> OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :) > > > > Could you please provide some examples of things that are impossible right now > > > with command lines, how those interact with the TargetMachine, and how you see > > > it being impossible to deal with? > > There's some examples above but I'll give the detail in the morning. It's 11:30pmat the moment :-).> Let's talk through one of your examples here when you write things up. I think > tracing the execution as you see it will be important to coming to a mutual > understanding here. I know that you have a solution that you see is going to > solve the problems you see, but the I think the problems that you and I are seeing > are possibly not the same thing. So let's walk through this execution trace and see > what we can do.ABI Let's start at llvm-mc's main(). It's important to note that llvm-mc does not create a TargetMachine. Here's a sketch of what happens: · Initialize LLVM · Parse the command line · Construct an MCTargetOptions from the flags · Normalize the triple · Construct a llvm::Target o If the triple is not given, we fetch the default o We normalize the triple o We call TargetRegistry::lookupTarget() to get a llvm::Target. § If –march is given, and Triple::getArchTypeForLLVMName() doesn't return Triple::UnknownArch, the new arch this mutates the triple. Otherwise it applies the –march correctly but doesn't change the triple to match. In this way, it's possible to end up with i586-linux-gnu targeting the foobar architecture. · Call createMCRegInfo() · Call createMCAsmInfo() o MipsMCAsmInfo::PointerSize is incorrect for the N32 ABI (should be 4 but gets 8 since it checks for Triple::mips64/mips64el) o MipsMCAsmInfo::CalleeSaveStackSlotSize is incorrect for mips-linux-gnu –mips64 –mabi=64. Since it too checks for Triple::mips64/mips64el o MipsMCAsmInfo::PrivateLabelPrefix and MipsMCAsmInfo::PrivateGlobalPrefix are wrong (currently "$", should be ".L") for N32/N64 but it's possible to fix this. However, O32 should permit "$" in addition to ".L". Even if MipsMCAsmInfo supported multiple prefixes (which is easy enough to add), checking for Triple::mips/mipsel would not yield the correct result on mips64-linux-gnu –mabi=32. · InitMCObjectFileInfo() o FDECFEEncoding is incorrect for N32 (should be sdata4 but gets sdata8 since it checks for Triple::mips64/mips64el) o PersonalityEncoding and TTypeEncoding are correct but only because we don't have a R_MIPS_PC64 relocation yet. If we had such a relocation this would have the same problem as FDECFEEncoding. · createMCInstrInfo() · createMCInstPrinter() · createMCCodeEmitter() · createMCAsmBackend() · If emitting assembly, createMCAsmStreamer() · if emitting object, createMCObjectStreamer() o This in turn calls createObjectWriter() and tells it to emit ELF32/ELF64 objects. This information comes from MipsAsmBackend and ultimately comes from Triple::mips/mipsel vs Triple::mips64/mips64el. This is incorrect for N32 (which should be ELF32 but has Triple::mips64/mips64el) and for mips-linux-gnu –mips64 (which should be ELF32 since it should target O32). · If assembling createMCAsmParser · If disassembling: o createMCRegInfo() (again) o createMCAsmInfo() (again) § This has the same issues as the first call. o createMCDisassembler() Clang does pretty much the same thing as this but additionally has to deal with using the correct default ABI for the given triple. I'll cover this kind of problem in 'CPU Defaults' below. Other places that get ABI information wrong: · AddressSanitizer: Uses Triple::mips64/mips64el to mean the N64 ABI. N32 is a Triple::mips64/mips64el that should behave as the Triple::mips/mipsel cases do. · DataFlowSanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. · MemorySanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. · Many places where hasMips64*() or isGP64bit() are used in the backend. o MSA intrinsic lowering o Legalization configuration o Instruction selection o MipsTargetLowering::getOptimalMemOpType() o And many more. I can provide more detail if you want. Other notables: · RuntimeDyldELF gets it right but only because it can read the ELF headers instead of the Triple. It went down the same road for a while. I'll provide a CodeGen example tomorrow if you want. I'd intended to include one but this email took longer to type up than I expected. Endian Defaults The toolchain is mips-linux-gnu and targets little endian by default. Here's what currently happens: · We parse the triple (mips-linux-gnu) and get Triple::mips · No command line flags modify this · We construct a TargetMachine and all the other objects using this llvm::Triple. · The architecture was Triple::mips so everything configures for big-endian even though the target was supposed to be little endian. CPU Defaults In LLVM, the default CPU is hardcoded to be MIPS32 (in MipsABIInfo::computeTargetABI()). In Clang, the default CPU for this triple is hardcoded to be MIPS32R2 (in mips::getMipsCPUAndABI()) and clang always passes an explicit CPU to the backend via –target-cpu. On Debian, the default CPU for mipsel-linux-gnu is MIPS-II. On Fedora, the default CPU for mipsel-linux-gnu is MIPS32R2. It is not possible to hardcode the default both ways. How would you resolve this conflict? In my opinion, the only choices to resolve this conflict are configure-time options or run-time config files. Configure-time options to select the default CPU is faster to implement and produces a (slightly) faster clang while run-time config files are more flexible but slower to implement and produces a slower clang. To me, configure-time is the sensible short term choice followed by moving to run-time config files once the pressure to achieve an initial release is gone. Now let's consider JIT's. JIT's should default to the host CPU as defined by the host triple so that it generates code for the same target as the rest of the system. There is a reasonable argument that the default CPU should be auto-detected CPU for performance reasons but it may not be possible to auto-detect the CPU in all circumstances. We therefore need a default to fall back on. This default should be the same as the default for the native compiler on this host (MIPS-II for Debian, MIPS32R2 for Fedora). In my opinion, the default CPU is a property of the target platform since the platform specifies the minimum CPU it is intended to run on. Our representation of the target platform is called llvm::Triple so the default CPU belongs in this object. Being in this object means that tools such as clang, or API's such as Target::createTargetMachine() will always get the defaults corresponding to the triple. These defaults, as we discussed above vary according to the OS (MIPS-II on Debian, MIPS32R2 on Fedora). This kind of problem also exists in other forms such as Softfloat vs Hardfloat defaults, NAN1985 vs NAN2008 defaults, default ABIs, etc. Other things to mention MIPS64 is not a fundamentally different architecture from MIPS32. If we had a representation of the ABI in the triple then we wouldn't need Triple::mips64/mips64el. From: Eric Christopher [mailto:echristo at gmail.com] Sent: 23 September 2015 01:34 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org Subject: Re: The Trouble with Triples OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :)> Could you please provide some examples of things that are impossible right now > with command lines, how those interact with the TargetMachine, and how you see > it being impossible to deal with?There's some examples above but I'll give the detail in the morning. It's 11:30pm at the moment :-). Let's talk through one of your examples here when you write things up. I think tracing the execution as you see it will be important to coming to a mutual understanding here. I know that you have a solution that you see is going to solve the problems you see, but the I think the problems that you and I are seeing are possibly not the same thing. So let's walk through this execution trace and see what we can do. Thanks! -eric ________________________________ From: Eric Christopher [echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 22 September 2015 20:40 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples On Thu, Sep 17, 2015 at 6:21 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote: I think we need to take a step further back and re-enter from the right starting point. The thing that's bothering me about the push back so far is that it's trying to discuss and understand the consequences of resolving the core problem while seemingly ignoring the core problem itself. The reason I've been steering everything back to GNU Triple's being ambiguous and inconsistent is because it's the root of all the problems and the fixes to the various issues fall out naturally once this core point has been addressed. *sigh* Here's the line of thought that I'd like people to start with: • Triples don't describe the target. They look like they should, but they don't. They're really just arbitrary strings. Triples are used as a starting point, but no more. • LLVM relies on Triple as a description of the target. It defines the backend to use, the binary format to use, OS and Vendor specific quirks to enable/disable, the default CPU, the default ABI, the endian, and countless other details about the target. These two statements aren't necessarily true in whole. a) We don't use the Triple to fully specify the target. b) We don't use the Triple to fully specify the ABI. c) We don't use the Triple to fully specify the CPU. d) We do use the triple to handle endianness since most, if not all, triples actually bother to encode endianness. e) The rest of the "countless details" may or may not be relevant, you haven't given an example of what you care about. From here on your email relies on all of these assumptions being true. So I'm going to skip past that part and go to where you answer some of my questions. At this point, in the MC layer we have a number of classes that need to know the ABI but lack this information. Our TargetMachine has an accurate TargetTuple object that describes the invariants of the desired target. The desired ABI is an invariant too so why not have it in the TargetTuple which is already plumbed in everywhere we need it? After all, it's a property of the target OS/Environment. If we have the ABI in the TargetTuple, then we don't need any other means to set the ABI, tools can set it up front in the TargetTuple and we don't need any command-line option handling for it in the backend. This isn't sufficient anyways as I don't want to depend on a weird serialization format to deal with something a simple command line can deal with (or you've said this in a way that's confused me). I see you saying you want: -tuple mips-linux-gnu-abio32-el to specify on a command line to, say, llvm-mc or a new assembler interface, or heck, to clang itself, that you want to compile for: -triple mipsel-linux-gnu -mabi=o32 right? Basically? (Bikeshedding of how to actually serialize things aside?) Meanwhile, in clang we have a number of command line options that change the desired target. Let's say we've constructed a Triple and resolved it to TargetTuple (more on that below). We're now processing the –EL option. At the moment, we substitute our mips-linux-gnu triple for a mipsel-linux-gnu triple, construct a Triple object from it and resolve the new Triple to a TargetTuple. But why do we need to bother with that kind of weird hackery when we can simply do Obj.setEndian(Little)? This is what Phase 7 of the plan is about. We end up with a cleaner way to process target changes that, until now, have required weird triple hacking to handle. This is something else I don't understand. Here is the first time you start talking about APIs which is what I'm particularly asking about in my earlier mails. I'd like to see how you plan on changing the TargetMachine and MC level APIs to deal with this. It seems like the Tuple is going to be a way to side-load information around to the MC layer and while I agree that something is necessary there, I don't think that this solution is the right one. (As I said earlier in the thread) I skipped the Triple -> TargetTuple resolution a moment ago and I should address that now. We already know that mapping Triple to TargetTuple is a many to many mapping. One Triple has many possible TargetTuple's depending on the environment. One TargetTuple can be formed from multiple possible Triples. In an ideal world, we'd like to bake in all of these mappings so that one clang binary supports everything. Unfortunately, being a many to many mapping, some of these mappings are mutually exclusive. Note that this isn't a new problem resulting from this project. The problem has always been there but has been ignored until now. To resolve this, we need to provide configure-time and possibly run-time controls for how this conversion is disambiguated. This resolution is performed as early as possible so that the middle/back-ends don't need to know anything about the ambiguity problem. The minute you start talking about configure time controls we've already lost. This, for me, is a non-starter. That said, I'd like to see the examples you think show that things are impossible to deal with in the current architecture. --- To reply more directly to your email: Thanks :)> What can't be done to TargetMachine to avoid this serialization?TargetMachine already has the serialization (see TargetMachine::TargetTriple). We're not doing anything new here. We're simply replacing one object holding faulty information with a new object holding reliable information. This is side stepping my question and making it about Triple. I've specifically said that TargetMachine does not and is not completely dependent upon Triple.> And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options.The data I want to fix is global. I think the bit you may be getting hung up on here is that small portions of this global data can also be overridden at the function level. Those overrides aren't a problem and continue to operate in the same way as they do today. Examples please.> And one more: What global options do we need to consider here?I'm not certain I understand this question. If you're talking command line options, it's things like –EL, -EB, -mips32, -mips32r[2356], -mips64, -mips64r[2356], -mabi=…. If you're talking about Triple -> TargetTuple mappings, there's quite a wide variety but the main ones for Mips are endian, architecture, default CPU, and default ABI. All of these are representable right now in the TargetMachine as far as I can tell. What examples are you having problems with?> The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. > This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of > everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part > of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM > were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults > as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some > of the handling there during the TargetSubtargetInfo work.I generally agree with this. The key bit I need to draw attention to is that the 'defaults' don't change, but are instead overridden. These constant defaults are stored in TargetMachine and particularly TargetMachine::TargetTriple. These defaults are wrong for some toolchains since the information stored in TargetMachine::TargetTriple are wrong. It's the defaults I'm trying to fix rather than the overrides. I don't understand what you mean here. I think I understand your proposed plan now and it's a few steps ahead of where we are and where we need to be. I agree that overridable state should be in TargetSubtargetInfo, however I can't initialize that state without the default values which come from the faulty information in TargetMachine::TargetTriple. This triple work is a pre-requisite to your plan and at first I don't need to override ABI's. Can you provide an example of using a tool that you're having problems with?> Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. > I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems > with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree > with some of the directions you're headed - I just don't see the unification and interactions right now.I think we'll end up with TargetTuple taking over many arguments to TargetMachine but that's not my goal at this stage. My goal is simply to fix the faulty information currently held in Triple and use the now-accurate information in TargetTuple to fix various blocking issues that prevent a proper Mips toolchain product based on Clang/LLVM. At the end of Phase 7, it become possible to fix a number of issues that are impossible to fix right now because the available data we can consult at the moment is incorrect. Could you please provide some examples of things that are impossible right now with command lines, how those interact with the TargetMachine, and how you see it being impossible to deal with? Thanks -eric From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 16 September 2015 23:52 To: Renato Golin; Jim Grosbach Cc: Daniel Sanders; llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples Let's take a step back here. It appears that you and Daniel are trying to solve some problems. I think solving problems is good, I just want to make sure that we're solving them in a way that gets us a decent API at the end. I also want to make sure we're solving the right problems. TargetTuple appears to be related to the TargetParser as you bring up in this mail. They're two separate parts of similar problems - people trying to both serialize command line options and communication from the front end to the backend with respect to target information. This leads me to a question: What can't be done to TargetMachine to avoid this serialization? And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options. And one more: What global options do we need to consider here? The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some of the handling there during the TargetSubtargetInfo work. Now a bit more on TargetParser + TargetTuple: TargetParser appears to be trying to solve the parsing in Triple in a nice way for ARM and also some of the "what kind of subtarget feature canonicalization can we do in llvm that makes sense to communicate to the front end". I like this particular idea and have often wanted a library of feature handling, but it seems to have stabilized at an ARM specific set of code with no defined interface. I can't even figure out how I'd use it in lib/Basic right now for any target other than ARM. This isn't a condemnation of TargetParser, but I think it's something that needs to be thought through a bit more. It's been hooked up well before I'd expected it to and right now if we moved it to the ARM backend from Support it'd make just as much sense as it does where it is now other than making clang depend on the ARM backend as well as the X86 backend :) Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree with some of the directions you're headed - I just don't see the unification and interactions right now. As a suggestion as a way forward here let's see if we can get my questions above answered and also show some of how the interactions between llvm's libraries are going to get fixed, moved to a better place, etc here. Thanks! -eric On Wed, Sep 16, 2015 at 3:02 PM Renato Golin <renato.golin at linaro.org<mailto:renato.golin at linaro.org>> wrote: On 16 September 2015 at 21:56, Jim Grosbach <grosbach at apple.com<mailto:grosbach at apple.com>> wrote:> Why do we care about GAS? We have an assembler.It's not that simple. There are a lot of old code out there, including the Linux kernel which we do care a lot, that only compiles with GAS. We're slowly moving the legacy code up to modern standards, and specifically some kernel folks are happy to move up not only the asm syntax, but the C standard and move away from GNU-specific behaviour. But we're not quite there yet, and might not be for a few more years. so, yes, we still care about GAS. But this is not just about GAS. As I said on my previous email, this is about clearing the bloat in target descriptions by both: removing the need for adding numerous CPU names, target features, architecture names (xscale, strongarm, etc), AND making sure all parties (front/middle/back-ends) speak the same language, produced from the same source. The TargetTuple is that common language, and the TargetParser created from the TableGen files is the common source. The Triple becomes a legacy constructor value for the Tuple. All other target information classes are already (or should be) generated from the TableGen files, so the ultimate source becomes the TableGen description, which I think it what you were aiming to on your comment. For simple architectures, like x86, you don't even need a TargetParser. You can easily construct the Tuple from a triple and use the Tuple as you've always used the triple. No harm done. But for the complex ones like ARM and MIPS, having a common interface generated from the same place the other interfaces are is important to avoid more bridges between front and middle and back end interpretations of the same target. Whatever legacy ARM or MIPS carry can be isolated in their own implementation, leaving the rest of the targets with a clean and simple interface. cheers, --renato -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20150923/29a6a8a4/attachment-0001.html>
On Wed, Sep 23, 2015 at 11:38 AM Daniel Sanders <Daniel.Sanders at imgtec.com> wrote:> > OK, I'm going to just reply to the last because I think it's the most > important part of all this and would like to try to have us side tracked > again. If you'd like I can reply to it, but let's take the last part first > :) > > > > > > > Could you please provide some examples of things that are impossible > right now > > > > with command lines, how those interact with the TargetMachine, and > how you see > > > > it being impossible to deal with? > > > There's some examples above but I'll give the detail in the morning. > It's 11:30pm > at the moment :-). > > Let's talk through one of your examples here when you write things up. > I think > > tracing the execution as you see it will be important to coming to a > mutual > > understanding here. I know that you have a solution that you see is > going to > > solve the problems you see, but the I think the problems that you and I > are seeing > > are possibly not the same thing. So let's walk through this execution > trace and see > > what we can do. > > *ABI* > > > > Let's start at llvm-mc's main(). It's important to note that llvm-mc does > not create a TargetMachine. Here's a sketch of what happens: >So, we can just stop here. A couple problems: a) llvm-mc isn't a supported product, but that's not the real issue. b) The lack of a TargetMachine at the MC level was something I brought up a long time ago in this thread with my proposed solutions. This is what needs to be fixed, especially given that targets can switch ISA, ABI, floating point, etc within a single assemble action. I even brought up a lot of these problems originally when I was fixing MIPS to work with the current subtarget rewrite. -eric> · Initialize LLVM > > · Parse the command line > > · Construct an MCTargetOptions from the flags > > · Normalize the triple > > · Construct a llvm::Target > > o If the triple is not given, we fetch the default > > o We normalize the triple > > o We call TargetRegistry::lookupTarget() to get a llvm::Target. > > § If –march is given, and Triple::getArchTypeForLLVMName() doesn't > return Triple::UnknownArch, the new arch this mutates the triple. Otherwise > it applies the –march correctly but doesn't change the triple to match. In > this way, it's possible to end up with i586-linux-gnu targeting the foobar > architecture. > > · Call createMCRegInfo() > > · Call createMCAsmInfo() > > o MipsMCAsmInfo::PointerSize is incorrect for the N32 ABI (should be 4 > but gets 8 since it checks for Triple::mips64/mips64el) > > o MipsMCAsmInfo::CalleeSaveStackSlotSize is incorrect for > mips-linux-gnu –mips64 –mabi=64. Since it too checks for > Triple::mips64/mips64el > > o MipsMCAsmInfo::PrivateLabelPrefix and > MipsMCAsmInfo::PrivateGlobalPrefix are wrong (currently "$", should be > ".L") for N32/N64 but it's possible to fix this. However, O32 should permit > "$" in addition to ".L". Even if MipsMCAsmInfo supported multiple prefixes > (which is easy enough to add), checking for Triple::mips/mipsel would not > yield the correct result on mips64-linux-gnu –mabi=32. > > · InitMCObjectFileInfo() > > o FDECFEEncoding is incorrect for N32 (should be sdata4 but gets sdata8 > since it checks for Triple::mips64/mips64el) > > o PersonalityEncoding and TTypeEncoding are correct but only because we > don't have a R_MIPS_PC64 relocation yet. If we had such a relocation this > would have the same problem as FDECFEEncoding. > > · createMCInstrInfo() > > · createMCInstPrinter() > > · createMCCodeEmitter() > > · createMCAsmBackend() > > · If emitting assembly, createMCAsmStreamer() > > · if emitting object, createMCObjectStreamer() > > o This in turn calls createObjectWriter() and tells it to emit > ELF32/ELF64 objects. This information comes from MipsAsmBackend and > ultimately comes from Triple::mips/mipsel vs Triple::mips64/mips64el. This > is incorrect for N32 (which should be ELF32 but has > Triple::mips64/mips64el) and for mips-linux-gnu –mips64 (which should be > ELF32 since it should target O32). > > · If assembling createMCAsmParser > > · If disassembling: > > o createMCRegInfo() (again) > > o createMCAsmInfo() (again) > > § This has the same issues as the first call. > > o createMCDisassembler() > > Clang does pretty much the same thing as this but additionally has to deal > with using the correct default ABI for the given triple. I'll cover this > kind of problem in 'CPU Defaults' below. > > > > Other places that get ABI information wrong: > > · AddressSanitizer: Uses Triple::mips64/mips64el to mean the N64 > ABI. N32 is a Triple::mips64/mips64el that should behave as the > Triple::mips/mipsel cases do. > > · DataFlowSanitizer: Is heading down the same road but hasn't > implemented O32/N32 yet. > > · MemorySanitizer: Is heading down the same road but hasn't > implemented O32/N32 yet. > > · Many places where hasMips64*() or isGP64bit() are used in the > backend. > > o MSA intrinsic lowering > > o Legalization configuration > > o Instruction selection > > o MipsTargetLowering::getOptimalMemOpType() > > o And many more. I can provide more detail if you want. > > > > Other notables: > > · RuntimeDyldELF gets it right but only because it can read the > ELF headers instead of the Triple. It went down the same road for a while. > > > > I'll provide a CodeGen example tomorrow if you want. I'd intended to > include one but this email took longer to type up than I expected. > > > > *Endian Defaults* > > > > The toolchain is mips-linux-gnu and targets little endian by default. > Here's what currently happens: > > · We parse the triple (mips-linux-gnu) and get Triple::mips > > · No command line flags modify this > > · We construct a TargetMachine and all the other objects using > this llvm::Triple. > > · The architecture was Triple::mips so everything configures for > big-endian even though the target was supposed to be little endian. > > > > *CPU Defaults* > > > > In LLVM, the default CPU is hardcoded to be MIPS32 (in > MipsABIInfo::computeTargetABI()). In Clang, the default CPU for this triple > is hardcoded to be MIPS32R2 (in mips::getMipsCPUAndABI()) and clang always > passes an explicit CPU to the backend via –target-cpu. > > > > On Debian, the default CPU for mipsel-linux-gnu is MIPS-II. On Fedora, the > default CPU for mipsel-linux-gnu is MIPS32R2. It is not possible to > hardcode the default both ways. > > How would you resolve this conflict? > > > > In my opinion, the only choices to resolve this conflict are > configure-time options or run-time config files. Configure-time options to > select the default CPU is faster to > > implement and produces a (slightly) faster clang while run-time config > files are more flexible but slower to implement and produces a slower > clang. To me, configure-time is the > > sensible short term choice followed by moving to run-time config files > once the pressure to achieve an initial release is gone. > > > > Now let's consider JIT's. JIT's should default to the host CPU as defined > by the host triple so that it generates code for the same target as the > rest of the system. There is a reasonable argument that the default CPU > should be auto-detected CPU for performance reasons but it may not be > possible to auto-detect the CPU in all circumstances. We therefore need a > default to fall back on. This default should be the same as the default for > the native compiler on this host (MIPS-II for Debian, MIPS32R2 for Fedora). > > > > In my opinion, the default CPU is a property of the target platform since > the platform specifies the minimum CPU it is intended to run on. Our > representation of the target platform is called llvm::Triple so the default > CPU belongs in this object. Being in this object means that tools such as > clang, or API's such as Target::createTargetMachine() will always get the > defaults corresponding to the triple. These defaults, as we discussed above > vary according to the OS (MIPS-II on Debian, MIPS32R2 on Fedora). > > > > This kind of problem also exists in other forms such as Softfloat vs > Hardfloat defaults, NAN1985 vs NAN2008 defaults, default ABIs, etc. > > > > *Other things to mention* > > > > MIPS64 is not a fundamentally different architecture from MIPS32. If we > had a representation of the ABI in the triple then we wouldn't need > Triple::mips64/mips64el. > > > > *From:* Eric Christopher [mailto:echristo at gmail.com] > *Sent:* 23 September 2015 01:34 > > > *To:* Daniel Sanders; Renato Golin; Jim Grosbach > *Cc:* llvm-dev at lists.llvm.org > *Subject:* Re: The Trouble with Triples > > > > OK, I'm going to just reply to the last because I think it's the most > important part of all this and would like to try to have us side tracked > again. If you'd like I can reply to it, but let's take the last part first > :) > > > > > Could you please provide some examples of things that are impossible > right now > > with command lines, how those interact with the TargetMachine, and how > you see > > it being impossible to deal with? > > There's some examples above but I'll give the detail in the morning. It's > 11:30pm > at the moment :-). > > > > Let's talk through one of your examples here when you write things up. I > think tracing the execution as you see it will be important to coming to a > mutual understanding here. I know that you have a solution that you see is > going to solve the problems you see, but the I think the problems that you > and I are seeing are possibly not the same thing. So let's walk through > this execution trace and see what we can do. > > > > Thanks! > > > > -eric > > > > ------------------------------ > > *From:* Eric Christopher [echristo at gmail.com] > *Sent:* 22 September 2015 20:40 > *To:* Daniel Sanders; Renato Golin; Jim Grosbach > *Cc:* llvm-dev at lists.llvm.org > > > *Subject:* Re: The Trouble with Triples > > > > On Thu, Sep 17, 2015 at 6:21 AM Daniel Sanders <Daniel.Sanders at imgtec.com> > wrote: > > I think we need to take a step further back and re-enter from the right > starting point. The thing that's bothering me about the push back so far is > that it's trying to discuss and understand the consequences of resolving > the core problem while seemingly ignoring the core problem itself. The > reason I've been steering everything back to GNU Triple's being ambiguous > and inconsistent is because it's the root of all the problems and the fixes > to the various issues fall out naturally once this core point has been > addressed. > > > > *sigh* > > > > > > Here's the line of thought that I'd like people to start with: > > · Triples don't describe the target. They look like they should, > but they don't. They're really just arbitrary strings. > > > > Triples are used as a starting point, but no more. > > > > · LLVM relies on Triple as a description of the target. It > defines the backend to use, the binary format to use, OS and Vendor > specific quirks to enable/disable, the default CPU, the default ABI, the > endian, and countless other details about the target. > > > > These two statements aren't necessarily true in whole. > > > > a) We don't use the Triple to fully specify the target. > > b) We don't use the Triple to fully specify the ABI. > > c) We don't use the Triple to fully specify the CPU. > > d) We do use the triple to handle endianness since most, if not all, > triples actually bother to encode endianness. > > e) The rest of the "countless details" may or may not be relevant, you > haven't given an example of what you care about. > > > > From here on your email relies on all of these assumptions being true. So > I'm going to skip past that part and go to where you answer some of my > questions. > > At this point, in the MC layer we have a number of classes that need to > know the ABI but lack this information. Our TargetMachine has an accurate > TargetTuple object that describes the invariants of the desired target. The > desired ABI is an invariant too so why not have it in the TargetTuple which > is already plumbed in everywhere we need it? After all, it's a property of > the target OS/Environment. If we have the ABI in the TargetTuple, then we > don't need any other means to set the ABI, tools can set it up front in the > TargetTuple and we don't need any command-line option handling for it in > the backend. > > > > This isn't sufficient anyways as I don't want to depend on a weird > serialization format to deal with something a simple command line can deal > with (or you've said this in a way that's confused me). I see you saying > you want: > > > > -tuple mips-linux-gnu-abio32-el > > > > to specify on a command line to, say, llvm-mc or a new assembler > interface, or heck, to clang itself, that you want to compile for: > > > > -triple mipsel-linux-gnu -mabi=o32 > > > > right? Basically? (Bikeshedding of how to actually serialize things aside?) > > > > Meanwhile, in clang we have a number of command line options that change > the desired target. Let's say we've constructed a Triple and resolved it to > TargetTuple (more on that below). We're now processing the –EL option. At > the moment, we substitute our mips-linux-gnu triple for a mipsel-linux-gnu > triple, construct a Triple object from it and resolve the new Triple to a > TargetTuple. But why do we need to bother with that kind of weird hackery > when we can simply do Obj.setEndian(Little)? This is what Phase 7 of the > plan is about. We end up with a cleaner way to process target changes that, > until now, have required weird triple hacking to handle. > > > > > > This is something else I don't understand. Here is the first time you > start talking about APIs which is what I'm particularly asking about in my > earlier mails. I'd like to see how you plan on changing the TargetMachine > and MC level APIs to deal with this. It seems like the Tuple is going to be > a way to side-load information around to the MC layer and while I agree > that something is necessary there, I don't think that this solution is the > right one. (As I said earlier in the thread) > > > > I skipped the Triple -> TargetTuple resolution a moment ago and I should > address that now. We already know that mapping Triple to TargetTuple is a > many to many mapping. One Triple has many possible TargetTuple's depending > on the environment. One TargetTuple can be formed from multiple possible > Triples. In an ideal world, we'd like to bake in all of these mappings so > that one clang binary supports everything. Unfortunately, being a many to > many mapping, some of these mappings are mutually exclusive. Note that this > isn't a new problem resulting from this project. The problem has always > been there but has been ignored until now. To resolve this, we need to > provide configure-time and possibly run-time controls for how this > conversion is disambiguated. This resolution is performed as early as > possible so that the middle/back-ends don't need to know anything about the > ambiguity problem. > > > > The minute you start talking about configure time controls we've already > lost. This, for me, is a non-starter. That said, I'd like to see the > examples you think show that things are impossible to deal with in the > current architecture. > > > > --- > > > > To reply more directly to your email: > > > > Thanks :) > > > > > What can't be done to TargetMachine to avoid this serialization? > > > > TargetMachine already has the serialization (see > TargetMachine::TargetTriple). We're not doing anything new here. We're > simply replacing one object holding faulty information with a new object > holding reliable information. > > > > > > This is side stepping my question and making it about Triple. I've > specifically said that TargetMachine does not and is not completely > dependent upon Triple. > > > > > And a followup question: What can't be serialized at the function level > in the IR to make certain things clear that aren't global? We already do > this for a lot of command line options. > > > > The data I want to fix is global. I think the bit you may be getting hung > up on here is that small portions of this global data can also be > overridden at the function level. Those overrides aren't a problem and > continue to operate in the same way as they do today. > > > > Examples please. > > > > > And one more: What global options do we need to consider here? > > > > I'm not certain I understand this question. If you're talking command line > options, it's things like –EL, -EB, -mips32, -mips32r[2356], -mips64, > -mips64r[2356], -mabi=…. If you're talking about Triple -> TargetTuple > mappings, there's quite a wide variety but the main ones for Mips are > endian, architecture, default CPU, and default ABI. > > > > All of these are representable right now in the TargetMachine as far as I > can tell. What examples are you having problems with? > > > > > > > The goal of the configuration level of the TargetMachine is that it > controls things that don't change at the object level. > > > This is a fairly recently stated goal, but I think it makes sense for > LLVM in general. TargetSubtargetInfo takes care of > > > everything that resides under this (as much as possible, some bits are > still in transition, e.g. TargetOptions). This is part > > > of my suggestion to Daniel about the problems with MCSubtargetInfo and > the assembler. Targets like Mips and ARM > > > were unfortunately designed to change things on the fly during assembly > and need to collate or at least change defaults > > > as we're processing code. I definitely had to deal with a lot of the > pain you're talking about when I was rewriting some > > > of the handling there during the TargetSubtargetInfo work. > > > > I generally agree with this. The key bit I need to draw attention to is > that the 'defaults' don't change, but are instead overridden. These > constant defaults are stored in TargetMachine and particularly > TargetMachine::TargetTriple. These defaults are wrong for some toolchains > since the information stored in TargetMachine::TargetTriple are wrong. It's > the defaults I'm trying to fix rather than the overrides. > > > > > > I don't understand what you mean here. > > > > I think I understand your proposed plan now and it's a few steps ahead of > where we are and where we need to be. I agree that overridable state should > be in TargetSubtargetInfo, however I can't initialize that state without > the default values which come from the faulty information in > TargetMachine::TargetTriple. This triple work is a pre-requisite to your > plan and at first I don't need to override ABI's. > > > > > > Can you provide an example of using a tool that you're having problems > with? > > > > > Right now I see TargetTuple as trying to take over all of the various > arguments to TargetMachine and encapsulate them into a single thing. > > > I also don't see this is bad, but I also don't see it taking all of them > right now and I'm not sure how it solves some of the existing problems > > > with data sharing that we've got which is where the push back you're > both getting is coming from here. Ultimately library-wise I can agree > > > with some of the directions you're headed - I just don't see the > unification and interactions right now. > > > > I think we'll end up with TargetTuple taking over many arguments to > TargetMachine but that's not my goal at this stage. My goal is simply to > fix the faulty information currently held in Triple and use the > now-accurate information in TargetTuple to fix various blocking issues that > prevent a proper Mips toolchain product based on Clang/LLVM. At the end of > Phase 7, it become possible to fix a number of issues that are impossible > to fix right now because the available data we can consult at the moment is > incorrect. > > > > > > Could you please provide some examples of things that are impossible right > now with command lines, how those interact with the TargetMachine, and how > you see it being impossible to deal with? > > > > Thanks > > > > -eric > > > > > > *From:* Eric Christopher [mailto:echristo at gmail.com] > *Sent:* 16 September 2015 23:52 > *To:* Renato Golin; Jim Grosbach > *Cc:* Daniel Sanders; llvm-dev at lists.llvm.org > > > *Subject:* Re: The Trouble with Triples > > > > Let's take a step back here. > > > > It appears that you and Daniel are trying to solve some problems. I think > solving problems is good, I just want to make sure that we're solving them > in a way that gets us a decent API at the end. I also want to make sure > we're solving the right problems. > > > > TargetTuple appears to be related to the TargetParser as you bring up in > this mail. They're two separate parts of similar problems - people trying > to both serialize command line options and communication from the front end > to the backend with respect to target information. > > > > This leads me to a question: What can't be done to TargetMachine to avoid > this serialization? > > And a followup question: What can't be serialized at the function level in > the IR to make certain things clear that aren't global? We already do this > for a lot of command line options. > > And one more: What global options do we need to consider here? > > > > The goal of the configuration level of the TargetMachine is that it > controls things that don't change at the object level. This is a fairly > recently stated goal, but I think it makes sense for LLVM in general. > TargetSubtargetInfo takes care of everything that resides under this (as > much as possible, some bits are still in transition, e.g. TargetOptions). > This is part of my suggestion to Daniel about the problems with > MCSubtargetInfo and the assembler. Targets like Mips and ARM were > unfortunately designed to change things on the fly during assembly and need > to collate or at least change defaults as we're processing code. I > definitely had to deal with a lot of the pain you're talking about when I > was rewriting some of the handling there during the TargetSubtargetInfo > work. > > > > Now a bit more on TargetParser + TargetTuple: > > > > TargetParser appears to be trying to solve the parsing in Triple in a nice > way for ARM and also some of the "what kind of subtarget feature > canonicalization can we do in llvm that makes sense to communicate to the > front end". I like this particular idea and have often wanted a library of > feature handling, but it seems to have stabilized at an ARM specific set of > code with no defined interface. I can't even figure out how I'd use it in > lib/Basic right now for any target other than ARM. This isn't a > condemnation of TargetParser, but I think it's something that needs to be > thought through a bit more. It's been hooked up well before I'd expected it > to and right now if we moved it to the ARM backend from Support it'd make > just as much sense as it does where it is now other than making clang > depend on the ARM backend as well as the X86 backend :) > > > > Right now I see TargetTuple as trying to take over all of the various > arguments to TargetMachine and encapsulate them into a single thing. I also > don't see this is bad, but I also don't see it taking all of them right now > and I'm not sure how it solves some of the existing problems with data > sharing that we've got which is where the push back you're both getting is > coming from here. Ultimately library-wise I can agree with some of the > directions you're headed - I just don't see the unification and > interactions right now. > > > > As a suggestion as a way forward here let's see if we can get my questions > above answered and also show some of how the interactions between llvm's > libraries are going to get fixed, moved to a better place, etc here. > > > > Thanks! > > > > -eric > > > > > > On Wed, Sep 16, 2015 at 3:02 PM Renato Golin <renato.golin at linaro.org> > wrote: > > On 16 September 2015 at 21:56, Jim Grosbach <grosbach at apple.com> wrote: > > Why do we care about GAS? We have an assembler. > > It's not that simple. > > There are a lot of old code out there, including the Linux kernel > which we do care a lot, that only compiles with GAS. We're slowly > moving the legacy code up to modern standards, and specifically some > kernel folks are happy to move up not only the asm syntax, but the C > standard and move away from GNU-specific behaviour. But we're not > quite there yet, and might not be for a few more years. so, yes, we > still care about GAS. > > But this is not just about GAS. > > As I said on my previous email, this is about clearing the bloat in > target descriptions by both: removing the need for adding numerous CPU > names, target features, architecture names (xscale, strongarm, etc), > AND making sure all parties (front/middle/back-ends) speak the same > language, produced from the same source. > > The TargetTuple is that common language, and the TargetParser created > from the TableGen files is the common source. The Triple becomes a > legacy constructor value for the Tuple. All other target information > classes are already (or should be) generated from the TableGen files, > so the ultimate source becomes the TableGen description, which I think > it what you were aiming to on your comment. > > For simple architectures, like x86, you don't even need a > TargetParser. You can easily construct the Tuple from a triple and use > the Tuple as you've always used the triple. No harm done. But for the > complex ones like ARM and MIPS, having a common interface generated > from the same place the other interfaces are is important to avoid > more bridges between front and middle and back end interpretations of > the same target. Whatever legacy ARM or MIPS carry can be isolated in > their own implementation, leaving the rest of the targets with a clean > and simple interface. > > cheers, > --renato > >-------------- next part -------------- An HTML attachment was scrubbed... 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Could you address the other problems being discussed as well? It's not just the MC layer we're dealing with here. ________________________________ From: Eric Christopher [echristo at gmail.com] Sent: 23 September 2015 19:49 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org Subject: Re: The Trouble with Triples On Wed, Sep 23, 2015 at 11:38 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote:> OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :) > > > > Could you please provide some examples of things that are impossible right now > > > with command lines, how those interact with the TargetMachine, and how you see > > > it being impossible to deal with? > > There's some examples above but I'll give the detail in the morning. It's 11:30pmat the moment :-).> Let's talk through one of your examples here when you write things up. I think > tracing the execution as you see it will be important to coming to a mutual > understanding here. I know that you have a solution that you see is going to > solve the problems you see, but the I think the problems that you and I are seeing > are possibly not the same thing. So let's walk through this execution trace and see > what we can do.ABI Let's start at llvm-mc's main(). It's important to note that llvm-mc does not create a TargetMachine. Here's a sketch of what happens: So, we can just stop here. A couple problems: a) llvm-mc isn't a supported product, but that's not the real issue. b) The lack of a TargetMachine at the MC level was something I brought up a long time ago in this thread with my proposed solutions. This is what needs to be fixed, especially given that targets can switch ISA, ABI, floating point, etc within a single assemble action. I even brought up a lot of these problems originally when I was fixing MIPS to work with the current subtarget rewrite. -eric • Initialize LLVM • Parse the command line • Construct an MCTargetOptions from the flags • Normalize the triple • Construct a llvm::Target o If the triple is not given, we fetch the default o We normalize the triple o We call TargetRegistry::lookupTarget() to get a llvm::Target. • If –march is given, and Triple::getArchTypeForLLVMName() doesn't return Triple::UnknownArch, the new arch this mutates the triple. Otherwise it applies the –march correctly but doesn't change the triple to match. In this way, it's possible to end up with i586-linux-gnu targeting the foobar architecture. • Call createMCRegInfo() • Call createMCAsmInfo() o MipsMCAsmInfo::PointerSize is incorrect for the N32 ABI (should be 4 but gets 8 since it checks for Triple::mips64/mips64el) o MipsMCAsmInfo::CalleeSaveStackSlotSize is incorrect for mips-linux-gnu –mips64 –mabi=64. Since it too checks for Triple::mips64/mips64el o MipsMCAsmInfo::PrivateLabelPrefix and MipsMCAsmInfo::PrivateGlobalPrefix are wrong (currently "$", should be ".L") for N32/N64 but it's possible to fix this. However, O32 should permit "$" in addition to ".L". Even if MipsMCAsmInfo supported multiple prefixes (which is easy enough to add), checking for Triple::mips/mipsel would not yield the correct result on mips64-linux-gnu –mabi=32. • InitMCObjectFileInfo() o FDECFEEncoding is incorrect for N32 (should be sdata4 but gets sdata8 since it checks for Triple::mips64/mips64el) o PersonalityEncoding and TTypeEncoding are correct but only because we don't have a R_MIPS_PC64 relocation yet. If we had such a relocation this would have the same problem as FDECFEEncoding. • createMCInstrInfo() • createMCInstPrinter() • createMCCodeEmitter() • createMCAsmBackend() • If emitting assembly, createMCAsmStreamer() • if emitting object, createMCObjectStreamer() o This in turn calls createObjectWriter() and tells it to emit ELF32/ELF64 objects. This information comes from MipsAsmBackend and ultimately comes from Triple::mips/mipsel vs Triple::mips64/mips64el. This is incorrect for N32 (which should be ELF32 but has Triple::mips64/mips64el) and for mips-linux-gnu –mips64 (which should be ELF32 since it should target O32). • If assembling createMCAsmParser • If disassembling: o createMCRegInfo() (again) o createMCAsmInfo() (again) • This has the same issues as the first call. o createMCDisassembler() Clang does pretty much the same thing as this but additionally has to deal with using the correct default ABI for the given triple. I'll cover this kind of problem in 'CPU Defaults' below. Other places that get ABI information wrong: • AddressSanitizer: Uses Triple::mips64/mips64el to mean the N64 ABI. N32 is a Triple::mips64/mips64el that should behave as the Triple::mips/mipsel cases do. • DataFlowSanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. • MemorySanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. • Many places where hasMips64*() or isGP64bit() are used in the backend. o MSA intrinsic lowering o Legalization configuration o Instruction selection o MipsTargetLowering::getOptimalMemOpType() o And many more. I can provide more detail if you want. Other notables: • RuntimeDyldELF gets it right but only because it can read the ELF headers instead of the Triple. It went down the same road for a while. I'll provide a CodeGen example tomorrow if you want. I'd intended to include one but this email took longer to type up than I expected. Endian Defaults The toolchain is mips-linux-gnu and targets little endian by default. Here's what currently happens: • We parse the triple (mips-linux-gnu) and get Triple::mips • No command line flags modify this • We construct a TargetMachine and all the other objects using this llvm::Triple. • The architecture was Triple::mips so everything configures for big-endian even though the target was supposed to be little endian. CPU Defaults In LLVM, the default CPU is hardcoded to be MIPS32 (in MipsABIInfo::computeTargetABI()). In Clang, the default CPU for this triple is hardcoded to be MIPS32R2 (in mips::getMipsCPUAndABI()) and clang always passes an explicit CPU to the backend via –target-cpu. On Debian, the default CPU for mipsel-linux-gnu is MIPS-II. On Fedora, the default CPU for mipsel-linux-gnu is MIPS32R2. It is not possible to hardcode the default both ways. How would you resolve this conflict? In my opinion, the only choices to resolve this conflict are configure-time options or run-time config files. Configure-time options to select the default CPU is faster to implement and produces a (slightly) faster clang while run-time config files are more flexible but slower to implement and produces a slower clang. To me, configure-time is the sensible short term choice followed by moving to run-time config files once the pressure to achieve an initial release is gone. Now let's consider JIT's. JIT's should default to the host CPU as defined by the host triple so that it generates code for the same target as the rest of the system. There is a reasonable argument that the default CPU should be auto-detected CPU for performance reasons but it may not be possible to auto-detect the CPU in all circumstances. We therefore need a default to fall back on. This default should be the same as the default for the native compiler on this host (MIPS-II for Debian, MIPS32R2 for Fedora). In my opinion, the default CPU is a property of the target platform since the platform specifies the minimum CPU it is intended to run on. Our representation of the target platform is called llvm::Triple so the default CPU belongs in this object. Being in this object means that tools such as clang, or API's such as Target::createTargetMachine() will always get the defaults corresponding to the triple. These defaults, as we discussed above vary according to the OS (MIPS-II on Debian, MIPS32R2 on Fedora). This kind of problem also exists in other forms such as Softfloat vs Hardfloat defaults, NAN1985 vs NAN2008 defaults, default ABIs, etc. Other things to mention MIPS64 is not a fundamentally different architecture from MIPS32. If we had a representation of the ABI in the triple then we wouldn't need Triple::mips64/mips64el. From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 23 September 2015 01:34 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :)> Could you please provide some examples of things that are impossible right now > with command lines, how those interact with the TargetMachine, and how you see > it being impossible to deal with?There's some examples above but I'll give the detail in the morning. It's 11:30pm at the moment :-). Let's talk through one of your examples here when you write things up. I think tracing the execution as you see it will be important to coming to a mutual understanding here. I know that you have a solution that you see is going to solve the problems you see, but the I think the problems that you and I are seeing are possibly not the same thing. So let's walk through this execution trace and see what we can do. Thanks! -eric ________________________________ From: Eric Christopher [echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 22 September 2015 20:40 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples On Thu, Sep 17, 2015 at 6:21 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote: I think we need to take a step further back and re-enter from the right starting point. The thing that's bothering me about the push back so far is that it's trying to discuss and understand the consequences of resolving the core problem while seemingly ignoring the core problem itself. The reason I've been steering everything back to GNU Triple's being ambiguous and inconsistent is because it's the root of all the problems and the fixes to the various issues fall out naturally once this core point has been addressed. *sigh* Here's the line of thought that I'd like people to start with: • Triples don't describe the target. They look like they should, but they don't. They're really just arbitrary strings. Triples are used as a starting point, but no more. • LLVM relies on Triple as a description of the target. It defines the backend to use, the binary format to use, OS and Vendor specific quirks to enable/disable, the default CPU, the default ABI, the endian, and countless other details about the target. These two statements aren't necessarily true in whole. a) We don't use the Triple to fully specify the target. b) We don't use the Triple to fully specify the ABI. c) We don't use the Triple to fully specify the CPU. d) We do use the triple to handle endianness since most, if not all, triples actually bother to encode endianness. e) The rest of the "countless details" may or may not be relevant, you haven't given an example of what you care about.>From here on your email relies on all of these assumptions being true. So I'm going to skip past that part and go to where you answer some of my questions.At this point, in the MC layer we have a number of classes that need to know the ABI but lack this information. Our TargetMachine has an accurate TargetTuple object that describes the invariants of the desired target. The desired ABI is an invariant too so why not have it in the TargetTuple which is already plumbed in everywhere we need it? After all, it's a property of the target OS/Environment. If we have the ABI in the TargetTuple, then we don't need any other means to set the ABI, tools can set it up front in the TargetTuple and we don't need any command-line option handling for it in the backend. This isn't sufficient anyways as I don't want to depend on a weird serialization format to deal with something a simple command line can deal with (or you've said this in a way that's confused me). I see you saying you want: -tuple mips-linux-gnu-abio32-el to specify on a command line to, say, llvm-mc or a new assembler interface, or heck, to clang itself, that you want to compile for: -triple mipsel-linux-gnu -mabi=o32 right? Basically? (Bikeshedding of how to actually serialize things aside?) Meanwhile, in clang we have a number of command line options that change the desired target. Let's say we've constructed a Triple and resolved it to TargetTuple (more on that below). We're now processing the –EL option. At the moment, we substitute our mips-linux-gnu triple for a mipsel-linux-gnu triple, construct a Triple object from it and resolve the new Triple to a TargetTuple. But why do we need to bother with that kind of weird hackery when we can simply do Obj.setEndian(Little)? This is what Phase 7 of the plan is about. We end up with a cleaner way to process target changes that, until now, have required weird triple hacking to handle. This is something else I don't understand. Here is the first time you start talking about APIs which is what I'm particularly asking about in my earlier mails. I'd like to see how you plan on changing the TargetMachine and MC level APIs to deal with this. It seems like the Tuple is going to be a way to side-load information around to the MC layer and while I agree that something is necessary there, I don't think that this solution is the right one. (As I said earlier in the thread) I skipped the Triple -> TargetTuple resolution a moment ago and I should address that now. We already know that mapping Triple to TargetTuple is a many to many mapping. One Triple has many possible TargetTuple's depending on the environment. One TargetTuple can be formed from multiple possible Triples. In an ideal world, we'd like to bake in all of these mappings so that one clang binary supports everything. Unfortunately, being a many to many mapping, some of these mappings are mutually exclusive. Note that this isn't a new problem resulting from this project. The problem has always been there but has been ignored until now. To resolve this, we need to provide configure-time and possibly run-time controls for how this conversion is disambiguated. This resolution is performed as early as possible so that the middle/back-ends don't need to know anything about the ambiguity problem. The minute you start talking about configure time controls we've already lost. This, for me, is a non-starter. That said, I'd like to see the examples you think show that things are impossible to deal with in the current architecture. --- To reply more directly to your email: Thanks :)> What can't be done to TargetMachine to avoid this serialization?TargetMachine already has the serialization (see TargetMachine::TargetTriple). We're not doing anything new here. We're simply replacing one object holding faulty information with a new object holding reliable information. This is side stepping my question and making it about Triple. I've specifically said that TargetMachine does not and is not completely dependent upon Triple.> And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options.The data I want to fix is global. I think the bit you may be getting hung up on here is that small portions of this global data can also be overridden at the function level. Those overrides aren't a problem and continue to operate in the same way as they do today. Examples please.> And one more: What global options do we need to consider here?I'm not certain I understand this question. If you're talking command line options, it's things like –EL, -EB, -mips32, -mips32r[2356], -mips64, -mips64r[2356], -mabi=…. If you're talking about Triple -> TargetTuple mappings, there's quite a wide variety but the main ones for Mips are endian, architecture, default CPU, and default ABI. All of these are representable right now in the TargetMachine as far as I can tell. What examples are you having problems with?> The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. > This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of > everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part > of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM > were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults > as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some > of the handling there during the TargetSubtargetInfo work.I generally agree with this. The key bit I need to draw attention to is that the 'defaults' don't change, but are instead overridden. These constant defaults are stored in TargetMachine and particularly TargetMachine::TargetTriple. These defaults are wrong for some toolchains since the information stored in TargetMachine::TargetTriple are wrong. It's the defaults I'm trying to fix rather than the overrides. I don't understand what you mean here. I think I understand your proposed plan now and it's a few steps ahead of where we are and where we need to be. I agree that overridable state should be in TargetSubtargetInfo, however I can't initialize that state without the default values which come from the faulty information in TargetMachine::TargetTriple. This triple work is a pre-requisite to your plan and at first I don't need to override ABI's. Can you provide an example of using a tool that you're having problems with?> Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. > I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems > with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree > with some of the directions you're headed - I just don't see the unification and interactions right now.I think we'll end up with TargetTuple taking over many arguments to TargetMachine but that's not my goal at this stage. My goal is simply to fix the faulty information currently held in Triple and use the now-accurate information in TargetTuple to fix various blocking issues that prevent a proper Mips toolchain product based on Clang/LLVM. At the end of Phase 7, it become possible to fix a number of issues that are impossible to fix right now because the available data we can consult at the moment is incorrect. Could you please provide some examples of things that are impossible right now with command lines, how those interact with the TargetMachine, and how you see it being impossible to deal with? Thanks -eric From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 16 September 2015 23:52 To: Renato Golin; Jim Grosbach Cc: Daniel Sanders; llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples Let's take a step back here. It appears that you and Daniel are trying to solve some problems. I think solving problems is good, I just want to make sure that we're solving them in a way that gets us a decent API at the end. I also want to make sure we're solving the right problems. TargetTuple appears to be related to the TargetParser as you bring up in this mail. They're two separate parts of similar problems - people trying to both serialize command line options and communication from the front end to the backend with respect to target information. This leads me to a question: What can't be done to TargetMachine to avoid this serialization? And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options. And one more: What global options do we need to consider here? The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some of the handling there during the TargetSubtargetInfo work. Now a bit more on TargetParser + TargetTuple: TargetParser appears to be trying to solve the parsing in Triple in a nice way for ARM and also some of the "what kind of subtarget feature canonicalization can we do in llvm that makes sense to communicate to the front end". I like this particular idea and have often wanted a library of feature handling, but it seems to have stabilized at an ARM specific set of code with no defined interface. I can't even figure out how I'd use it in lib/Basic right now for any target other than ARM. This isn't a condemnation of TargetParser, but I think it's something that needs to be thought through a bit more. It's been hooked up well before I'd expected it to and right now if we moved it to the ARM backend from Support it'd make just as much sense as it does where it is now other than making clang depend on the ARM backend as well as the X86 backend :) Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree with some of the directions you're headed - I just don't see the unification and interactions right now. As a suggestion as a way forward here let's see if we can get my questions above answered and also show some of how the interactions between llvm's libraries are going to get fixed, moved to a better place, etc here. Thanks! -eric On Wed, Sep 16, 2015 at 3:02 PM Renato Golin <renato.golin at linaro.org<mailto:renato.golin at linaro.org>> wrote: On 16 September 2015 at 21:56, Jim Grosbach <grosbach at apple.com<mailto:grosbach at apple.com>> wrote:> Why do we care about GAS? We have an assembler.It's not that simple. There are a lot of old code out there, including the Linux kernel which we do care a lot, that only compiles with GAS. We're slowly moving the legacy code up to modern standards, and specifically some kernel folks are happy to move up not only the asm syntax, but the C standard and move away from GNU-specific behaviour. But we're not quite there yet, and might not be for a few more years. so, yes, we still care about GAS. But this is not just about GAS. As I said on my previous email, this is about clearing the bloat in target descriptions by both: removing the need for adding numerous CPU names, target features, architecture names (xscale, strongarm, etc), AND making sure all parties (front/middle/back-ends) speak the same language, produced from the same source. The TargetTuple is that common language, and the TargetParser created from the TableGen files is the common source. The Triple becomes a legacy constructor value for the Tuple. All other target information classes are already (or should be) generated from the TableGen files, so the ultimate source becomes the TableGen description, which I think it what you were aiming to on your comment. For simple architectures, like x86, you don't even need a TargetParser. You can easily construct the Tuple from a triple and use the Tuple as you've always used the triple. No harm done. But for the complex ones like ARM and MIPS, having a common interface generated from the same place the other interfaces are is important to avoid more bridges between front and middle and back end interpretations of the same target. Whatever legacy ARM or MIPS carry can be isolated in their own implementation, leaving the rest of the targets with a clean and simple interface. cheers, --renato -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20150923/5159d769/attachment-0001.html>
Eric Christopher echristo at gmail.com<mailto:echristo at gmail.com> writes:> The lack of a TargetMachine at the MC level was something I brought up a long time ago in this thread > with my proposed solutions. This is what needs to be fixed, especially given that targets can switch ISA, > ABI, floating point, etc within a single assemble action.I’ve been watching this thread in the background and while I am not versed in all the LLVM internals I understand the aims of the work here. As I understand it your proposal aims to help solve the issue of getting the complete set of ABI information to every part of LLVM that needs it and you are saying TargetMachine should encapsulate that data directly. Is that correct and do you see a reasonable chance of community agreement on adding TargetMachine to any place where it may be needed (currently identified as MC but there could be others)? The data that constitutes the full ABI would be made up of the triple (for whatever value it has) and additional flags/features that describe the effective meaning of the triple at any given point in time i.e. after being modified by command line options or in the case of per function overrides in a subtarget description. That sounds like it solves one big part of the problem. Perhaps the detail of how to achieve that can be forked off into another thread as I think it is safe to detach that from triples. My perspective on ‘the trouble with triples’: Given you have a GNU background I’ll pose a scenario in GCC config parlance and perhaps you can explain how, if at all, you see LLVM responding to the issue. This is a fake scenario but is still representative of what happens in the real world. 1) configure --target=mips64el-linux-gnu --with-arch-32=i6400 --with-arch-64=i6400 --with-abi=64 --with-float=soft 2) configure --target=mips64el-linux-gnu --with-arch-32=i6400 --with-arch-64=i6400 --with-abi=n32 --with-fp-32=xx I create a small linux distribution from scratch using these compilers. From a sysroot layout point of view there will be folders called mips64el-linux-gnu in various places albeit the libraries in each will have wildly different ABIs. For 1) When I run gcc I get n64+softfloat+nan2008+i6400 For 2) When I run gcc I get n32+hardfloat+doublefloat+nan2008+i6400 For 1) when I run gcc -mabi=32 I get o32+soft-float+nan2008+i6400 For 2) when I run gcc -mabi=32 I get o32+hardfloat+doublefloat+nan2008+fpxx+i6400 If I want to use clang as simply as I use GCC what do I need to change in llvm/clang to create a compiler such that I can replace ‘gcc’ above with ‘clang’ and get the same effect? Thanks, Matthew From: llvm-dev [mailto:llvm-dev-bounces at lists.llvm.org] On Behalf Of Eric Christopher via llvm-dev Sent: 23 September 2015 19:50 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org Subject: Re: [llvm-dev] The Trouble with Triples On Wed, Sep 23, 2015 at 11:38 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote:> OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :) > > > > Could you please provide some examples of things that are impossible right now > > > with command lines, how those interact with the TargetMachine, and how you see > > > it being impossible to deal with? > > There's some examples above but I'll give the detail in the morning. It's 11:30pmat the moment :-).> Let's talk through one of your examples here when you write things up. I think > tracing the execution as you see it will be important to coming to a mutual > understanding here. I know that you have a solution that you see is going to > solve the problems you see, but the I think the problems that you and I are seeing > are possibly not the same thing. So let's walk through this execution trace and see > what we can do.ABI Let's start at llvm-mc's main(). It's important to note that llvm-mc does not create a TargetMachine. Here's a sketch of what happens: So, we can just stop here. A couple problems: a) llvm-mc isn't a supported product, but that's not the real issue. b) The lack of a TargetMachine at the MC level was something I brought up a long time ago in this thread with my proposed solutions. This is what needs to be fixed, especially given that targets can switch ISA, ABI, floating point, etc within a single assemble action. I even brought up a lot of these problems originally when I was fixing MIPS to work with the current subtarget rewrite. -eric • Initialize LLVM • Parse the command line • Construct an MCTargetOptions from the flags • Normalize the triple • Construct a llvm::Target o If the triple is not given, we fetch the default o We normalize the triple o We call TargetRegistry::lookupTarget() to get a llvm::Target. • If –march is given, and Triple::getArchTypeForLLVMName() doesn't return Triple::UnknownArch, the new arch this mutates the triple. Otherwise it applies the –march correctly but doesn't change the triple to match. In this way, it's possible to end up with i586-linux-gnu targeting the foobar architecture. • Call createMCRegInfo() • Call createMCAsmInfo() o MipsMCAsmInfo::PointerSize is incorrect for the N32 ABI (should be 4 but gets 8 since it checks for Triple::mips64/mips64el) o MipsMCAsmInfo::CalleeSaveStackSlotSize is incorrect for mips-linux-gnu –mips64 –mabi=64. Since it too checks for Triple::mips64/mips64el o MipsMCAsmInfo::PrivateLabelPrefix and MipsMCAsmInfo::PrivateGlobalPrefix are wrong (currently "$", should be ".L") for N32/N64 but it's possible to fix this. However, O32 should permit "$" in addition to ".L". Even if MipsMCAsmInfo supported multiple prefixes (which is easy enough to add), checking for Triple::mips/mipsel would not yield the correct result on mips64-linux-gnu –mabi=32. • InitMCObjectFileInfo() o FDECFEEncoding is incorrect for N32 (should be sdata4 but gets sdata8 since it checks for Triple::mips64/mips64el) o PersonalityEncoding and TTypeEncoding are correct but only because we don't have a R_MIPS_PC64 relocation yet. If we had such a relocation this would have the same problem as FDECFEEncoding. • createMCInstrInfo() • createMCInstPrinter() • createMCCodeEmitter() • createMCAsmBackend() • If emitting assembly, createMCAsmStreamer() • if emitting object, createMCObjectStreamer() o This in turn calls createObjectWriter() and tells it to emit ELF32/ELF64 objects. This information comes from MipsAsmBackend and ultimately comes from Triple::mips/mipsel vs Triple::mips64/mips64el. This is incorrect for N32 (which should be ELF32 but has Triple::mips64/mips64el) and for mips-linux-gnu –mips64 (which should be ELF32 since it should target O32). • If assembling createMCAsmParser • If disassembling: o createMCRegInfo() (again) o createMCAsmInfo() (again) • This has the same issues as the first call. o createMCDisassembler() Clang does pretty much the same thing as this but additionally has to deal with using the correct default ABI for the given triple. I'll cover this kind of problem in 'CPU Defaults' below. Other places that get ABI information wrong: • AddressSanitizer: Uses Triple::mips64/mips64el to mean the N64 ABI. N32 is a Triple::mips64/mips64el that should behave as the Triple::mips/mipsel cases do. • DataFlowSanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. • MemorySanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. • Many places where hasMips64*() or isGP64bit() are used in the backend. o MSA intrinsic lowering o Legalization configuration o Instruction selection o MipsTargetLowering::getOptimalMemOpType() o And many more. I can provide more detail if you want. Other notables: • RuntimeDyldELF gets it right but only because it can read the ELF headers instead of the Triple. It went down the same road for a while. I'll provide a CodeGen example tomorrow if you want. I'd intended to include one but this email took longer to type up than I expected. Endian Defaults The toolchain is mips-linux-gnu and targets little endian by default. Here's what currently happens: • We parse the triple (mips-linux-gnu) and get Triple::mips • No command line flags modify this • We construct a TargetMachine and all the other objects using this llvm::Triple. • The architecture was Triple::mips so everything configures for big-endian even though the target was supposed to be little endian. CPU Defaults In LLVM, the default CPU is hardcoded to be MIPS32 (in MipsABIInfo::computeTargetABI()). In Clang, the default CPU for this triple is hardcoded to be MIPS32R2 (in mips::getMipsCPUAndABI()) and clang always passes an explicit CPU to the backend via –target-cpu. On Debian, the default CPU for mipsel-linux-gnu is MIPS-II. On Fedora, the default CPU for mipsel-linux-gnu is MIPS32R2. It is not possible to hardcode the default both ways. How would you resolve this conflict? In my opinion, the only choices to resolve this conflict are configure-time options or run-time config files. Configure-time options to select the default CPU is faster to implement and produces a (slightly) faster clang while run-time config files are more flexible but slower to implement and produces a slower clang. To me, configure-time is the sensible short term choice followed by moving to run-time config files once the pressure to achieve an initial release is gone. Now let's consider JIT's. JIT's should default to the host CPU as defined by the host triple so that it generates code for the same target as the rest of the system. There is a reasonable argument that the default CPU should be auto-detected CPU for performance reasons but it may not be possible to auto-detect the CPU in all circumstances. We therefore need a default to fall back on. This default should be the same as the default for the native compiler on this host (MIPS-II for Debian, MIPS32R2 for Fedora). In my opinion, the default CPU is a property of the target platform since the platform specifies the minimum CPU it is intended to run on. Our representation of the target platform is called llvm::Triple so the default CPU belongs in this object. Being in this object means that tools such as clang, or API's such as Target::createTargetMachine() will always get the defaults corresponding to the triple. These defaults, as we discussed above vary according to the OS (MIPS-II on Debian, MIPS32R2 on Fedora). This kind of problem also exists in other forms such as Softfloat vs Hardfloat defaults, NAN1985 vs NAN2008 defaults, default ABIs, etc. Other things to mention MIPS64 is not a fundamentally different architecture from MIPS32. If we had a representation of the ABI in the triple then we wouldn't need Triple::mips64/mips64el. From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 23 September 2015 01:34 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :)> Could you please provide some examples of things that are impossible right now > with command lines, how those interact with the TargetMachine, and how you see > it being impossible to deal with?There's some examples above but I'll give the detail in the morning. It's 11:30pm at the moment :-). Let's talk through one of your examples here when you write things up. I think tracing the execution as you see it will be important to coming to a mutual understanding here. I know that you have a solution that you see is going to solve the problems you see, but the I think the problems that you and I are seeing are possibly not the same thing. So let's walk through this execution trace and see what we can do. Thanks! -eric ________________________________ From: Eric Christopher [echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 22 September 2015 20:40 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples On Thu, Sep 17, 2015 at 6:21 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote: I think we need to take a step further back and re-enter from the right starting point. The thing that's bothering me about the push back so far is that it's trying to discuss and understand the consequences of resolving the core problem while seemingly ignoring the core problem itself. The reason I've been steering everything back to GNU Triple's being ambiguous and inconsistent is because it's the root of all the problems and the fixes to the various issues fall out naturally once this core point has been addressed. *sigh* Here's the line of thought that I'd like people to start with: • Triples don't describe the target. They look like they should, but they don't. They're really just arbitrary strings. Triples are used as a starting point, but no more. • LLVM relies on Triple as a description of the target. It defines the backend to use, the binary format to use, OS and Vendor specific quirks to enable/disable, the default CPU, the default ABI, the endian, and countless other details about the target. These two statements aren't necessarily true in whole. a) We don't use the Triple to fully specify the target. b) We don't use the Triple to fully specify the ABI. c) We don't use the Triple to fully specify the CPU. d) We do use the triple to handle endianness since most, if not all, triples actually bother to encode endianness. e) The rest of the "countless details" may or may not be relevant, you haven't given an example of what you care about. From here on your email relies on all of these assumptions being true. So I'm going to skip past that part and go to where you answer some of my questions. At this point, in the MC layer we have a number of classes that need to know the ABI but lack this information. Our TargetMachine has an accurate TargetTuple object that describes the invariants of the desired target. The desired ABI is an invariant too so why not have it in the TargetTuple which is already plumbed in everywhere we need it? After all, it's a property of the target OS/Environment. If we have the ABI in the TargetTuple, then we don't need any other means to set the ABI, tools can set it up front in the TargetTuple and we don't need any command-line option handling for it in the backend. This isn't sufficient anyways as I don't want to depend on a weird serialization format to deal with something a simple command line can deal with (or you've said this in a way that's confused me). I see you saying you want: -tuple mips-linux-gnu-abio32-el to specify on a command line to, say, llvm-mc or a new assembler interface, or heck, to clang itself, that you want to compile for: -triple mipsel-linux-gnu -mabi=o32 right? Basically? (Bikeshedding of how to actually serialize things aside?) Meanwhile, in clang we have a number of command line options that change the desired target. Let's say we've constructed a Triple and resolved it to TargetTuple (more on that below). We're now processing the –EL option. At the moment, we substitute our mips-linux-gnu triple for a mipsel-linux-gnu triple, construct a Triple object from it and resolve the new Triple to a TargetTuple. But why do we need to bother with that kind of weird hackery when we can simply do Obj.setEndian(Little)? This is what Phase 7 of the plan is about. We end up with a cleaner way to process target changes that, until now, have required weird triple hacking to handle. This is something else I don't understand. Here is the first time you start talking about APIs which is what I'm particularly asking about in my earlier mails. I'd like to see how you plan on changing the TargetMachine and MC level APIs to deal with this. It seems like the Tuple is going to be a way to side-load information around to the MC layer and while I agree that something is necessary there, I don't think that this solution is the right one. (As I said earlier in the thread) I skipped the Triple -> TargetTuple resolution a moment ago and I should address that now. We already know that mapping Triple to TargetTuple is a many to many mapping. One Triple has many possible TargetTuple's depending on the environment. One TargetTuple can be formed from multiple possible Triples. In an ideal world, we'd like to bake in all of these mappings so that one clang binary supports everything. Unfortunately, being a many to many mapping, some of these mappings are mutually exclusive. Note that this isn't a new problem resulting from this project. The problem has always been there but has been ignored until now. To resolve this, we need to provide configure-time and possibly run-time controls for how this conversion is disambiguated. This resolution is performed as early as possible so that the middle/back-ends don't need to know anything about the ambiguity problem. The minute you start talking about configure time controls we've already lost. This, for me, is a non-starter. That said, I'd like to see the examples you think show that things are impossible to deal with in the current architecture. --- To reply more directly to your email: Thanks :)> What can't be done to TargetMachine to avoid this serialization?TargetMachine already has the serialization (see TargetMachine::TargetTriple). We're not doing anything new here. We're simply replacing one object holding faulty information with a new object holding reliable information. This is side stepping my question and making it about Triple. I've specifically said that TargetMachine does not and is not completely dependent upon Triple.> And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options.The data I want to fix is global. I think the bit you may be getting hung up on here is that small portions of this global data can also be overridden at the function level. Those overrides aren't a problem and continue to operate in the same way as they do today. Examples please.> And one more: What global options do we need to consider here?I'm not certain I understand this question. If you're talking command line options, it's things like –EL, -EB, -mips32, -mips32r[2356], -mips64, -mips64r[2356], -mabi=…. If you're talking about Triple -> TargetTuple mappings, there's quite a wide variety but the main ones for Mips are endian, architecture, default CPU, and default ABI. All of these are representable right now in the TargetMachine as far as I can tell. What examples are you having problems with?> The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. > This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of > everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part > of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM > were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults > as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some > of the handling there during the TargetSubtargetInfo work.I generally agree with this. The key bit I need to draw attention to is that the 'defaults' don't change, but are instead overridden. These constant defaults are stored in TargetMachine and particularly TargetMachine::TargetTriple. These defaults are wrong for some toolchains since the information stored in TargetMachine::TargetTriple are wrong. It's the defaults I'm trying to fix rather than the overrides. I don't understand what you mean here. I think I understand your proposed plan now and it's a few steps ahead of where we are and where we need to be. I agree that overridable state should be in TargetSubtargetInfo, however I can't initialize that state without the default values which come from the faulty information in TargetMachine::TargetTriple. This triple work is a pre-requisite to your plan and at first I don't need to override ABI's. Can you provide an example of using a tool that you're having problems with?> Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. > I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems > with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree > with some of the directions you're headed - I just don't see the unification and interactions right now.I think we'll end up with TargetTuple taking over many arguments to TargetMachine but that's not my goal at this stage. My goal is simply to fix the faulty information currently held in Triple and use the now-accurate information in TargetTuple to fix various blocking issues that prevent a proper Mips toolchain product based on Clang/LLVM. At the end of Phase 7, it become possible to fix a number of issues that are impossible to fix right now because the available data we can consult at the moment is incorrect. Could you please provide some examples of things that are impossible right now with command lines, how those interact with the TargetMachine, and how you see it being impossible to deal with? Thanks -eric From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 16 September 2015 23:52 To: Renato Golin; Jim Grosbach Cc: Daniel Sanders; llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples Let's take a step back here. It appears that you and Daniel are trying to solve some problems. I think solving problems is good, I just want to make sure that we're solving them in a way that gets us a decent API at the end. I also want to make sure we're solving the right problems. TargetTuple appears to be related to the TargetParser as you bring up in this mail. They're two separate parts of similar problems - people trying to both serialize command line options and communication from the front end to the backend with respect to target information. This leads me to a question: What can't be done to TargetMachine to avoid this serialization? And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options. And one more: What global options do we need to consider here? The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some of the handling there during the TargetSubtargetInfo work. Now a bit more on TargetParser + TargetTuple: TargetParser appears to be trying to solve the parsing in Triple in a nice way for ARM and also some of the "what kind of subtarget feature canonicalization can we do in llvm that makes sense to communicate to the front end". I like this particular idea and have often wanted a library of feature handling, but it seems to have stabilized at an ARM specific set of code with no defined interface. I can't even figure out how I'd use it in lib/Basic right now for any target other than ARM. This isn't a condemnation of TargetParser, but I think it's something that needs to be thought through a bit more. It's been hooked up well before I'd expected it to and right now if we moved it to the ARM backend from Support it'd make just as much sense as it does where it is now other than making clang depend on the ARM backend as well as the X86 backend :) Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree with some of the directions you're headed - I just don't see the unification and interactions right now. As a suggestion as a way forward here let's see if we can get my questions above answered and also show some of how the interactions between llvm's libraries are going to get fixed, moved to a better place, etc here. Thanks! -eric On Wed, Sep 16, 2015 at 3:02 PM Renato Golin <renato.golin at linaro.org<mailto:renato.golin at linaro.org>> wrote: On 16 September 2015 at 21:56, Jim Grosbach <grosbach at apple.com<mailto:grosbach at apple.com>> wrote:> Why do we care about GAS? We have an assembler.It's not that simple. There are a lot of old code out there, including the Linux kernel which we do care a lot, that only compiles with GAS. We're slowly moving the legacy code up to modern standards, and specifically some kernel folks are happy to move up not only the asm syntax, but the C standard and move away from GNU-specific behaviour. But we're not quite there yet, and might not be for a few more years. so, yes, we still care about GAS. But this is not just about GAS. As I said on my previous email, this is about clearing the bloat in target descriptions by both: removing the need for adding numerous CPU names, target features, architecture names (xscale, strongarm, etc), AND making sure all parties (front/middle/back-ends) speak the same language, produced from the same source. The TargetTuple is that common language, and the TargetParser created from the TableGen files is the common source. The Triple becomes a legacy constructor value for the Tuple. All other target information classes are already (or should be) generated from the TableGen files, so the ultimate source becomes the TableGen description, which I think it what you were aiming to on your comment. For simple architectures, like x86, you don't even need a TargetParser. You can easily construct the Tuple from a triple and use the Tuple as you've always used the triple. No harm done. But for the complex ones like ARM and MIPS, having a common interface generated from the same place the other interfaces are is important to avoid more bridges between front and middle and back end interpretations of the same target. Whatever legacy ARM or MIPS carry can be isolated in their own implementation, leaving the rest of the targets with a clean and simple interface. cheers, --renato -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20150923/1e484c0b/attachment-0001.html>
Rewrote the ABI example in terms of clang -cc1as which is a supported tool. Note that the same problems exist and that they are unrelated to the existence of TargetMachine or not since TargetMachine gets the relevant information from the Triple it holds. This information is incorrect, even as a starting point. Please do read the other examples in my previous email. It contains a number of problems that need to be addressed and are completely unrelated to the MC layer. ABI Let's start at ExecuteAssembler() in cc1as_main.cpp. Here's a sketch of what happens: * Call TargetRegistry::lookupTarget() to get a llvm::Target. * Call createMCRegInfo(Triple, ...) * Call createMCAsmInfo(..., Triple) * MipsMCAsmInfo::PointerSize is incorrect for the N32 ABI (should be 4 but gets 8 since it checks for Triple::mips64/mips64el) * MipsMCAsmInfo::CalleeSaveStackSlotSize is incorrect for mips-linux-gnu –mips64 –mabi=64. Since it too checks for Triple::mips64/mips64el * MipsMCAsmInfo::PrivateLabelPrefix and MipsMCAsmInfo::PrivateGlobalPrefix are wrong (currently "$", should be ".L") for N32/N64 but it's possible to fix this. However, O32 should permit "$" in addition to ".L". Even if MipsMCAsmInfo supported multiple prefixes (which is easy enough to add), checking for Triple::mips/mipsel would not yield the correct result on mips64-linux-gnu –mabi=32. * Construct an MCObjectFileInfo * InitMCObjectFileInfo() * FDECFEEncoding is incorrect for N32 (should be sdata4 but gets sdata8 since it checks for Triple::mips64/mips64el) * PersonalityEncoding and TTypeEncoding are correct but only because we don't have a R_MIPS_PC64 relocation yet. If we had such a relocation this would have the same problem as FDECFEEncoding. * Call createMCInstrInfo * Call createMCSubtargetInfo(Triple, ...) * If emitting assembly: * Call createMCInstPrinter(Triple, ...) * If emitting encodings: * Call createMCCodeEmitter() * Call createMCAsmBackend(..., Triple, ...) * Call createMCAsmStreamer() * If emitting objects: * Call createMCCodeEmitter() * Call createMCAsmBackend(..., Triple, ...) * createMCObjectStreamer() * This in turn calls createObjectWriter() and tells it to emit ELF32/ELF64 objects. This information comes from MipsAsmBackend and ultimately comes from Triple::mips/mipsel vs Triple::mips64/mips64el. This is incorrect for N32 (which should be ELF32 but has Triple::mips64/mips64el) and for mips-linux-gnu –mips64 (which should be ELF32 since it should target O32). * Call createMCAsmParser() * Call a different createMCAsmParser(). Other places that get ABI information wrong: * AddressSanitizer: Uses Triple::mips64/mips64el to mean the N64 ABI. N32 is a Triple::mips64/mips64el that should behave as the Triple::mips/mipsel cases do. * DataFlowSanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. * MemorySanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. * Many places where hasMips64*() or isGP64bit() are used in the backend. * MSA intrinsic lowering * Legalization configuration * Instruction selection * MipsTargetLowering::getOptimalMemOpType() * And many more. I can provide more detail if you want. Other notables: * RuntimeDyldELF gets it right but only because it can read the ELF headers instead of the Triple. It went down the same road for a while. I'll provide a CodeGen example tomorrow if you want. ________________________________ From: Eric Christopher [echristo at gmail.com] Sent: 23 September 2015 19:49 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org Subject: Re: The Trouble with Triples On Wed, Sep 23, 2015 at 11:38 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote:> OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :) > > > > Could you please provide some examples of things that are impossible right now > > > with command lines, how those interact with the TargetMachine, and how you see > > > it being impossible to deal with? > > There's some examples above but I'll give the detail in the morning. It's 11:30pmat the moment :-).> Let's talk through one of your examples here when you write things up. I think > tracing the execution as you see it will be important to coming to a mutual > understanding here. I know that you have a solution that you see is going to > solve the problems you see, but the I think the problems that you and I are seeing > are possibly not the same thing. So let's walk through this execution trace and see > what we can do.ABI Let's start at llvm-mc's main(). It's important to note that llvm-mc does not create a TargetMachine. Here's a sketch of what happens: So, we can just stop here. A couple problems: a) llvm-mc isn't a supported product, but that's not the real issue. b) The lack of a TargetMachine at the MC level was something I brought up a long time ago in this thread with my proposed solutions. This is what needs to be fixed, especially given that targets can switch ISA, ABI, floating point, etc within a single assemble action. I even brought up a lot of these problems originally when I was fixing MIPS to work with the current subtarget rewrite. -eric • Initialize LLVM • Parse the command line • Construct an MCTargetOptions from the flags • Normalize the triple • Construct a llvm::Target o If the triple is not given, we fetch the default o We normalize the triple o We call TargetRegistry::lookupTarget() to get a llvm::Target. • If –march is given, and Triple::getArchTypeForLLVMName() doesn't return Triple::UnknownArch, the new arch this mutates the triple. Otherwise it applies the –march correctly but doesn't change the triple to match. In this way, it's possible to end up with i586-linux-gnu targeting the foobar architecture. • Call createMCRegInfo() • Call createMCAsmInfo() o MipsMCAsmInfo::PointerSize is incorrect for the N32 ABI (should be 4 but gets 8 since it checks for Triple::mips64/mips64el) o MipsMCAsmInfo::CalleeSaveStackSlotSize is incorrect for mips-linux-gnu –mips64 –mabi=64. Since it too checks for Triple::mips64/mips64el o MipsMCAsmInfo::PrivateLabelPrefix and MipsMCAsmInfo::PrivateGlobalPrefix are wrong (currently "$", should be ".L") for N32/N64 but it's possible to fix this. However, O32 should permit "$" in addition to ".L". Even if MipsMCAsmInfo supported multiple prefixes (which is easy enough to add), checking for Triple::mips/mipsel would not yield the correct result on mips64-linux-gnu –mabi=32. • InitMCObjectFileInfo() o FDECFEEncoding is incorrect for N32 (should be sdata4 but gets sdata8 since it checks for Triple::mips64/mips64el) o PersonalityEncoding and TTypeEncoding are correct but only because we don't have a R_MIPS_PC64 relocation yet. If we had such a relocation this would have the same problem as FDECFEEncoding. • createMCInstrInfo() • createMCInstPrinter() • createMCCodeEmitter() • createMCAsmBackend() • If emitting assembly, createMCAsmStreamer() • if emitting object, createMCObjectStreamer() o This in turn calls createObjectWriter() and tells it to emit ELF32/ELF64 objects. This information comes from MipsAsmBackend and ultimately comes from Triple::mips/mipsel vs Triple::mips64/mips64el. This is incorrect for N32 (which should be ELF32 but has Triple::mips64/mips64el) and for mips-linux-gnu –mips64 (which should be ELF32 since it should target O32). • If assembling createMCAsmParser • If disassembling: o createMCRegInfo() (again) o createMCAsmInfo() (again) • This has the same issues as the first call. o createMCDisassembler() Clang does pretty much the same thing as this but additionally has to deal with using the correct default ABI for the given triple. I'll cover this kind of problem in 'CPU Defaults' below. Other places that get ABI information wrong: • AddressSanitizer: Uses Triple::mips64/mips64el to mean the N64 ABI. N32 is a Triple::mips64/mips64el that should behave as the Triple::mips/mipsel cases do. • DataFlowSanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. • MemorySanitizer: Is heading down the same road but hasn't implemented O32/N32 yet. • Many places where hasMips64*() or isGP64bit() are used in the backend. o MSA intrinsic lowering o Legalization configuration o Instruction selection o MipsTargetLowering::getOptimalMemOpType() o And many more. I can provide more detail if you want. Other notables: • RuntimeDyldELF gets it right but only because it can read the ELF headers instead of the Triple. It went down the same road for a while. I'll provide a CodeGen example tomorrow if you want. I'd intended to include one but this email took longer to type up than I expected. Endian Defaults The toolchain is mips-linux-gnu and targets little endian by default. Here's what currently happens: • We parse the triple (mips-linux-gnu) and get Triple::mips • No command line flags modify this • We construct a TargetMachine and all the other objects using this llvm::Triple. • The architecture was Triple::mips so everything configures for big-endian even though the target was supposed to be little endian. CPU Defaults In LLVM, the default CPU is hardcoded to be MIPS32 (in MipsABIInfo::computeTargetABI()). In Clang, the default CPU for this triple is hardcoded to be MIPS32R2 (in mips::getMipsCPUAndABI()) and clang always passes an explicit CPU to the backend via –target-cpu. On Debian, the default CPU for mipsel-linux-gnu is MIPS-II. On Fedora, the default CPU for mipsel-linux-gnu is MIPS32R2. It is not possible to hardcode the default both ways. How would you resolve this conflict? In my opinion, the only choices to resolve this conflict are configure-time options or run-time config files. Configure-time options to select the default CPU is faster to implement and produces a (slightly) faster clang while run-time config files are more flexible but slower to implement and produces a slower clang. To me, configure-time is the sensible short term choice followed by moving to run-time config files once the pressure to achieve an initial release is gone. Now let's consider JIT's. JIT's should default to the host CPU as defined by the host triple so that it generates code for the same target as the rest of the system. There is a reasonable argument that the default CPU should be auto-detected CPU for performance reasons but it may not be possible to auto-detect the CPU in all circumstances. We therefore need a default to fall back on. This default should be the same as the default for the native compiler on this host (MIPS-II for Debian, MIPS32R2 for Fedora). In my opinion, the default CPU is a property of the target platform since the platform specifies the minimum CPU it is intended to run on. Our representation of the target platform is called llvm::Triple so the default CPU belongs in this object. Being in this object means that tools such as clang, or API's such as Target::createTargetMachine() will always get the defaults corresponding to the triple. These defaults, as we discussed above vary according to the OS (MIPS-II on Debian, MIPS32R2 on Fedora). This kind of problem also exists in other forms such as Softfloat vs Hardfloat defaults, NAN1985 vs NAN2008 defaults, default ABIs, etc. Other things to mention MIPS64 is not a fundamentally different architecture from MIPS32. If we had a representation of the ABI in the triple then we wouldn't need Triple::mips64/mips64el. From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 23 September 2015 01:34 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples OK, I'm going to just reply to the last because I think it's the most important part of all this and would like to try to have us side tracked again. If you'd like I can reply to it, but let's take the last part first :)> Could you please provide some examples of things that are impossible right now > with command lines, how those interact with the TargetMachine, and how you see > it being impossible to deal with?There's some examples above but I'll give the detail in the morning. It's 11:30pm at the moment :-). Let's talk through one of your examples here when you write things up. I think tracing the execution as you see it will be important to coming to a mutual understanding here. I know that you have a solution that you see is going to solve the problems you see, but the I think the problems that you and I are seeing are possibly not the same thing. So let's walk through this execution trace and see what we can do. Thanks! -eric ________________________________ From: Eric Christopher [echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 22 September 2015 20:40 To: Daniel Sanders; Renato Golin; Jim Grosbach Cc: llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples On Thu, Sep 17, 2015 at 6:21 AM Daniel Sanders <Daniel.Sanders at imgtec.com<mailto:Daniel.Sanders at imgtec.com>> wrote: I think we need to take a step further back and re-enter from the right starting point. The thing that's bothering me about the push back so far is that it's trying to discuss and understand the consequences of resolving the core problem while seemingly ignoring the core problem itself. The reason I've been steering everything back to GNU Triple's being ambiguous and inconsistent is because it's the root of all the problems and the fixes to the various issues fall out naturally once this core point has been addressed. *sigh* Here's the line of thought that I'd like people to start with: • Triples don't describe the target. They look like they should, but they don't. They're really just arbitrary strings. Triples are used as a starting point, but no more. • LLVM relies on Triple as a description of the target. It defines the backend to use, the binary format to use, OS and Vendor specific quirks to enable/disable, the default CPU, the default ABI, the endian, and countless other details about the target. These two statements aren't necessarily true in whole. a) We don't use the Triple to fully specify the target. b) We don't use the Triple to fully specify the ABI. c) We don't use the Triple to fully specify the CPU. d) We do use the triple to handle endianness since most, if not all, triples actually bother to encode endianness. e) The rest of the "countless details" may or may not be relevant, you haven't given an example of what you care about.>From here on your email relies on all of these assumptions being true. So I'm going to skip past that part and go to where you answer some of my questions.At this point, in the MC layer we have a number of classes that need to know the ABI but lack this information. Our TargetMachine has an accurate TargetTuple object that describes the invariants of the desired target. The desired ABI is an invariant too so why not have it in the TargetTuple which is already plumbed in everywhere we need it? After all, it's a property of the target OS/Environment. If we have the ABI in the TargetTuple, then we don't need any other means to set the ABI, tools can set it up front in the TargetTuple and we don't need any command-line option handling for it in the backend. This isn't sufficient anyways as I don't want to depend on a weird serialization format to deal with something a simple command line can deal with (or you've said this in a way that's confused me). I see you saying you want: -tuple mips-linux-gnu-abio32-el to specify on a command line to, say, llvm-mc or a new assembler interface, or heck, to clang itself, that you want to compile for: -triple mipsel-linux-gnu -mabi=o32 right? Basically? (Bikeshedding of how to actually serialize things aside?) Meanwhile, in clang we have a number of command line options that change the desired target. Let's say we've constructed a Triple and resolved it to TargetTuple (more on that below). We're now processing the –EL option. At the moment, we substitute our mips-linux-gnu triple for a mipsel-linux-gnu triple, construct a Triple object from it and resolve the new Triple to a TargetTuple. But why do we need to bother with that kind of weird hackery when we can simply do Obj.setEndian(Little)? This is what Phase 7 of the plan is about. We end up with a cleaner way to process target changes that, until now, have required weird triple hacking to handle. This is something else I don't understand. Here is the first time you start talking about APIs which is what I'm particularly asking about in my earlier mails. I'd like to see how you plan on changing the TargetMachine and MC level APIs to deal with this. It seems like the Tuple is going to be a way to side-load information around to the MC layer and while I agree that something is necessary there, I don't think that this solution is the right one. (As I said earlier in the thread) I skipped the Triple -> TargetTuple resolution a moment ago and I should address that now. We already know that mapping Triple to TargetTuple is a many to many mapping. One Triple has many possible TargetTuple's depending on the environment. One TargetTuple can be formed from multiple possible Triples. In an ideal world, we'd like to bake in all of these mappings so that one clang binary supports everything. Unfortunately, being a many to many mapping, some of these mappings are mutually exclusive. Note that this isn't a new problem resulting from this project. The problem has always been there but has been ignored until now. To resolve this, we need to provide configure-time and possibly run-time controls for how this conversion is disambiguated. This resolution is performed as early as possible so that the middle/back-ends don't need to know anything about the ambiguity problem. The minute you start talking about configure time controls we've already lost. This, for me, is a non-starter. That said, I'd like to see the examples you think show that things are impossible to deal with in the current architecture. --- To reply more directly to your email: Thanks :)> What can't be done to TargetMachine to avoid this serialization?TargetMachine already has the serialization (see TargetMachine::TargetTriple). We're not doing anything new here. We're simply replacing one object holding faulty information with a new object holding reliable information. This is side stepping my question and making it about Triple. I've specifically said that TargetMachine does not and is not completely dependent upon Triple.> And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options.The data I want to fix is global. I think the bit you may be getting hung up on here is that small portions of this global data can also be overridden at the function level. Those overrides aren't a problem and continue to operate in the same way as they do today. Examples please.> And one more: What global options do we need to consider here?I'm not certain I understand this question. If you're talking command line options, it's things like –EL, -EB, -mips32, -mips32r[2356], -mips64, -mips64r[2356], -mabi=…. If you're talking about Triple -> TargetTuple mappings, there's quite a wide variety but the main ones for Mips are endian, architecture, default CPU, and default ABI. All of these are representable right now in the TargetMachine as far as I can tell. What examples are you having problems with?> The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. > This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of > everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part > of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM > were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults > as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some > of the handling there during the TargetSubtargetInfo work.I generally agree with this. The key bit I need to draw attention to is that the 'defaults' don't change, but are instead overridden. These constant defaults are stored in TargetMachine and particularly TargetMachine::TargetTriple. These defaults are wrong for some toolchains since the information stored in TargetMachine::TargetTriple are wrong. It's the defaults I'm trying to fix rather than the overrides. I don't understand what you mean here. I think I understand your proposed plan now and it's a few steps ahead of where we are and where we need to be. I agree that overridable state should be in TargetSubtargetInfo, however I can't initialize that state without the default values which come from the faulty information in TargetMachine::TargetTriple. This triple work is a pre-requisite to your plan and at first I don't need to override ABI's. Can you provide an example of using a tool that you're having problems with?> Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. > I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems > with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree > with some of the directions you're headed - I just don't see the unification and interactions right now.I think we'll end up with TargetTuple taking over many arguments to TargetMachine but that's not my goal at this stage. My goal is simply to fix the faulty information currently held in Triple and use the now-accurate information in TargetTuple to fix various blocking issues that prevent a proper Mips toolchain product based on Clang/LLVM. At the end of Phase 7, it become possible to fix a number of issues that are impossible to fix right now because the available data we can consult at the moment is incorrect. Could you please provide some examples of things that are impossible right now with command lines, how those interact with the TargetMachine, and how you see it being impossible to deal with? Thanks -eric From: Eric Christopher [mailto:echristo at gmail.com<mailto:echristo at gmail.com>] Sent: 16 September 2015 23:52 To: Renato Golin; Jim Grosbach Cc: Daniel Sanders; llvm-dev at lists.llvm.org<mailto:llvm-dev at lists.llvm.org> Subject: Re: The Trouble with Triples Let's take a step back here. It appears that you and Daniel are trying to solve some problems. I think solving problems is good, I just want to make sure that we're solving them in a way that gets us a decent API at the end. I also want to make sure we're solving the right problems. TargetTuple appears to be related to the TargetParser as you bring up in this mail. They're two separate parts of similar problems - people trying to both serialize command line options and communication from the front end to the backend with respect to target information. This leads me to a question: What can't be done to TargetMachine to avoid this serialization? And a followup question: What can't be serialized at the function level in the IR to make certain things clear that aren't global? We already do this for a lot of command line options. And one more: What global options do we need to consider here? The goal of the configuration level of the TargetMachine is that it controls things that don't change at the object level. This is a fairly recently stated goal, but I think it makes sense for LLVM in general. TargetSubtargetInfo takes care of everything that resides under this (as much as possible, some bits are still in transition, e.g. TargetOptions). This is part of my suggestion to Daniel about the problems with MCSubtargetInfo and the assembler. Targets like Mips and ARM were unfortunately designed to change things on the fly during assembly and need to collate or at least change defaults as we're processing code. I definitely had to deal with a lot of the pain you're talking about when I was rewriting some of the handling there during the TargetSubtargetInfo work. Now a bit more on TargetParser + TargetTuple: TargetParser appears to be trying to solve the parsing in Triple in a nice way for ARM and also some of the "what kind of subtarget feature canonicalization can we do in llvm that makes sense to communicate to the front end". I like this particular idea and have often wanted a library of feature handling, but it seems to have stabilized at an ARM specific set of code with no defined interface. I can't even figure out how I'd use it in lib/Basic right now for any target other than ARM. This isn't a condemnation of TargetParser, but I think it's something that needs to be thought through a bit more. It's been hooked up well before I'd expected it to and right now if we moved it to the ARM backend from Support it'd make just as much sense as it does where it is now other than making clang depend on the ARM backend as well as the X86 backend :) Right now I see TargetTuple as trying to take over all of the various arguments to TargetMachine and encapsulate them into a single thing. I also don't see this is bad, but I also don't see it taking all of them right now and I'm not sure how it solves some of the existing problems with data sharing that we've got which is where the push back you're both getting is coming from here. Ultimately library-wise I can agree with some of the directions you're headed - I just don't see the unification and interactions right now. As a suggestion as a way forward here let's see if we can get my questions above answered and also show some of how the interactions between llvm's libraries are going to get fixed, moved to a better place, etc here. Thanks! -eric On Wed, Sep 16, 2015 at 3:02 PM Renato Golin <renato.golin at linaro.org<mailto:renato.golin at linaro.org>> wrote: On 16 September 2015 at 21:56, Jim Grosbach <grosbach at apple.com<mailto:grosbach at apple.com>> wrote:> Why do we care about GAS? We have an assembler.It's not that simple. There are a lot of old code out there, including the Linux kernel which we do care a lot, that only compiles with GAS. We're slowly moving the legacy code up to modern standards, and specifically some kernel folks are happy to move up not only the asm syntax, but the C standard and move away from GNU-specific behaviour. But we're not quite there yet, and might not be for a few more years. so, yes, we still care about GAS. But this is not just about GAS. As I said on my previous email, this is about clearing the bloat in target descriptions by both: removing the need for adding numerous CPU names, target features, architecture names (xscale, strongarm, etc), AND making sure all parties (front/middle/back-ends) speak the same language, produced from the same source. The TargetTuple is that common language, and the TargetParser created from the TableGen files is the common source. The Triple becomes a legacy constructor value for the Tuple. All other target information classes are already (or should be) generated from the TableGen files, so the ultimate source becomes the TableGen description, which I think it what you were aiming to on your comment. For simple architectures, like x86, you don't even need a TargetParser. You can easily construct the Tuple from a triple and use the Tuple as you've always used the triple. No harm done. But for the complex ones like ARM and MIPS, having a common interface generated from the same place the other interfaces are is important to avoid more bridges between front and middle and back end interpretations of the same target. Whatever legacy ARM or MIPS carry can be isolated in their own implementation, leaving the rest of the targets with a clean and simple interface. cheers, --renato -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20150923/57836e06/attachment-0001.html>