Quentin Colombet via llvm-dev
2018-Feb-09 01:34 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
Hi, TL;DR r317488 changed the way fast math flags are laid out in the bitcode and anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math expectations. Should we bump the bitcode version because of that and have the autoupgrader properly rewrite the fast-math to preserve that semantic? (I believe we should!) * Context * With https://reviews.llvm.org/D39304 <https://reviews.llvm.org/D39304> / r317488 we got rid of the umbrella UnsafeMath flag and introduced 3 more flags that better represent the different things that happen under fast-math. From a bitcode perspective, this change looks like this: Before r317488 we had 6 bits that respectively represented: UnsafeMath nnan ninf nsz arcp contract *unset* (The order may not match what is exactly in the bitcode.) After r317488 we had 7 bits that respectively represented: reassoc (-UnsafeMath- is gone) nnan ninf nsz arcp contract *afn* (new bit) Before r317488, fast-math was true if UnsafeMath was true (this should also imply all the other flags are sets). After r317488, fast-math is true if all the bits are set, in particular the afn, new one, too. * Problem * Given we currently have no way to check if a bitcode file has been generated pre-r317488 or post-r317488 that means that: 1. a post-r317488 compiler is going to skip any optimization guarded by isFast for all pre-r317488 bitcode file (remember the afn bit is not set here) 2. a pre-r317488 compiler is going to run any optimization guarded by unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit (remember we repurposed UnsafeMath) Scenario #2 might be unlikely but we’re potentially breaking the semantic of the program. It is particularly dangerous because there is nothing that is going to tell us that we are in this situation “downgrade" situation. #1 means that any code that uses unsafeMath is going to get a performance hit. In other words, one scenario implies generating wrong code and the other, runtime performance regressions. * Feedback Needed * I believe this change is big enough that it would be worth bumping the bitcode version so that the upgrader can do the right thing *before* we release it to the public with LLVM-6.0. That being said, I don’t know what are the implications of such bump and if people really don’t care about the performance problem that might be okay. The silent downgrade path is however concerning. Should we bump the bitcode version because of that change and have the autoupgrader properly rewrite the fast-math flags to preserve the semantic and make sure there are no silent downgrade? Thanks, -Quentin -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180208/88412a27/attachment.html>
via llvm-dev
2018-Feb-09 17:59 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
Hi Quentin,> r317488 changed the way fast math flags are laid out in the bitcode and anyone > compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded > by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially > generate incorrect code w.r.t. fast math expectations. > > Should we bump the bitcode version because of that and have the autoupgrader properly > rewrite the fast-math to preserve that semantic? > (I believe we should!)I agree. Since I was involved in the discussions that motivated the change of r317488, I feel compelled to chime in. The danger you described of a pre-llvm-6.0 compiler compiling llvm-6.0 bitcode with the reassoc bit enabled (but not the entire set of fast-math-flags enabled), incorrectly behaving as though all of fast-math is enabled, is pretty compelling. As an aside, at my employer (Sony), this isn't a critical issue for our product. But that's just because out of an abundance of caution, we only permit LTO using bitcode files built using the same llvm version, irrespective of the bitcode version of the IR. That is, when doing LTO, even if the bitcode version isn't bumped, our llvm-5.0 based compiler will reject llvm-6.0 bitcode, and our llvm-6.0 based compiler will reject llvm-5.0 bitcode. So if there is a strong feeling by others that the possibility of users compiling new bitcode with an older compiler is insignificant, then I won't argue that we must bump the IR version markers. But given your points, it seems to me bumping the bitcode version is the “right thing to do”. And from the discussion at https://reviews.llvm.org/D39304, apparently Michael already has the patch ready, so this can be addressed quickly. Thanks, -Warren From: llvm-dev [mailto:llvm-dev-bounces at lists.llvm.org] On Behalf Of Quentin Colombet via llvm-dev Sent: Thursday, February 8, 2018 5:34 PM To: llvm-dev Cc: Michael Berg Subject: [llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0? Hi, TL;DR r317488 changed the way fast math flags are laid out in the bitcode and anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math expectations. Should we bump the bitcode version because of that and have the autoupgrader properly rewrite the fast-math to preserve that semantic? (I believe we should!) * Context * With https://reviews.llvm.org/D39304 / r317488 we got rid of the umbrella UnsafeMath flag and introduced 3 more flags that better represent the different things that happen under fast-math. From a bitcode perspective, this change looks like this: Before r317488 we had 6 bits that respectively represented: UnsafeMath nnan ninf nsz arcp contract *unset* (The order may not match what is exactly in the bitcode.) After r317488 we had 7 bits that respectively represented: reassoc (-UnsafeMath- is gone) nnan ninf nsz arcp contract *afn* (new bit) Before r317488, fast-math was true if UnsafeMath was true (this should also imply all the other flags are sets). After r317488, fast-math is true if all the bits are set, in particular the afn, new one, too. * Problem * Given we currently have no way to check if a bitcode file has been generated pre-r317488 or post-r317488 that means that: 1. a post-r317488 compiler is going to skip any optimization guarded by isFast for all pre-r317488 bitcode file (remember the afn bit is not set here) 2. a pre-r317488 compiler is going to run any optimization guarded by unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit (remember we repurposed UnsafeMath) Scenario #2 might be unlikely but we’re potentially breaking the semantic of the program. It is particularly dangerous because there is nothing that is going to tell us that we are in this situation “downgrade" situation. #1 means that any code that uses unsafeMath is going to get a performance hit. In other words, one scenario implies generating wrong code and the other, runtime performance regressions. * Feedback Needed * I believe this change is big enough that it would be worth bumping the bitcode version so that the upgrader can do the right thing *before* we release it to the public with LLVM-6.0. That being said, I don’t know what are the implications of such bump and if people really don’t care about the performance problem that might be okay. The silent downgrade path is however concerning. Should we bump the bitcode version because of that change and have the autoupgrader properly rewrite the fast-math flags to preserve the semantic and make sure there are no silent downgrade? Thanks, -Quentin -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180209/536ffc07/attachment.html>
Matthias Braun via llvm-dev
2018-Feb-09 18:05 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
Just wanted to point out part of this even becoming a problem is the use of `isFast()`. There should be warnings against using isFast() and the existing code should be changed to query specific flags instead... - Matthias> On Feb 8, 2018, at 5:34 PM, Quentin Colombet via llvm-dev <llvm-dev at lists.llvm.org> wrote: > > Hi, > > TL;DR > r317488 changed the way fast math flags are laid out in the bitcode and anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math expectations. > > Should we bump the bitcode version because of that and have the autoupgrader properly rewrite the fast-math to preserve that semantic? > (I believe we should!) > > > * Context * > > With https://reviews.llvm.org/D39304 <https://reviews.llvm.org/D39304> / r317488 we got rid of the umbrella UnsafeMath flag and introduced 3 more flags that better represent the different things that happen under fast-math. > > From a bitcode perspective, this change looks like this: > Before r317488 we had 6 bits that respectively represented: > > UnsafeMath > nnan > ninf > nsz > arcp > contract > *unset* > > (The order may not match what is exactly in the bitcode.) > > After r317488 we had 7 bits that respectively represented: > reassoc (-UnsafeMath- is gone) > nnan > ninf > nsz > arcp > contract > *afn* (new bit) > > Before r317488, fast-math was true if UnsafeMath was true (this should also imply all the other flags are sets). After r317488, fast-math is true if all the bits are set, in particular the afn, new one, too. > > > * Problem * > > Given we currently have no way to check if a bitcode file has been generated pre-r317488 or post-r317488 that means that: > 1. a post-r317488 compiler is going to skip any optimization guarded by isFast for all pre-r317488 bitcode file (remember the afn bit is not set here) > 2. a pre-r317488 compiler is going to run any optimization guarded by unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit (remember we repurposed UnsafeMath) > > Scenario #2 might be unlikely but we’re potentially breaking the semantic of the program. It is particularly dangerous because there is nothing that is going to tell us that we are in this situation “downgrade" situation. > #1 means that any code that uses unsafeMath is going to get a performance hit. > > In other words, one scenario implies generating wrong code and the other, runtime performance regressions. > > > * Feedback Needed * > > I believe this change is big enough that it would be worth bumping the bitcode version so that the upgrader can do the right thing *before* we release it to the public with LLVM-6.0. > > That being said, I don’t know what are the implications of such bump and if people really don’t care about the performance problem that might be okay. The silent downgrade path is however concerning. > > Should we bump the bitcode version because of that change and have the autoupgrader properly rewrite the fast-math flags to > preserve the semantic and make sure there are no silent downgrade? > > > Thanks, > -Quentin > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180209/2113d2ac/attachment-0001.html>
Andrew Kelley via llvm-dev
2018-Feb-09 18:07 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
Does the language reference need to be updated? http://llvm.org/docs/LangRef.html#fast-math-flags It still mentions "fast" On Thu, Feb 8, 2018 at 8:34 PM, Quentin Colombet via llvm-dev < llvm-dev at lists.llvm.org> wrote:> Hi, > > TL;DR > r317488 changed the way fast math flags are laid out in the bitcode and > anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the > optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a > llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math > expectations. > > Should we bump the bitcode version because of that and have the > autoupgrader properly rewrite the fast-math to preserve that semantic? > (I believe we should!) > > > * Context * > > With https://reviews.llvm.org/D39304 / r317488 we got rid of the umbrella > UnsafeMath flag and introduced 3 more flags that better represent the > different things that happen under fast-math. > > From a bitcode perspective, this change looks like this: > Before r317488 we had 6 bits that respectively represented: > > UnsafeMath > nnan > ninf > nsz > arcp > contract > *unset* > > (The order may not match what is exactly in the bitcode.) > > After r317488 we had 7 bits that respectively represented: > reassoc (-UnsafeMath- is gone) > nnan > ninf > nsz > arcp > contract > *afn* (new bit) > > Before r317488, fast-math was true if UnsafeMath was true (this should > also imply all the other flags are sets). After r317488, fast-math is true > if all the bits are set, in particular the afn, new one, too. > > > * Problem * > > Given we currently have no way to check if a bitcode file has been > generated pre-r317488 or post-r317488 that means that: > 1. a post-r317488 compiler is going to skip any optimization guarded by > isFast for all pre-r317488 bitcode file (remember the afn bit is not set > here) > 2. a pre-r317488 compiler is going to run any optimization guarded by > unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit > (remember we repurposed UnsafeMath) > > Scenario #2 might be unlikely but we’re potentially breaking the semantic > of the program. It is particularly dangerous because there is nothing that > is going to tell us that we are in this situation “downgrade" situation. > #1 means that any code that uses unsafeMath is going to get a performance > hit. > > In other words, one scenario implies generating wrong code and the other, > runtime performance regressions. > > > * Feedback Needed * > > I believe this change is big enough that it would be worth bumping the > bitcode version so that the upgrader can do the right thing *before* we > release it to the public with LLVM-6.0. > > That being said, I don’t know what are the implications of such bump and > if people really don’t care about the performance problem that might be > okay. The silent downgrade path is however concerning. > > Should we bump the bitcode version because of that change and have the > autoupgrader properly rewrite the fast-math flags to > preserve the semantic and make sure there are no silent downgrade? > > > Thanks, > -Quentin > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180209/0b881b04/attachment.html>
Sanjay Patel via llvm-dev
2018-Feb-09 18:57 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
I agree about isFast(), but determining the minimal subset of flags needed to replace those calls requires some thought. I did start looking at replacing isFast() in the reassociation pass. In theory, we should be able to do those transforms with just 'reassoc' now, but I hit complications with intersecting FMF of different instructions. Conservatively, we could just ask if everything but the new 'afn' is set for folds that do not include mathlib or intrinsic math functions. That could be an alternative to versioning the IR...unless the perf problems are actually caused by not folding mathlib calls now? As I said in D39304, I have no objection to versioning the IR, but I also don't know if there's a cost/downside to that. On Fri, Feb 9, 2018 at 11:05 AM, Matthias Braun via llvm-dev < llvm-dev at lists.llvm.org> wrote:> Just wanted to point out part of this even becoming a problem is the use > of `isFast()`. > There should be warnings against using isFast() and the existing code > should be changed to query specific flags instead... > > - Matthias > > On Feb 8, 2018, at 5:34 PM, Quentin Colombet via llvm-dev < > llvm-dev at lists.llvm.org> wrote: > > Hi, > > TL;DR > r317488 changed the way fast math flags are laid out in the bitcode and > anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the > optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a > llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math > expectations. > > Should we bump the bitcode version because of that and have the > autoupgrader properly rewrite the fast-math to preserve that semantic? > (I believe we should!) > > > * Context * > > With https://reviews.llvm.org/D39304 / r317488 we got rid of the umbrella > UnsafeMath flag and introduced 3 more flags that better represent the > different things that happen under fast-math. > > From a bitcode perspective, this change looks like this: > Before r317488 we had 6 bits that respectively represented: > > UnsafeMath > nnan > ninf > nsz > arcp > contract > *unset* > > (The order may not match what is exactly in the bitcode.) > > After r317488 we had 7 bits that respectively represented: > reassoc (-UnsafeMath- is gone) > nnan > ninf > nsz > arcp > contract > *afn* (new bit) > > Before r317488, fast-math was true if UnsafeMath was true (this should > also imply all the other flags are sets). After r317488, fast-math is true > if all the bits are set, in particular the afn, new one, too. > > > * Problem * > > Given we currently have no way to check if a bitcode file has been > generated pre-r317488 or post-r317488 that means that: > 1. a post-r317488 compiler is going to skip any optimization guarded by > isFast for all pre-r317488 bitcode file (remember the afn bit is not set > here) > 2. a pre-r317488 compiler is going to run any optimization guarded by > unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit > (remember we repurposed UnsafeMath) > > Scenario #2 might be unlikely but we’re potentially breaking the semantic > of the program. It is particularly dangerous because there is nothing that > is going to tell us that we are in this situation “downgrade" situation. > #1 means that any code that uses unsafeMath is going to get a performance > hit. > > In other words, one scenario implies generating wrong code and the other, > runtime performance regressions. > > > * Feedback Needed * > > I believe this change is big enough that it would be worth bumping the > bitcode version so that the upgrader can do the right thing *before* we > release it to the public with LLVM-6.0. > > That being said, I don’t know what are the implications of such bump and > if people really don’t care about the performance problem that might be > okay. The silent downgrade path is however concerning. > > Should we bump the bitcode version because of that change and have the > autoupgrader properly rewrite the fast-math flags to > preserve the semantic and make sure there are no silent downgrade? > > > Thanks, > -Quentin > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > > > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180209/39a7b7f0/attachment.html>
Sanjay Patel via llvm-dev
2018-Feb-09 19:04 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
No, I think that's ok as-is. We still allow 'fast' in IR text as a shortcut meaning all of the other bits are set. It's just encoded differently in binary form. On Fri, Feb 9, 2018 at 11:07 AM, Andrew Kelley via llvm-dev < llvm-dev at lists.llvm.org> wrote:> Does the language reference need to be updated? > > http://llvm.org/docs/LangRef.html#fast-math-flags > > It still mentions "fast" > > > > On Thu, Feb 8, 2018 at 8:34 PM, Quentin Colombet via llvm-dev < > llvm-dev at lists.llvm.org> wrote: > >> Hi, >> >> TL;DR >> r317488 changed the way fast math flags are laid out in the bitcode and >> anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the >> optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a >> llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math >> expectations. >> >> Should we bump the bitcode version because of that and have the >> autoupgrader properly rewrite the fast-math to preserve that semantic? >> (I believe we should!) >> >> >> * Context * >> >> With https://reviews.llvm.org/D39304 / r317488 we got rid of the >> umbrella UnsafeMath flag and introduced 3 more flags that better represent >> the different things that happen under fast-math. >> >> From a bitcode perspective, this change looks like this: >> Before r317488 we had 6 bits that respectively represented: >> >> UnsafeMath >> nnan >> ninf >> nsz >> arcp >> contract >> *unset* >> >> (The order may not match what is exactly in the bitcode.) >> >> After r317488 we had 7 bits that respectively represented: >> reassoc (-UnsafeMath- is gone) >> nnan >> ninf >> nsz >> arcp >> contract >> *afn* (new bit) >> >> Before r317488, fast-math was true if UnsafeMath was true (this should >> also imply all the other flags are sets). After r317488, fast-math is true >> if all the bits are set, in particular the afn, new one, too. >> >> >> * Problem * >> >> Given we currently have no way to check if a bitcode file has been >> generated pre-r317488 or post-r317488 that means that: >> 1. a post-r317488 compiler is going to skip any optimization guarded by >> isFast for all pre-r317488 bitcode file (remember the afn bit is not set >> here) >> 2. a pre-r317488 compiler is going to run any optimization guarded by >> unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit >> (remember we repurposed UnsafeMath) >> >> Scenario #2 might be unlikely but we’re potentially breaking the semantic >> of the program. It is particularly dangerous because there is nothing that >> is going to tell us that we are in this situation “downgrade" situation. >> #1 means that any code that uses unsafeMath is going to get a performance >> hit. >> >> In other words, one scenario implies generating wrong code and the other, >> runtime performance regressions. >> >> >> * Feedback Needed * >> >> I believe this change is big enough that it would be worth bumping the >> bitcode version so that the upgrader can do the right thing *before* we >> release it to the public with LLVM-6.0. >> >> That being said, I don’t know what are the implications of such bump and >> if people really don’t care about the performance problem that might be >> okay. The silent downgrade path is however concerning. >> >> Should we bump the bitcode version because of that change and have the >> autoupgrader properly rewrite the fast-math flags to >> preserve the semantic and make sure there are no silent downgrade? >> >> >> Thanks, >> -Quentin >> >> _______________________________________________ >> LLVM Developers mailing list >> llvm-dev at lists.llvm.org >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >> >> > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180209/3fee1771/attachment.html>
Quentin Colombet via llvm-dev
2018-Feb-09 19:07 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
Agree, but that wouldn’t solve the downgrade problem plus this is probably too late to fix LLVM 6.0 for all the isFast uses.> On Feb 9, 2018, at 10:05 AM, Matthias Braun <mbraun at apple.com> wrote: > > Just wanted to point out part of this even becoming a problem is the use of `isFast()`. > There should be warnings against using isFast() and the existing code should be changed to query specific flags instead... > > - Matthias > >> On Feb 8, 2018, at 5:34 PM, Quentin Colombet via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>> wrote: >> >> Hi, >> >> TL;DR >> r317488 changed the way fast math flags are laid out in the bitcode and anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math expectations. >> >> Should we bump the bitcode version because of that and have the autoupgrader properly rewrite the fast-math to preserve that semantic? >> (I believe we should!) >> >> >> * Context * >> >> With https://reviews.llvm.org/D39304 <https://reviews.llvm.org/D39304> / r317488 we got rid of the umbrella UnsafeMath flag and introduced 3 more flags that better represent the different things that happen under fast-math. >> >> From a bitcode perspective, this change looks like this: >> Before r317488 we had 6 bits that respectively represented: >> >> UnsafeMath >> nnan >> ninf >> nsz >> arcp >> contract >> *unset* >> >> (The order may not match what is exactly in the bitcode.) >> >> After r317488 we had 7 bits that respectively represented: >> reassoc (-UnsafeMath- is gone) >> nnan >> ninf >> nsz >> arcp >> contract >> *afn* (new bit) >> >> Before r317488, fast-math was true if UnsafeMath was true (this should also imply all the other flags are sets). After r317488, fast-math is true if all the bits are set, in particular the afn, new one, too. >> >> >> * Problem * >> >> Given we currently have no way to check if a bitcode file has been generated pre-r317488 or post-r317488 that means that: >> 1. a post-r317488 compiler is going to skip any optimization guarded by isFast for all pre-r317488 bitcode file (remember the afn bit is not set here) >> 2. a pre-r317488 compiler is going to run any optimization guarded by unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit (remember we repurposed UnsafeMath) >> >> Scenario #2 might be unlikely but we’re potentially breaking the semantic of the program. It is particularly dangerous because there is nothing that is going to tell us that we are in this situation “downgrade" situation. >> #1 means that any code that uses unsafeMath is going to get a performance hit. >> >> In other words, one scenario implies generating wrong code and the other, runtime performance regressions. >> >> >> * Feedback Needed * >> >> I believe this change is big enough that it would be worth bumping the bitcode version so that the upgrader can do the right thing *before* we release it to the public with LLVM-6.0. >> >> That being said, I don’t know what are the implications of such bump and if people really don’t care about the performance problem that might be okay. The silent downgrade path is however concerning. >> >> Should we bump the bitcode version because of that change and have the autoupgrader properly rewrite the fast-math flags to >> preserve the semantic and make sure there are no silent downgrade? >> >> >> Thanks, >> -Quentin >> _______________________________________________ >> LLVM Developers mailing list >> llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org> >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180209/d2acebdd/attachment.html>
Mehdi AMINI via llvm-dev
2018-Feb-13 20:34 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
2018-02-08 17:34 GMT-08:00 Quentin Colombet via llvm-dev < llvm-dev at lists.llvm.org>:> Hi, > > TL;DR > r317488 changed the way fast math flags are laid out in the bitcode and > anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the > optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a > llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math > expectations. > > Should we bump the bitcode version because of that and have the > autoupgrader properly rewrite the fast-math to preserve that semantic? > (I believe we should!) > > > * Context * > > With https://reviews.llvm.org/D39304 / r317488 we got rid of the umbrella > UnsafeMath flag and introduced 3 more flags that better represent the > different things that happen under fast-math. > > From a bitcode perspective, this change looks like this: > Before r317488 we had 6 bits that respectively represented: > > UnsafeMath > nnan > ninf > nsz > arcp > contract > *unset* > > (The order may not match what is exactly in the bitcode.) > > After r317488 we had 7 bits that respectively represented: > reassoc (-UnsafeMath- is gone) > nnan > ninf > nsz > arcp > contract > *afn* (new bit) > > Before r317488, fast-math was true if UnsafeMath was true (this should > also imply all the other flags are sets). After r317488, fast-math is true > if all the bits are set, in particular the afn, new one, too. > > > * Problem * > > Given we currently have no way to check if a bitcode file has been > generated pre-r317488 or post-r317488 that means that: > 1. a post-r317488 compiler is going to skip any optimization guarded by > isFast for all pre-r317488 bitcode file (remember the afn bit is not set > here) > 2. a pre-r317488 compiler is going to run any optimization guarded by > unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit > (remember we repurposed UnsafeMath) > > Scenario #2 might be unlikely but we’re potentially breaking the semantic > of the program. It is particularly dangerous because there is nothing that > is going to tell us that we are in this situation “downgrade" situation. > #1 means that any code that uses unsafeMath is going to get a performance > hit. > > In other words, one scenario implies generating wrong code and the other, > runtime performance regressions. >Scenario #1 is unsupported AFAIK, unless I missed something the bitcode is not forward compatible: loading newer bitcode with an older LLVM has never been supported as far I can remember. Scenario #2 is very much like other performance regression when we drop old metadata (i.e. bitcode upgrade isn't performance proof in general but only "best effort", there have been multiple instance of this in the past). Usually IIRC we try not to version the bitcode at all this way (i.e. bitcode does not have a linear versioning that is regularly bumped) but instead make sure the encoding itself allows an easy upgrade. I.e. the encoding of the FMF should have been such that the reader can detect and upgrade to the new IR representation. Now this is too late here I guess, so bumping may be a possible trade-off. What about any bitcode shipped after r317488 but before the version bump? Not worth taking into account because of the short period of time? Best, -- Mehdi> > > * Feedback Needed * > > I believe this change is big enough that it would be worth bumping the > bitcode version so that the upgrader can do the right thing *before* we > release it to the public with LLVM-6.0. > > That being said, I don’t know what are the implications of such bump and > if people really don’t care about the performance problem that might be > okay. The silent downgrade path is however concerning. > > Should we bump the bitcode version because of that change and have the > autoupgrader properly rewrite the fast-math flags to > preserve the semantic and make sure there are no silent downgrade? > > > Thanks, > -Quentin > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180213/4a1263ce/attachment.html>
Michael Berg via llvm-dev
2018-Feb-13 20:41 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
For all who want to participate in the discussion there is a review open now regarding this topic: https://reviews.llvm.org/D43253 <https://reviews.llvm.org/D43253> Regards, Michael> On Feb 13, 2018, at 12:34 PM, Mehdi AMINI <joker.eph at gmail.com> wrote: > > > > 2018-02-08 17:34 GMT-08:00 Quentin Colombet via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>>: > Hi, > > TL;DR > r317488 changed the way fast math flags are laid out in the bitcode and anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math expectations. > > Should we bump the bitcode version because of that and have the autoupgrader properly rewrite the fast-math to preserve that semantic? > (I believe we should!) > > > * Context * > > With https://reviews.llvm.org/D39304 <https://reviews.llvm.org/D39304> / r317488 we got rid of the umbrella UnsafeMath flag and introduced 3 more flags that better represent the different things that happen under fast-math. > > From a bitcode perspective, this change looks like this: > Before r317488 we had 6 bits that respectively represented: > > UnsafeMath > nnan > ninf > nsz > arcp > contract > *unset* > > (The order may not match what is exactly in the bitcode.) > > After r317488 we had 7 bits that respectively represented: > reassoc (-UnsafeMath- is gone) > nnan > ninf > nsz > arcp > contract > *afn* (new bit) > > Before r317488, fast-math was true if UnsafeMath was true (this should also imply all the other flags are sets). After r317488, fast-math is true if all the bits are set, in particular the afn, new one, too. > > > * Problem * > > Given we currently have no way to check if a bitcode file has been generated pre-r317488 or post-r317488 that means that: > 1. a post-r317488 compiler is going to skip any optimization guarded by isFast for all pre-r317488 bitcode file (remember the afn bit is not set here) > 2. a pre-r317488 compiler is going to run any optimization guarded by unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit (remember we repurposed UnsafeMath) > > Scenario #2 might be unlikely but we’re potentially breaking the semantic of the program. It is particularly dangerous because there is nothing that is going to tell us that we are in this situation “downgrade" situation. > #1 means that any code that uses unsafeMath is going to get a performance hit. > > In other words, one scenario implies generating wrong code and the other, runtime performance regressions. > > > > Scenario #1 is unsupported AFAIK, unless I missed something the bitcode is not forward compatible: loading newer bitcode with an older LLVM has never been supported as far I can remember. > > Scenario #2 is very much like other performance regression when we drop old metadata (i.e. bitcode upgrade isn't performance proof in general but only "best effort", there have been multiple instance of this in the past). > > Usually IIRC we try not to version the bitcode at all this way (i.e. bitcode does not have a linear versioning that is regularly bumped) but instead make sure the encoding itself allows an easy upgrade. I.e. the encoding of the FMF should have been such that the reader can detect and upgrade to the new IR representation. > Now this is too late here I guess, so bumping may be a possible trade-off. What about any bitcode shipped after r317488 but before the version bump? Not worth taking into account because of the short period of time? > > Best, > > -- > Mehdi > > > > * Feedback Needed * > > I believe this change is big enough that it would be worth bumping the bitcode version so that the upgrader can do the right thing *before* we release it to the public with LLVM-6.0. > > That being said, I don’t know what are the implications of such bump and if people really don’t care about the performance problem that might be okay. The silent downgrade path is however concerning. > > Should we bump the bitcode version because of that change and have the autoupgrader properly rewrite the fast-math flags to > preserve the semantic and make sure there are no silent downgrade? > > > Thanks, > -Quentin > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org> > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev <http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev> > >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180213/96234a7e/attachment.html>
Quentin Colombet via llvm-dev
2018-Feb-13 21:29 UTC
[llvm-dev] [RFC] Should we bump the bitcode version in LLVM 6.0?
Hi Mehdi,> On Feb 13, 2018, at 12:34 PM, Mehdi AMINI <joker.eph at gmail.com> wrote: > > > > 2018-02-08 17:34 GMT-08:00 Quentin Colombet via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>>: > Hi, > > TL;DR > r317488 changed the way fast math flags are laid out in the bitcode and anyone compiling a pre-llvm-6.0 bitcode with llvm-6.0 will lose all the optimizations guarded by isFast and a pre-llvm-6.0 compiler compiling a llvm-6.0 bitcode will potentially generate incorrect code w.r.t. fast math expectations. > > Should we bump the bitcode version because of that and have the autoupgrader properly rewrite the fast-math to preserve that semantic? > (I believe we should!) > > > * Context * > > With https://reviews.llvm.org/D39304 <https://reviews.llvm.org/D39304> / r317488 we got rid of the umbrella UnsafeMath flag and introduced 3 more flags that better represent the different things that happen under fast-math. > > From a bitcode perspective, this change looks like this: > Before r317488 we had 6 bits that respectively represented: > > UnsafeMath > nnan > ninf > nsz > arcp > contract > *unset* > > (The order may not match what is exactly in the bitcode.) > > After r317488 we had 7 bits that respectively represented: > reassoc (-UnsafeMath- is gone) > nnan > ninf > nsz > arcp > contract > *afn* (new bit) > > Before r317488, fast-math was true if UnsafeMath was true (this should also imply all the other flags are sets). After r317488, fast-math is true if all the bits are set, in particular the afn, new one, too. > > > * Problem * > > Given we currently have no way to check if a bitcode file has been generated pre-r317488 or post-r317488 that means that: > 1. a post-r317488 compiler is going to skip any optimization guarded by isFast for all pre-r317488 bitcode file (remember the afn bit is not set here) > 2. a pre-r317488 compiler is going to run any optimization guarded by unsafeAlgebra for any post-r317488 bitcode file that has the reassoc bit (remember we repurposed UnsafeMath) > > Scenario #2 might be unlikely but we’re potentially breaking the semantic of the program. It is particularly dangerous because there is nothing that is going to tell us that we are in this situation “downgrade" situation. > #1 means that any code that uses unsafeMath is going to get a performance hit. > > In other words, one scenario implies generating wrong code and the other, runtime performance regressions. > > > > Scenario #1 is unsupported AFAIK, unless I missed something the bitcode is not forward compatible: loading newer bitcode with an older LLVM has never been supported as far I can remember.I agree, but we cannot detect that this is the situation we are in and debugging would prove hard. That said, if we say we don’t care, so be it :).> > Scenario #2 is very much like other performance regression when we drop old metadata (i.e. bitcode upgrade isn't performance proof in general but only "best effort", there have been multiple instance of this in the past). > > Usually IIRC we try not to version the bitcode at all this way (i.e. bitcode does not have a linear versioning that is regularly bumped) but instead make sure the encoding itself allows an easy upgrade. I.e. the encoding of the FMF should have been such that the reader can detect and upgrade to the new IR representation. > Now this is too late here I guess, so bumping may be a possible trade-off.Do you think we should do it, or live with the performance drop? I know this performance drop is not acceptable for our use cases, but I don’t want to impose our ruling on this.> What about any bitcode shipped after r317488 but before the version bump? Not worth taking into account because of the short period of time?I was hoping we can ignore that period of time because it was not in any official LLVM release. Best, -Quentin> > Best, > > -- > Mehdi > > > > * Feedback Needed * > > I believe this change is big enough that it would be worth bumping the bitcode version so that the upgrader can do the right thing *before* we release it to the public with LLVM-6.0. > > That being said, I don’t know what are the implications of such bump and if people really don’t care about the performance problem that might be okay. The silent downgrade path is however concerning. > > Should we bump the bitcode version because of that change and have the autoupgrader properly rewrite the fast-math flags to > preserve the semantic and make sure there are no silent downgrade? > > > Thanks, > -Quentin > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org> > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev <http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev>-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180213/47a2bd30/attachment.html>
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