Villmow, Micah
2011-Oct-03 18:36 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
One of the projects I am working on with others is to make LLVM-IR endian agnostic. So, I am sending out this proposal for feedback to the LLVM community. I've attached pretty version of the proposal in PDF format and pasted a 80-column safe text version below. I'm looking forward to comments and feedback. Thanks, Micah Villmow Text of Proposal: ===============================================================================RFC - ENDIAN AGNOSTIC IR REPRESENTATION. =============================================================================== ------------------------------------------------------------------------------- MOTIVATION: ------------------------------------------------------------------------------- In our current compilation model, a compiler will compile from a source language to an intermediate IR representation, perform optimizations, and then use the LLVM code generation infrastructure to target a specific backend. This approach works well for homogenous devices, but compilation models of compute languages, like OpenCL, now take place with heterogeneous devices(e.g. x86 core + gpu) as the targets. In some cases the devices have varying pointer sizes and byte ordering and this causes a problem for cross-device binary compatibility that a source language provides. The major problem is that when creating a program for a heterogeneous system, different compilation paths are required for different devices for each source compilation. OpenCL, an Open Standard for compute on various types of devices, defines a source language that is portable across devices(i.e. same source on GPU's and CPUs). While compilation from source is portable, compilation from binary is not, and diverging compilation paths have issues with both maintenance and testing. ------------------------------------------------------------------------------- PROBLEM QUESTION: ------------------------------------------------------------------------------- How does a vendor simplify the compiler stack across multiple target devices by removing endianess from the IR representation? ------------------------------------------------------------------------------- PROPOSAL: ------------------------------------------------------------------------------- I am proposing an extension to LLVM[1] that abstracts away all endian related IR operations with a series of intrinsic calls. These intrinsic calls allow consumers of the IR to quickly reconstruct either the original IR, or an equivalent IR, with respect to the byte ordering of the target device. This IR representation provides an abstraction layer similar to the hton[sl]() series of function calls with network programming. ------------------------------------------------------------------------------- OTHER SYSTEMS: ------------------------------------------------------------------------------- While this approach is similar to Google's PNaCl[3] which attempts to provide an ISA neutral representation. The goals of this proposal are slightly different in that we not only want ISA neutral representation, but also endian-neutral representation. Therefore, where PNaCl represents LLVM-IR before codegen, see figure 1 from [3], this approach provides a portable representation after the frontend and before LLVM-bitcode generation. The PNaCl representation makes assumptions on address space, data types, byte-order, concurrency and runtime system. This proposal inherits the assumptions on data types, address sizes, concurrency and runtime systems from OpenCL[4]. ------------------------------------------------------------------------------- DEFINITIONS: ------------------------------------------------------------------------------- Global Memory - Memory that is visible to all threads in a process/program, e.g. video ram. This includes all read-only, write-only and read-write memories on the system that are visible to all threads. ------------------------------------------------------------------------------- INTRINSICS: ------------------------------------------------------------------------------- This proposal introduces new sets of intrinsics, two load intrinsics and two store intrinsics. The sets are as follows: declare <type> @llvm.portable.load.e.<type>(<type>* ptr, , i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // little endian load declare <type> @llvm.portable.load.E.<type>(<type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // big endian load declare void @llvm.portable.store.e.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatilei1 nontemporal, i1 singlethread) // little endian store declare void @llvm.portable.store.E.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // big endian store A second smaller set could be: declare <type> @llvm.portable.load.<type>(<type>* ptr, i32 alignment, i1 host, i1 littleEndian, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) declare void @llvm.portable.store.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 littleEndian, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) Valid values for type are scalar sizes i8, i16, i32, i64, f16, f32, f64 and vector versions with sizes of 2, 3, 4, 8 and 16 elements. Only pointers to the global address space, designated to separate it from the default address space in LLVM which is 0, with the pointer address space 1, are valid pointer values. The reason for the different address space is that requirement in OpenCL that the default address space is private memory, which conflicts with LLVM's default memory going to globally visible memory. For brevity, all possible combinations are not enumerated here. Another issue is with the data layout. A third option to the endianess is added to the LLVM reference manual that is defined as follows. "p Specifies that the IR is in endian-portable form, i.e. code produced by little- and big-endian target back ends will be functionally equivalent (in their affect on global memory). The IR must be converted to a target format before the IR is valid LLVM-IR." Using this data layout option will allow the compiler to quickly determine if the IR is in endian portable form. ------------------------------------------------------------------------------- PARAMETERS: ------------------------------------------------------------------------------- host - True when the load/store is from the host machine and false when the load/store is from the device. atomic/volatile/nontemporal/singlethread - Follows the same semantics as the arguments to the load/store instructions in the LLVM-IR with the same names. See the LLVM Lang Ref[1]. ------------------------------------------------------------------------------- POINTER ATTRIBUTES: ------------------------------------------------------------------------------- In OpenCL, a pointer can have attributes attached, and this information needs to be encoded. In LLVM, the method of encoding extra information is via metadata nodes and this is used so that the intrinsic do not need to be modified to add extra information. One example of this is the endian(host) attribute that can be attached to a pointer argument(see 6.10.3 of OpenCL 1.1 spec). This information can be encoded in a metadata node which is attached to the intrinsic. An example encoding of this information is as follows: !0 = metadata !{ i32, ;; Tag = <OpenCL version number> using the official OpenCL version macro i1,;;Boolean value to specify that load is from host on true, device on false metadata ;; List of attributes for this intrinsic instruction } ------------------------------------------------------------------------------- CONSTRAINTS: ------------------------------------------------------------------------------- Except for the data and ptr arguments, all arguments must be compile time constants. Optimizations that rely on the byte ordering of memory or that modify the programs interactions with global memory are illegal to be performed on the IR when in the portable form. All accesses to global memory must be done through these intrinsic calls. ------------------------------------------------------------------------------- LINKS: ------------------------------------------------------------------------------- 1. http://llvm.org/docs/LangRef.html 2. http://llvm.org/docs/Atomics.html 3. http://nativeclient.googlecode.com/svn/data/site/pnacl.pdf 4. http://www.khronos.org/opencl/ -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20111003/972c6dea/attachment.html> -------------- next part -------------- A non-text attachment was scrubbed... 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Török Edwin
2011-Oct-03 21:00 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
On 10/03/2011 09:36 PM, Villmow, Micah wrote:> One of the projects I am working on with others is to make LLVM-IR endian agnostic. > > > > So, I am sending out this proposal for feedback to the LLVM community. I’ve attached > > pretty version of the proposal in PDF format and pasted a 80-column safe text version > > below. > > > > A second smaller set could be: > > declare <type> @llvm.portable.load.<type>(<type>* ptr, i32 alignment, > > i1 host, i1 littleEndian, i1 atomic, i1 volatile, > > i1 nontemporal, i1 singlethread) > > > > declare void @llvm.portable.store.<type>(<type> data, <type>* ptr, > > i32 alignment, i1 host, i1 littleEndian, i1 atomic, i1 volatile, > > i1 nontemporal, i1 singlethread)FWIW here is another way to do it (which is approximately what ClamAV does currently) by introducing just one intrinsic: declare i1 @llvm.is_bigendian() The advantage is that you can implement htonl() and ntohl() like functionality without using a temporary memory location. Actually I think having the 2 intrinsics you suggest and the is_bigendian() intrinsic would be optimal: you can use your 2 intrinsics for initial codegen, and mem2reg can transform it to is_bigendian(). For load/store: <type> %val = load <type>* %ptr <type> %sval = bswap.i<type> %val %result = <type> select @llvm.is_bigendian(), %val, %sval For htonl(): <type> %sval = bswap.i<type> %val %result = <type> select @llvm.is_bigendian(), %val, %sval (store is similar, byteswap before the store) At bytecode JIT time / assembly emission time @llvm.is_bigendian() is a known constant, and constant propagation is used to throw away the unwanted code path, so it becomes either: <type> %result = load <type>* %ptr or <type> %val = load <type>* %ptr <type> %result = bswap.i<type> %val Best regards, --Edwin
James Molloy
2011-Oct-04 07:06 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
Hi Micah, I'm no core developer, but FWIW here are my thoughts: I'm general I think the patch is too OpenCL oriented, and I have some niggling qualms about other parts. Specifically (comments inline): From: llvmdev-bounces at cs.uiuc.edu [mailto:llvmdev-bounces at cs.uiuc.edu] On Behalf Of Villmow, Micah Sent: 03 October 2011 19:37 To: llvmdev at cs.uiuc.edu Subject: [LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic One of the projects I am working on with others is to make LLVM-IR endian agnostic. So, I am sending out this proposal for feedback to the LLVM community. I've attached pretty version of the proposal in PDF format and pasted a 80-column safe text version below. I'm looking forward to comments and feedback. ---------------------------------------------------------------------------- --- PROBLEM QUESTION: ---------------------------------------------------------------------------- --- How does a vendor simplify the compiler stack across multiple target devices by removing endianess from the IR representation? This is not the question that your RFC answers. Your RFC answers a superset of just "represent endianness". ---------------------------------------------------------------------------- --- DEFINITIONS: ---------------------------------------------------------------------------- --- Global Memory - Memory that is visible to all threads in a process/program, e.g. video ram. This includes all read-only, write-only and read-write memories on the system that are visible to all threads. What has this got to do with endianness? ---------------------------------------------------------------------------- --- INTRINSICS: ---------------------------------------------------------------------------- --- This proposal introduces new sets of intrinsics, two load intrinsics and two store intrinsics. The sets are as follows: declare <type> @llvm.portable.load.e.<type>(<type>* ptr, , i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // little endian load declare <type> @llvm.portable.load.E.<type>(<type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // big endian load declare void @llvm.portable.store.e.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatilei1 nontemporal, i1 singlethread) // little endian store declare void @llvm.portable.store.E.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // big endian store . I don't like the 'e'/'E' representation. If there were only little or big endian loads throughout an IR file, it wouldn't be obvious to me what the 'e'/'E' meant. It's only seeing the two in tandem where it jumps out at me. I'd prefer the standard 'le'/'be'. . You've put the OpenCL concept of "host" and "device" in a supposedly target-agnostic IR. Why should there be only one device? More importantly, why is host/device an attribute of the load or store as opposed to the pointer to load/store to? Does it semantically make sense to have both a host load and a device load of the same memory location in the same module? ---------------------------------------------------------------------------- --- POINTER ATTRIBUTES: ---------------------------------------------------------------------------- --- In OpenCL, a pointer can have attributes attached, and this information needs to be encoded. In LLVM, the method of encoding extra information is via metadata nodes and this is used so that the intrinsic do not need to be modified to add extra information. One example of this is the endian(host) attribute that can be attached to a pointer argument(see 6.10.3 of OpenCL 1.1 spec). This information can be encoded in a metadata node which is attached to the intrinsic. An example encoding of this information is as follows: !0 = metadata !{ i32, ;; Tag = <OpenCL version number> using the official OpenCL version macro i1,;;Boolean value to specify that load is from host on true, device on false metadata ;; List of attributes for this intrinsic instruction } Does this subsection add anything extra to the RFC? It talks about a format for metadata, but doesn't appear to really add any suggestions or requirements for changing LLVM IR. If your intention was just to make the IR endian-agnostic, I don't see why you wouldn't just propose an extra attribute on the load/store instructions (load be %0, load le %0) instead of recreating all loads and stores in a new form and having to make all passes interact with them. My general summary is that I think your suggestions take a "somewhat language-agnostic and somewhat target-agnostic" IR and turn it into a "somewhat language-dependent and more target-agnostic" IR, by embedding OpenCL specifics. I'm not sure I think that's the best way to go. Cheers, James Thanks, Micah Villmow -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20111004/5965e872/attachment.html>
Duncan Sands
2011-Oct-04 07:28 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
Hi Edwin,> FWIW here is another way to do it (which is approximately what ClamAV does currently) by introducing just one intrinsic: > declare i1 @llvm.is_bigendian()why is an intrinsic needed? It is easy to write a small LLVM IR function that computes this. For example: define i1 @is_big_endian() { %ip = alloca i16 store i16 1, i16* %ip %cp = bitcast i16* %ip to i8* %c = load i8* %cp %r = icmp eq i8 %c, 0 ret i1 %r } Ciao, Duncan.
Villmow, Micah
2011-Oct-04 16:36 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
> -----Original Message----- > From: llvmdev-bounces at cs.uiuc.edu [mailto:llvmdev-bounces at cs.uiuc.edu] > On Behalf Of Török Edwin > Sent: Monday, October 03, 2011 2:00 PM > To: llvmdev at cs.uiuc.edu > Subject: Re: [LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic > > On 10/03/2011 09:36 PM, Villmow, Micah wrote: > > One of the projects I am working on with others is to make LLVM-IR > endian agnostic. > > > > > > > > So, I am sending out this proposal for feedback to the LLVM > community. I've attached > > > > pretty version of the proposal in PDF format and pasted a 80-column > safe text version > > > > below. > > > > > > > > A second smaller set could be: > > > > declare <type> @llvm.portable.load.<type>(<type>* ptr, i32 alignment, > > > > i1 host, i1 littleEndian, i1 atomic, i1 volatile, > > > > i1 nontemporal, i1 singlethread) > > > > > > > > declare void @llvm.portable.store.<type>(<type> data, <type>* ptr, > > > > i32 alignment, i1 host, i1 littleEndian, i1 atomic, i1 volatile, > > > > i1 nontemporal, i1 singlethread) > > FWIW here is another way to do it (which is approximately what ClamAV > does currently) by introducing just one intrinsic: > declare i1 @llvm.is_bigendian()[Villmow, Micah] I think the big difference in our requirements is that we can have both big endian(host) and little endian(device), or vice versa, accesses to the same pointer. So a global is_bigendian intrinsic would not work for what we are attempting to accomplish.> > The advantage is that you can implement htonl() and ntohl() like > functionality without using a temporary memory location. > Actually I think having the 2 intrinsics you suggest and the > is_bigendian() intrinsic would be optimal: > you can use your 2 intrinsics for initial codegen, and mem2reg can > transform it to is_bigendian(). > > For load/store: > <type> %val = load <type>* %ptr > <type> %sval = bswap.i<type> %val > %result = <type> select @llvm.is_bigendian(), %val, %sval > > For htonl(): > <type> %sval = bswap.i<type> %val > %result = <type> select @llvm.is_bigendian(), %val, %sval > > (store is similar, byteswap before the store) > > At bytecode JIT time / assembly emission time @llvm.is_bigendian() is a > known constant, and constant propagation is > used to throw away the unwanted code path, so it becomes either: > > <type> %result = load <type>* %ptr > > or > > <type> %val = load <type>* %ptr > <type> %result = bswap.i<type> %val > > Best regards, > --Edwin > _______________________________________________ > LLVM Developers mailing list > LLVMdev at cs.uiuc.edu http://llvm.cs.uiuc.edu > http://lists.cs.uiuc.edu/mailman/listinfo/llvmdev
Samuel Crow
2011-Oct-04 16:48 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
>________________________________ >From: "Villmow, Micah" <Micah.Villmow at amd.com> >To: "llvmdev at cs.uiuc.edu" <llvmdev at cs.uiuc.edu> >Sent: Monday, October 3, 2011 1:36 PM >Subject: [LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic > > >One of the projects I am working on with others is to make LLVM-IR endian agnostic. > >So, I am sending out this proposal for feedback to the LLVM community. I’ve attached >pretty version of the proposal in PDF format and pasted a 80-column safe text version >below. > >I’m looking forward to comments and feedback. > >Thanks, >Micah Villmow > >--snip-- Hello Micah, Without having read a lot into your plan I'd like to make a few suggestions: Some game systems use mixed-endian datalayouts as a form of lockouts for homebrew software. While I believe it isn't a terribly effective mechanism, it does leave LLVM unable to be used for such game systems. I think LLVM should allow some sort of swizzle mechanism to allow such mixed-endian datalayouts. (I think swizzle is the correct term.) Also, as a co-developer of Clang's AROS backend, it would be really handy to have an endian-agnostic bitcode format since our OS covers about 5 different CPU architectures, some of which are big-endian. We were hoping to base a superset of the ELF loader that would be endian-agnostic based on PNaCl's bitcode format. Thanks for taking this challenge on, --Samuel Crow
Villmow, Micah
2011-Oct-04 17:07 UTC
[LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic
From: James Molloy [mailto:james.molloy at arm.com] Sent: Tuesday, October 04, 2011 12:06 AM To: Villmow, Micah; llvmdev at cs.uiuc.edu Subject: RE: [RFC] Proposal to make LLVM-IR endian agnostic Hi Micah, I'm no core developer, but FWIW here are my thoughts: I'm general I think the patch is too OpenCL oriented [Villmow, Micah] I agree, but this is mainly to solve a problem that is unique to OpenCL or related technologies(CUDA, DirectCompute, etc...). , and I have some niggling qualms about other parts. Specifically (comments inline): From: llvmdev-bounces at cs.uiuc.edu [mailto:llvmdev-bounces at cs.uiuc.edu] On Behalf Of Villmow, Micah Sent: 03 October 2011 19:37 To: llvmdev at cs.uiuc.edu Subject: [LLVMdev] [RFC] Proposal to make LLVM-IR endian agnostic One of the projects I am working on with others is to make LLVM-IR endian agnostic. So, I am sending out this proposal for feedback to the LLVM community. I've attached pretty version of the proposal in PDF format and pasted a 80-column safe text version below. I'm looking forward to comments and feedback. ------------------------------------------------------------------------------- PROBLEM QUESTION: ------------------------------------------------------------------------------- How does a vendor simplify the compiler stack across multiple target devices by removing endianess from the IR representation? This is not the question that your RFC answers. Your RFC answers a superset of just "represent endianness". [Villmow, Micah] Maybe I didn't go into enough detail on how this proposal helps solve this problem. Currently our compiler stack has to handle issues with big endian vs little endian devices along with 32bit vs 64bit devices(which is outside of this scope). If we want to have a common binary that we can use to compile for all devices, then we must store both versions of the LLVM-IR, increasing binary size and compile time. By abstracting away endianness representation, two of the 4 variations are unified, allowing the fat binary to store 1 LLVM-IR representation for each bitness instead of 2. So by abstracting endian assumptions out of the LLVM-IR, we are simplifying the compiler stack. ------------------------------------------------------------------------------- DEFINITIONS: ------------------------------------------------------------------------------- Global Memory - Memory that is visible to all threads in a process/program, e.g. video ram. This includes all read-only, write-only and read-write memories on the system that are visible to all threads. What has this got to do with endianness? [Villmow, Micah] This just defines the type of memory we are interested in. Other types of memory are not covered by this proposal, as they should not have this problem. For example, endianness agnostic load/stores to private memory are meaningless as it is only visible within a thread. ------------------------------------------------------------------------------- INTRINSICS: ------------------------------------------------------------------------------- This proposal introduces new sets of intrinsics, two load intrinsics and two store intrinsics. The sets are as follows: declare <type> @llvm.portable.load.e.<type>(<type>* ptr, , i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // little endian load declare <type> @llvm.portable.load.E.<type>(<type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // big endian load declare void @llvm.portable.store.e.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatilei1 nontemporal, i1 singlethread) // little endian store declare void @llvm.portable.store.E.<type>(<type> data, <type>* ptr, i32 alignment, i1 host, i1 atomic, i1 volatile, i1 nontemporal, i1 singlethread) // big endian store * I don't like the 'e'/'E' representation. If there were only little or big endian loads throughout an IR file, it wouldn't be obvious to me what the 'e'/'E' meant. It's only seeing the two in tandem where it jumps out at me. I'd prefer the standard 'le'/'be'. [Villmow, Micah] Good suggestion, I was using the 'e' and 'E' as that is what is in the target data description from the LLVM spec. * You've put the OpenCL concept of "host" and "device" in a supposedly target-agnostic IR. Why should there be only one device? More importantly, why is host/device an attribute of the load or store as opposed to the pointer to load/store to? Does it semantically make sense to have both a host load and a device load of the same memory location in the same module? [Villmow, Micah] Abstracting LLVM-IR so it can encode multiple device execution information from a single compilation unit is outside the scope of this proposal, hence the single device. The reason for not adding the attribute to the pointer is that each load/store can be unique in how to represent the endianness of the memory it points to. As for the third question, it isn't a host load and a device load, it is a load with host endianess and a load with device endianess. A hypothetical example of this is a simple embedded co-processor attached to a general purpose processor(i.e. AMD's Torrenza initiative) where the co-processor did not have hardware to convert between the endianness but memory spans across its own memory and the system memory. In this case, the compiler when it generates executables needs to make sure that loads from the host have memory ordered correctly for the device. Again, this is just an example, but a possible valid situation. ------------------------------------------------------------------------------- POINTER ATTRIBUTES: ------------------------------------------------------------------------------- In OpenCL, a pointer can have attributes attached, and this information needs to be encoded. In LLVM, the method of encoding extra information is via metadata nodes and this is used so that the intrinsic do not need to be modified to add extra information. One example of this is the endian(host) attribute that can be attached to a pointer argument(see 6.10.3 of OpenCL 1.1 spec). This information can be encoded in a metadata node which is attached to the intrinsic. An example encoding of this information is as follows: !0 = metadata !{ i32, ;; Tag = <OpenCL version number> using the official OpenCL version macro i1,;;Boolean value to specify that load is from host on true, device on false metadata ;; List of attributes for this intrinsic instruction } Does this subsection add anything extra to the RFC? It talks about a format for metadata, but doesn't appear to really add any suggestions or requirements for changing LLVM IR. [Villmow, Micah] Your right, this is more on how to encode pointer information, this can be ignored. If your intention was just to make the IR endian-agnostic, I don't see why you wouldn't just propose an extra attribute on the load/store instructions (load be %0, load le %0) instead of recreating all loads and stores in a new form and having to make all passes interact with them. [Villmow, Micah] While we could go this route, this would make the endian agnostic IR compatible with LLVM-IR passes, which we don't want to do, hence the use of intrinsic. Basically we want the endian agnostic IR to be mostly compatible with LLVM-IR, but will require a transformation pass to generate the correct load/store instructions for the device it will be generated for. I believe there was other reasons brought up by other contributors, but they escape me right now. My general summary is that I think your suggestions take a "somewhat language-agnostic and somewhat target-agnostic" IR and turn it into a "somewhat language-dependent and more target-agnostic" IR, by embedding OpenCL specifics. I'm not sure I think that's the best way to go. [Villmow, Micah] That is correct, that is basically what we are attempting to do. We want a single IR that can be used across multiple devices for OpenCL. If this is something that can be modified to be less language dependent but keep the target agnostic and fulfill our needs, then we are willing to go down that path. This is why we believe involving the LLVM community is important so we can get this kind of feedback and hopefully agree on something that we can use, but other non-related projects can also use. Cheers, James Thanks, Micah Villmow -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20111004/104c13eb/attachment.html>
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