful programmer who did size the SmallString to match its use + >> >>>> small reserve will find either of these heap allocations surprising, >> >>>> negating the SmallString advantage and then paying memcpy cost. >> >>>> >> >>>> I filed http://llvm.org/pr23395 about this. To temporarly avoid this >> >>>> issue, in addition to the outline methods change I commented the >> >>>> OS.reserve >> >>>> line in flush(). (This change of course requires further review.) >> >>>> >> >>>> With reserve being out of the way, the gap now is smaller but still >> >>>> significant: raw_char_ostream is about 20% faster than >> >>>> raw_svector_ostream >> >>>> in Release=optimized configuration. >> >>>> >> >>>> >> >>>> 2015-05-02 4:39 GMT+03:00 Sean Silva <chisophugis at gmail.com>: >> >>>>> >> >>>>> >> >>>>> Could you dig into why: >> >>>>> + raw_ostream &write(unsigned char C) override { >> >>>>> + grow(1); >> >>>>> + *OutBufCur++ = C; >> >>>>> + return *this; >> >>>>> + } >> >>>>> >> >>>>> Is 3 times as fast as raw_svector_ostream? I don't see a good reason >> >>>>> why that should be any faster than: >> >>>>> >> >>>>> raw_ostream &operator<<(char C) { >> >>>>> if (OutBufCur >= OutBufEnd) >> >>>>> return write(C); >> >>>>> *OutBufCur++ = C; >> >>>>> return *this; >> >>>>> } >> >>>>> >> >>>>> >> >>>>> You might just be seeing the difference between having write inlined >> >>>>> vs. non-inlined, in which case your patch might be a complicated way >> >>>>> to pull >> >>>>> the likely cases of some raw_ostream methods into the header. >> >>>>> >> >>>>> >> >>>>> -- Sean Silva >> >>>> >> >>>> >> >>>> On Thu, Apr 30, 2015 at 8:02 PM, Yaron Keren <yaron.keren at gmail.com> >> >>>> wrote: >> >>>>> >> >>>>> Yes, we should do without virtual flush. The problem was >> >>>>> raw_char_ostream should not be flushed - it's always current - so I >> >>>>> overloaded flush to a no-op. A cleaner solution is attached, adding >> >>>>> a >> >>>>> DirectBuffer mode to the raw_ostream. >> >>>>> >> >>>>> Also added a simple performance comparison project between >> >>>>> raw_char_ostream and raw_svector_ostream. On Window 7 x64 machine, >> >>>>> raw_char_ostream was three times faster than raw_svector_ostream >> >>>>> when the >> >>>>> provided buffer size is large enough and two times as fast with one >> >>>>> dynamic >> >>>>> allocation resize. >> >>>>> >> >>>>> >> >>>>> 2015-04-30 22:48 GMT+03:00 Rafael Espíndola >> >>>>> <rafael.espindola at gmail.com>: >> >>>>>> >> >>>>>> I don't think we should make flush virtual. Why do you need to do >> >>>>>> it? >> >>>>>> Can't you set up the base class to write to use the tail of the >> >>>>>> memory >> >>>>>> region as the buffer? >> >>>>>> >> >>>>>> >> >>>>>> >> >>>>>> On 24 April 2015 at 06:46, Yaron Keren <yaron.keren at gmail.com> >> >>>>>> wrote: >> >>>>>> > Hi, >> >>>>>> > >> >>>>>> > Is this what you're thinking about? >> >>>>>> > The code is not tested yet, I'd like to know if the overall >> >>>>>> > direction and >> >>>>>> > design are correct. >> >>>>>> > >> >>>>>> > Yaron >> >>>>>> > >> >>>>>> > >> >>>>>> > 2015-04-21 0:10 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: >> >>>>>> >> >> >>>>>> >> Sean, thanks for reminding this, Alp did commit a class derived >> >>>>>> >> from >> >>>>>> >> raw_svector_ostream conatining an internal SmallString he called >> >>>>>> >> small_string_ostream. The commit was reverted after a day due to >> >>>>>> >> a >> >>>>>> >> disagreement about the commit approval and apparently abandoned. >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140623/223393.html >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140623/223557.html >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140630/223986.html >> >>>>>> >> >> >>>>>> >> The class Alp comitted did solve the possible mismatch between >> >>>>>> >> the >> >>>>>> >> SmallString and the stream by making the SmallString private to >> >>>>>> >> the >> >>>>>> >> class. >> >>>>>> >> This however did not treat the root problem, the duplication of >> >>>>>> >> the >> >>>>>> >> information about the buffer between SmallString and the stream. >> >>>>>> >> >> >>>>>> >> I can make performance measurements but even if the performance >> >>>>>> >> difference >> >>>>>> >> is neglible (and looking at all the code paths and conditionals >> >>>>>> >> of >> >>>>>> >> non-inlined functions at raw_ostream.cpp that's hard to >> >>>>>> >> believe), >> >>>>>> >> the >> >>>>>> >> current SmallString-raw_svector_ostream is simply wrong. >> >>>>>> >> >> >>>>>> >> Personally, after the previous "Alp" discussion I found and >> >>>>>> >> fixed >> >>>>>> >> several >> >>>>>> >> such issues in my out-of-tree code only to make new similar new >> >>>>>> >> error >> >>>>>> >> earlier this year, which I caught only months after, when Rafael >> >>>>>> >> committed >> >>>>>> >> the pwrite which reminded me the issue. Due ot the information >> >>>>>> >> duplication >> >>>>>> >> Rafael commit also had a bug and Mehdi reports similar >> >>>>>> >> experience. >> >>>>>> >> Back then >> >>>>>> >> Alp reported similar problems he found in LLVM code which were >> >>>>>> >> hopefully >> >>>>>> >> fixed otherwise. >> >>>>>> >> >> >>>>>> >> In addition to the information duplication, the design is quite >> >>>>>> >> confusing >> >>>>>> >> to use >> >>>>>> >> >> >>>>>> >> - Should one use the stream.str() function or the SmallString >> >>>>>> >> itself? >> >>>>>> >> - flush or str? >> >>>>>> >> - How do you properly clear the combination for reuse (that was >> >>>>>> >> my >> >>>>>> >> mistake, I forgot to resync after OS.clear())? >> >>>>>> >> >> >>>>>> >> It's safe to say this design pattern is very easy to get wrong >> >>>>>> >> one >> >>>>>> >> way or >> >>>>>> >> another, we got burned by it multiple times and it should be >> >>>>>> >> replaced. >> >>>>>> >> >> >>>>>> >> Alp suggested a derived class containing its own SmallString. >> >>>>>> >> That's a >> >>>>>> >> simple and effective approach to avoid the bugs mentioned but >> >>>>>> >> does >> >>>>>> >> not fix >> >>>>>> >> the memory or runtime issues. Small as they may be, why have >> >>>>>> >> them >> >>>>>> >> at a >> >>>>>> >> fundemental data structure? >> >>>>>> >> >> >>>>>> >> I was thinking about going further avoiding all duplication with >> >>>>>> >> a >> >>>>>> >> templated class derived with its own internal buffer storage. >> >>>>>> >> >> >>>>>> >> Rafael suggested a more modular approach, a derived adpater >> >>>>>> >> class >> >>>>>> >> adapter >> >>>>>> >> to a *simple* buffer (or nullptr for fully-dynamic operation) >> >>>>>> >> which >> >>>>>> >> also >> >>>>>> >> won't duplicate any information the buffer is dumb and has no >> >>>>>> >> state. >> >>>>>> >> >> >>>>>> >> That solution sounds simple, efficient and safe to use. The >> >>>>>> >> implementation >> >>>>>> >> would be actually simpler then raw_svector_ostream since all the >> >>>>>> >> coordination logic is not required anymore. >> >>>>>> >> >> >>>>>> >> >> >>>>>> >> 2015-04-20 22:17 GMT+03:00 Sean Silva <chisophugis at gmail.com>: >> >>>>>> >>> >> >>>>>> >>> >> >>>>>> >>> >> >>>>>> >>> On Sun, Apr 19, 2015 at 7:40 AM, Yaron Keren >> >>>>>> >>> <yaron.keren at gmail.com> >> >>>>>> >>> wrote: >> >>>>>> >>>> >> >>>>>> >>>> A very common code pattern in LLVM is >> >>>>>> >>>> >> >>>>>> >>>> SmallString<128> S; >> >>>>>> >>>> raw_svector_ostream OS(S); >> >>>>>> >>>> OS<< ... >> >>>>>> >>>> Use OS.str() >> >>>>>> >>>> >> >>>>>> >>>> While raw_svector_ostream is smart to share the text buffer >> >>>>>> >>>> itself, it's >> >>>>>> >>>> inefficient keeping two sets of pointers to the same buffer: >> >>>>>> >>>> >> >>>>>> >>>> In SmallString: void *BeginX, *EndX, *CapacityX >> >>>>>> >>>> In raw_ostream: char *OutBufStart, *OutBufEnd, *OutBufCur >> >>>>>> >>>> >> >>>>>> >>>> Moreover, at runtime the two sets of pointers need to be >> >>>>>> >>>> coordinated >> >>>>>> >>>> between the SmallString and raw_svector_ostream using >> >>>>>> >>>> raw_svector_ostream::init, raw_svector_ostream::pwrite, >> >>>>>> >>>> raw_svector_ostream::resync and >> >>>>>> >>>> raw_svector_ostream::write_impl. >> >>>>>> >>>> All these functions have non-inlined implementations in >> >>>>>> >>>> raw_ostream.cpp. >> >>>>>> >>>> >> >>>>>> >>>> Finally, this may cause subtle bugs if S is modified without >> >>>>>> >>>> calling >> >>>>>> >>>> OS::resync(). This is too easy to do by mistake. >> >>>>>> >>>> >> >>>>>> >>>> In this frequent case usage the client does not really care >> >>>>>> >>>> about >> >>>>>> >>>> S >> >>>>>> >>>> being a SmallString with its many useful string helper >> >>>>>> >>>> function. >> >>>>>> >>>> It's just >> >>>>>> >>>> boilerplate code for raw_svector_ostream. But it does cost >> >>>>>> >>>> three >> >>>>>> >>>> extra >> >>>>>> >>>> pointers, some runtime performance and possible bugs. >> >>>>>> >>> >> >>>>>> >>> >> >>>>>> >>> I agree the bugs are real (Alp proposed something a while back >> >>>>>> >>> regarding >> >>>>>> >>> this?), but you will need to provide measurements to justify >> >>>>>> >>> the >> >>>>>> >>> cost in >> >>>>>> >>> runtime performance. One technique I have used in the past to >> >>>>>> >>> measure these >> >>>>>> >>> sorts of things I call "stuffing": take the operation that you >> >>>>>> >>> want to >> >>>>>> >>> measure, then essentially change the logic so that you pay the >> >>>>>> >>> cost 2 times, >> >>>>>> >>> 3 times, etc. You can then look at the trend in performance as >> >>>>>> >>> N >> >>>>>> >>> varies and >> >>>>>> >>> extrapolate back to the case where N = 0 (i.e. you don't pay >> >>>>>> >>> the >> >>>>>> >>> cost). >> >>>>>> >>> >> >>>>>> >>> For example, in one situation where I used this method it was >> >>>>>> >>> to >> >>>>>> >>> measure >> >>>>>> >>> the cost of stat'ing files (sys::fs::status) across a holistic >> >>>>>> >>> build, using >> >>>>>> >>> only "time" on the command line (it was on Windows and I didn't >> >>>>>> >>> have any >> >>>>>> >>> tools like DTrace available that can directly measure this). In >> >>>>>> >>> order to do >> >>>>>> >>> this, I changed sys::fs::status to call stat N times instead of >> >>>>>> >>> 1, >> >>>>>> >>> and >> >>>>>> >>> measured with N=1 N=2 N=3 etc. The result was that the >> >>>>>> >>> difference >> >>>>>> >>> between >> >>>>>> >>> the N and N+1 versions was about 1-2% across N=1..10 (or >> >>>>>> >>> whatever >> >>>>>> >>> I >> >>>>>> >>> measured). In order to negate caching and other confounding >> >>>>>> >>> effects, it is >> >>>>>> >>> important to try different distributions of stats; e.g. the >> >>>>>> >>> extra >> >>>>>> >>> stats are >> >>>>>> >>> on the same file as the "real" stat vs. the extra stats are on >> >>>>>> >>> nonexistent >> >>>>>> >>> files in the same directory as the "real" file vs. parent >> >>>>>> >>> directories of the >> >>>>>> >>> "real" file; if these match up fairly well (they did), then you >> >>>>>> >>> have some >> >>>>>> >>> indication that the "stuffing" is measuring what you want to >> >>>>>> >>> measure. >> >>>>>> >>> >> >>>>>> >>> So e.g. if you think the cost of 3 extra pointers is >> >>>>>> >>> significant, >> >>>>>> >>> then >> >>>>>> >>> "stuff" the struct with 3, 6, 9, ... extra pointers and measure >> >>>>>> >>> the >> >>>>>> >>> difference in performance (e.g. measure the time building a >> >>>>>> >>> real >> >>>>>> >>> project). >> >>>>>> >>> >> >>>>>> >>> -- Sean Silva >> >>>>>> >>> >> >>>>>> >>>> >> >>>>>> >>>> >> >>>>>> >>>> To solve all three issues, would it make sense to have >> >>>>>> >>>> raw_ostream-derived container with a its own SmallString like >> >>>>>> >>>> templated-size >> >>>>>> >>>> built-in buffer? >> >>>>>> >>>> >> >>>>>> >>> >> >>>>>> > >> >>>>> >> >>>>> >> >>>> >> > > >
Yaron Keren via llvm-dev
2015-Aug-13 08:17 UTC
[llvm-dev] SmallString + raw_svector_ostream combination should be more efficient
r244870 (with the change you requested), thanks! I initially placed the virtual function in header since they were one-liners. The coding standards say that an anchor() function should be supplied, which was indeed missing. Other than required anchor function, why should the virtual functions go in the .cpp? Should I move the empty raw_svector_ostream destructor to the .cpp file too as well? 2015-08-13 2:59 GMT+03:00 Rafael Espíndola <rafael.espindola at gmail.com>:> Given that it is faster, I am OK with it. > > I get 0.774371631s with master and 0.649787169s with your patch. > > Why move all virtual functions to the header? LGTM with them still in > the .cpp file. > > On 12 August 2015 at 01:53, Yaron Keren <yaron.keren at gmail.com> wrote: > > +llvm-dev at lists.llvm.org > > > > The impact should be small as all the other streamers usually write > directly > > to the memory buffer and only when out of buffer they call write(). > > > > OTOH, raw_svector_ostream (without a buffer) goes though write for every > > character or block it writes. It can work without virtual write() by > > overriding the existing virtual write_impl() but this is a slower code > path > > for raw_svector_ostream. > > > > Even though the attached raw_svector_ostream patch without virtual > write() > > is still significantly faster then the current raw_svector_ostream since > it > > avoids the double buffering. With this patch, on my system the example > runs > > at 750ms compared with about 1000ms for the current raw_svector_ostream. > > > > Would you prefer to continue review on Phabricator? > > > > 2015-07-11 20:48 GMT+03:00 Rafael Espíndola <rafael.espindola at gmail.com > >: > >> > >> This makes write virtual. What is the impact of that on the other > >> streamers? > >> > >> > >> > >> On 22 May 2015 at 10:17, Yaron Keren <yaron.keren at gmail.com> wrote: > >> > Here's a performance testcase for the raw_svector_ostream patch. On my > >> > WIndows x64 machine it runs in 1010ms with the current code and in > 440ms > >> > with the patch applies. Is this OK to commit? > >> > > >> > > >> > 2015-05-02 21:31 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >> >> > >> >> Following a hint from Duncan in http://llvm.org/pr23395, here is a > >> >> revised > >> >> patch. Rather then introduce the raw_char_ostream adapter, this > version > >> >> improves raw_svector_ostream. > >> >> > >> >> raw_svector_ostream is now a very lightweight adapter, running > without > >> >> a > >> >> buffer and fowarding almost anything to the SmallString. This solves > >> >> both > >> >> the performance issue and the information duplication issue. The > >> >> SmallString > >> >> is always up-to-date and can be used at any time. flush() does > nothing > >> >> and > >> >> is not required. resync() was kept in this patch as a no-op and will > be > >> >> removed with its users in a follow-up patch. I'll also try to remove > >> >> the > >> >> superfluous flush calls() along the way. > >> >> > >> >> > >> >> > >> >> 2015-05-02 7:41 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >> >>> > >> >>> +update diff > >> >>> > >> >>> > >> >>> 2015-05-02 7:38 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >> >>>> > >> >>>> I outlined (is that the right word?) raw_char_ostream::grow, > >> >>>> raw_char_ostream::write (both) into raw_ostream.cpp with less than > >> >>>> 10% > >> >>>> difference in performance. > >> >>>> > >> >>>> Profiling reveals that the real culprit is the code line > >> >>>> > >> >>>> OS.reserve(OS.size() + 64); > >> >>>> > >> >>>> called from raw_svector_ostream::write_impl called from > >> >>>> raw_svector_ostream::~raw_svector_ostream. > >> >>>> The issue is already documented: > >> >>>> > >> >>>> raw_svector_ostream::~raw_svector_ostream() { > >> >>>> // FIXME: Prevent resizing during this flush(). > >> >>>> flush(); > >> >>>> } > >> >>>> > >> >>>> And a solution is provided in raw_svector_ostream::init(): > >> >>>> > >> >>>> // Set up the initial external buffer. We make sure that the > buffer > >> >>>> has at > >> >>>> // least 128 bytes free; raw_ostream itself only requires 64, but > >> >>>> we > >> >>>> want to > >> >>>> // make sure that we don't grow the buffer unnecessarily on > >> >>>> destruction (when > >> >>>> // the data is flushed). See the FIXME below. > >> >>>> OS.reserve(OS.size() + 128); > >> >>>> > >> >>>> This solution may be worse than the problem. In total: > >> >>>> > >> >>>> * If the SmallString was less than 128 bytes init() will always(!) > >> >>>> heap > >> >>>> allocate. > >> >>>> * If it's more or equal to 128 bytes but upon destruction less than > >> >>>> 64 > >> >>>> bytes are left unused it will heap allocate for no reason. > >> >>>> > >> >>>> A careful programmer who did size the SmallString to match its use > + > >> >>>> small reserve will find either of these heap allocations > surprising, > >> >>>> negating the SmallString advantage and then paying memcpy cost. > >> >>>> > >> >>>> I filed http://llvm.org/pr23395 about this. To temporarly avoid > this > >> >>>> issue, in addition to the outline methods change I commented the > >> >>>> OS.reserve > >> >>>> line in flush(). (This change of course requires further review.) > >> >>>> > >> >>>> With reserve being out of the way, the gap now is smaller but still > >> >>>> significant: raw_char_ostream is about 20% faster than > >> >>>> raw_svector_ostream > >> >>>> in Release=optimized configuration. > >> >>>> > >> >>>> > >> >>>> 2015-05-02 4:39 GMT+03:00 Sean Silva <chisophugis at gmail.com>: > >> >>>>> > >> >>>>> > >> >>>>> Could you dig into why: > >> >>>>> + raw_ostream &write(unsigned char C) override { > >> >>>>> + grow(1); > >> >>>>> + *OutBufCur++ = C; > >> >>>>> + return *this; > >> >>>>> + } > >> >>>>> > >> >>>>> Is 3 times as fast as raw_svector_ostream? I don't see a good > reason > >> >>>>> why that should be any faster than: > >> >>>>> > >> >>>>> raw_ostream &operator<<(char C) { > >> >>>>> if (OutBufCur >= OutBufEnd) > >> >>>>> return write(C); > >> >>>>> *OutBufCur++ = C; > >> >>>>> return *this; > >> >>>>> } > >> >>>>> > >> >>>>> > >> >>>>> You might just be seeing the difference between having write > inlined > >> >>>>> vs. non-inlined, in which case your patch might be a complicated > way > >> >>>>> to pull > >> >>>>> the likely cases of some raw_ostream methods into the header. > >> >>>>> > >> >>>>> > >> >>>>> -- Sean Silva > >> >>>> > >> >>>> > >> >>>> On Thu, Apr 30, 2015 at 8:02 PM, Yaron Keren < > yaron.keren at gmail.com> > >> >>>> wrote: > >> >>>>> > >> >>>>> Yes, we should do without virtual flush. The problem was > >> >>>>> raw_char_ostream should not be flushed - it's always current - so > I > >> >>>>> overloaded flush to a no-op. A cleaner solution is attached, > adding > >> >>>>> a > >> >>>>> DirectBuffer mode to the raw_ostream. > >> >>>>> > >> >>>>> Also added a simple performance comparison project between > >> >>>>> raw_char_ostream and raw_svector_ostream. On Window 7 x64 machine, > >> >>>>> raw_char_ostream was three times faster than raw_svector_ostream > >> >>>>> when the > >> >>>>> provided buffer size is large enough and two times as fast with > one > >> >>>>> dynamic > >> >>>>> allocation resize. > >> >>>>> > >> >>>>> > >> >>>>> 2015-04-30 22:48 GMT+03:00 Rafael Espíndola > >> >>>>> <rafael.espindola at gmail.com>: > >> >>>>>> > >> >>>>>> I don't think we should make flush virtual. Why do you need to do > >> >>>>>> it? > >> >>>>>> Can't you set up the base class to write to use the tail of the > >> >>>>>> memory > >> >>>>>> region as the buffer? > >> >>>>>> > >> >>>>>> > >> >>>>>> > >> >>>>>> On 24 April 2015 at 06:46, Yaron Keren <yaron.keren at gmail.com> > >> >>>>>> wrote: > >> >>>>>> > Hi, > >> >>>>>> > > >> >>>>>> > Is this what you're thinking about? > >> >>>>>> > The code is not tested yet, I'd like to know if the overall > >> >>>>>> > direction and > >> >>>>>> > design are correct. > >> >>>>>> > > >> >>>>>> > Yaron > >> >>>>>> > > >> >>>>>> > > >> >>>>>> > 2015-04-21 0:10 GMT+03:00 Yaron Keren <yaron.keren at gmail.com>: > >> >>>>>> >> > >> >>>>>> >> Sean, thanks for reminding this, Alp did commit a class > derived > >> >>>>>> >> from > >> >>>>>> >> raw_svector_ostream conatining an internal SmallString he > called > >> >>>>>> >> small_string_ostream. The commit was reverted after a day due > to > >> >>>>>> >> a > >> >>>>>> >> disagreement about the commit approval and apparently > abandoned. > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140623/223393.html > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140623/223557.html > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> > http://lists.cs.uiuc.edu/pipermail/llvm-commits/Week-of-Mon-20140630/223986.html > >> >>>>>> >> > >> >>>>>> >> The class Alp comitted did solve the possible mismatch between > >> >>>>>> >> the > >> >>>>>> >> SmallString and the stream by making the SmallString private > to > >> >>>>>> >> the > >> >>>>>> >> class. > >> >>>>>> >> This however did not treat the root problem, the duplication > of > >> >>>>>> >> the > >> >>>>>> >> information about the buffer between SmallString and the > stream. > >> >>>>>> >> > >> >>>>>> >> I can make performance measurements but even if the > performance > >> >>>>>> >> difference > >> >>>>>> >> is neglible (and looking at all the code paths and > conditionals > >> >>>>>> >> of > >> >>>>>> >> non-inlined functions at raw_ostream.cpp that's hard to > >> >>>>>> >> believe), > >> >>>>>> >> the > >> >>>>>> >> current SmallString-raw_svector_ostream is simply wrong. > >> >>>>>> >> > >> >>>>>> >> Personally, after the previous "Alp" discussion I found and > >> >>>>>> >> fixed > >> >>>>>> >> several > >> >>>>>> >> such issues in my out-of-tree code only to make new similar > new > >> >>>>>> >> error > >> >>>>>> >> earlier this year, which I caught only months after, when > Rafael > >> >>>>>> >> committed > >> >>>>>> >> the pwrite which reminded me the issue. Due ot the information > >> >>>>>> >> duplication > >> >>>>>> >> Rafael commit also had a bug and Mehdi reports similar > >> >>>>>> >> experience. > >> >>>>>> >> Back then > >> >>>>>> >> Alp reported similar problems he found in LLVM code which were > >> >>>>>> >> hopefully > >> >>>>>> >> fixed otherwise. > >> >>>>>> >> > >> >>>>>> >> In addition to the information duplication, the design is > quite > >> >>>>>> >> confusing > >> >>>>>> >> to use > >> >>>>>> >> > >> >>>>>> >> - Should one use the stream.str() function or the SmallString > >> >>>>>> >> itself? > >> >>>>>> >> - flush or str? > >> >>>>>> >> - How do you properly clear the combination for reuse (that > was > >> >>>>>> >> my > >> >>>>>> >> mistake, I forgot to resync after OS.clear())? > >> >>>>>> >> > >> >>>>>> >> It's safe to say this design pattern is very easy to get wrong > >> >>>>>> >> one > >> >>>>>> >> way or > >> >>>>>> >> another, we got burned by it multiple times and it should be > >> >>>>>> >> replaced. > >> >>>>>> >> > >> >>>>>> >> Alp suggested a derived class containing its own SmallString. > >> >>>>>> >> That's a > >> >>>>>> >> simple and effective approach to avoid the bugs mentioned but > >> >>>>>> >> does > >> >>>>>> >> not fix > >> >>>>>> >> the memory or runtime issues. Small as they may be, why have > >> >>>>>> >> them > >> >>>>>> >> at a > >> >>>>>> >> fundemental data structure? > >> >>>>>> >> > >> >>>>>> >> I was thinking about going further avoiding all duplication > with > >> >>>>>> >> a > >> >>>>>> >> templated class derived with its own internal buffer storage. > >> >>>>>> >> > >> >>>>>> >> Rafael suggested a more modular approach, a derived adpater > >> >>>>>> >> class > >> >>>>>> >> adapter > >> >>>>>> >> to a *simple* buffer (or nullptr for fully-dynamic operation) > >> >>>>>> >> which > >> >>>>>> >> also > >> >>>>>> >> won't duplicate any information the buffer is dumb and has no > >> >>>>>> >> state. > >> >>>>>> >> > >> >>>>>> >> That solution sounds simple, efficient and safe to use. The > >> >>>>>> >> implementation > >> >>>>>> >> would be actually simpler then raw_svector_ostream since all > the > >> >>>>>> >> coordination logic is not required anymore. > >> >>>>>> >> > >> >>>>>> >> > >> >>>>>> >> 2015-04-20 22:17 GMT+03:00 Sean Silva <chisophugis at gmail.com > >: > >> >>>>>> >>> > >> >>>>>> >>> > >> >>>>>> >>> > >> >>>>>> >>> On Sun, Apr 19, 2015 at 7:40 AM, Yaron Keren > >> >>>>>> >>> <yaron.keren at gmail.com> > >> >>>>>> >>> wrote: > >> >>>>>> >>>> > >> >>>>>> >>>> A very common code pattern in LLVM is > >> >>>>>> >>>> > >> >>>>>> >>>> SmallString<128> S; > >> >>>>>> >>>> raw_svector_ostream OS(S); > >> >>>>>> >>>> OS<< ... > >> >>>>>> >>>> Use OS.str() > >> >>>>>> >>>> > >> >>>>>> >>>> While raw_svector_ostream is smart to share the text buffer > >> >>>>>> >>>> itself, it's > >> >>>>>> >>>> inefficient keeping two sets of pointers to the same buffer: > >> >>>>>> >>>> > >> >>>>>> >>>> In SmallString: void *BeginX, *EndX, *CapacityX > >> >>>>>> >>>> In raw_ostream: char *OutBufStart, *OutBufEnd, *OutBufCur > >> >>>>>> >>>> > >> >>>>>> >>>> Moreover, at runtime the two sets of pointers need to be > >> >>>>>> >>>> coordinated > >> >>>>>> >>>> between the SmallString and raw_svector_ostream using > >> >>>>>> >>>> raw_svector_ostream::init, raw_svector_ostream::pwrite, > >> >>>>>> >>>> raw_svector_ostream::resync and > >> >>>>>> >>>> raw_svector_ostream::write_impl. > >> >>>>>> >>>> All these functions have non-inlined implementations in > >> >>>>>> >>>> raw_ostream.cpp. > >> >>>>>> >>>> > >> >>>>>> >>>> Finally, this may cause subtle bugs if S is modified without > >> >>>>>> >>>> calling > >> >>>>>> >>>> OS::resync(). This is too easy to do by mistake. > >> >>>>>> >>>> > >> >>>>>> >>>> In this frequent case usage the client does not really care > >> >>>>>> >>>> about > >> >>>>>> >>>> S > >> >>>>>> >>>> being a SmallString with its many useful string helper > >> >>>>>> >>>> function. > >> >>>>>> >>>> It's just > >> >>>>>> >>>> boilerplate code for raw_svector_ostream. But it does cost > >> >>>>>> >>>> three > >> >>>>>> >>>> extra > >> >>>>>> >>>> pointers, some runtime performance and possible bugs. > >> >>>>>> >>> > >> >>>>>> >>> > >> >>>>>> >>> I agree the bugs are real (Alp proposed something a while > back > >> >>>>>> >>> regarding > >> >>>>>> >>> this?), but you will need to provide measurements to justify > >> >>>>>> >>> the > >> >>>>>> >>> cost in > >> >>>>>> >>> runtime performance. One technique I have used in the past to > >> >>>>>> >>> measure these > >> >>>>>> >>> sorts of things I call "stuffing": take the operation that > you > >> >>>>>> >>> want to > >> >>>>>> >>> measure, then essentially change the logic so that you pay > the > >> >>>>>> >>> cost 2 times, > >> >>>>>> >>> 3 times, etc. You can then look at the trend in performance > as > >> >>>>>> >>> N > >> >>>>>> >>> varies and > >> >>>>>> >>> extrapolate back to the case where N = 0 (i.e. you don't pay > >> >>>>>> >>> the > >> >>>>>> >>> cost). > >> >>>>>> >>> > >> >>>>>> >>> For example, in one situation where I used this method it was > >> >>>>>> >>> to > >> >>>>>> >>> measure > >> >>>>>> >>> the cost of stat'ing files (sys::fs::status) across a > holistic > >> >>>>>> >>> build, using > >> >>>>>> >>> only "time" on the command line (it was on Windows and I > didn't > >> >>>>>> >>> have any > >> >>>>>> >>> tools like DTrace available that can directly measure this). > In > >> >>>>>> >>> order to do > >> >>>>>> >>> this, I changed sys::fs::status to call stat N times instead > of > >> >>>>>> >>> 1, > >> >>>>>> >>> and > >> >>>>>> >>> measured with N=1 N=2 N=3 etc. The result was that the > >> >>>>>> >>> difference > >> >>>>>> >>> between > >> >>>>>> >>> the N and N+1 versions was about 1-2% across N=1..10 (or > >> >>>>>> >>> whatever > >> >>>>>> >>> I > >> >>>>>> >>> measured). In order to negate caching and other confounding > >> >>>>>> >>> effects, it is > >> >>>>>> >>> important to try different distributions of stats; e.g. the > >> >>>>>> >>> extra > >> >>>>>> >>> stats are > >> >>>>>> >>> on the same file as the "real" stat vs. the extra stats are > on > >> >>>>>> >>> nonexistent > >> >>>>>> >>> files in the same directory as the "real" file vs. parent > >> >>>>>> >>> directories of the > >> >>>>>> >>> "real" file; if these match up fairly well (they did), then > you > >> >>>>>> >>> have some > >> >>>>>> >>> indication that the "stuffing" is measuring what you want to > >> >>>>>> >>> measure. > >> >>>>>> >>> > >> >>>>>> >>> So e.g. if you think the cost of 3 extra pointers is > >> >>>>>> >>> significant, > >> >>>>>> >>> then > >> >>>>>> >>> "stuff" the struct with 3, 6, 9, ... extra pointers and > measure > >> >>>>>> >>> the > >> >>>>>> >>> difference in performance (e.g. measure the time building a > >> >>>>>> >>> real > >> >>>>>> >>> project). > >> >>>>>> >>> > >> >>>>>> >>> -- Sean Silva > >> >>>>>> >>> > >> >>>>>> >>>> > >> >>>>>> >>>> > >> >>>>>> >>>> To solve all three issues, would it make sense to have > >> >>>>>> >>>> raw_ostream-derived container with a its own SmallString > like > >> >>>>>> >>>> templated-size > >> >>>>>> >>>> built-in buffer? > >> >>>>>> >>>> > >> >>>>>> >>> > >> >>>>>> > > >> >>>>> > >> >>>>> > >> >>>> > >> > > > > > >-------------- next part -------------- An HTML attachment was scrubbed... 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