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This will become necessary in a subsequent change to make this method merge adjacent stack adjustments, i.e. it might erase the previous and/or next instruction. It also greatly simplifies the calls to this function from Prolog- EpilogInserter. Previously, that had a bunch of logic to resume iteration after the call; now it just continues with the returned iterator. Note that this changes the behaviour of PEI a little. Previously, it attempted to re-visit the new instruction created by eliminateCallFramePseudoInstr(). That code was added in r36625, but I can't see any reason for it: the new instructions will obviously not be pseudo instructions, they will not have FrameIndex operands, and we have already accounted for the stack adjustment. Differential Revision: http://reviews.llvm.org/D18627 llvm-svn: 265036 |
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.. | ||
Disassembler | ||
InstPrinter | ||
MCTargetDesc | ||
TargetInfo | ||
CMakeLists.txt | ||
known_gcc_test_failures.txt | ||
LLVMBuild.txt | ||
README.txt | ||
WebAssembly.h | ||
WebAssembly.td | ||
WebAssemblyArgumentMove.cpp | ||
WebAssemblyAsmPrinter.cpp | ||
WebAssemblyCFGStackify.cpp | ||
WebAssemblyFastISel.cpp | ||
WebAssemblyFixIrreducibleControlFlow.cpp | ||
WebAssemblyFrameLowering.cpp | ||
WebAssemblyFrameLowering.h | ||
WebAssemblyInstrAtomics.td | ||
WebAssemblyInstrCall.td | ||
WebAssemblyInstrControl.td | ||
WebAssemblyInstrConv.td | ||
WebAssemblyInstrFloat.td | ||
WebAssemblyInstrFormats.td | ||
WebAssemblyInstrInfo.cpp | ||
WebAssemblyInstrInfo.h | ||
WebAssemblyInstrInfo.td | ||
WebAssemblyInstrInteger.td | ||
WebAssemblyInstrMemory.td | ||
WebAssemblyInstrSIMD.td | ||
WebAssemblyISD.def | ||
WebAssemblyISelDAGToDAG.cpp | ||
WebAssemblyISelLowering.cpp | ||
WebAssemblyISelLowering.h | ||
WebAssemblyLowerBrUnless.cpp | ||
WebAssemblyMachineFunctionInfo.cpp | ||
WebAssemblyMachineFunctionInfo.h | ||
WebAssemblyMCInstLower.cpp | ||
WebAssemblyMCInstLower.h | ||
WebAssemblyOptimizeReturned.cpp | ||
WebAssemblyPeephole.cpp | ||
WebAssemblyPEI.cpp | ||
WebAssemblyRegColoring.cpp | ||
WebAssemblyRegisterInfo.cpp | ||
WebAssemblyRegisterInfo.h | ||
WebAssemblyRegisterInfo.td | ||
WebAssemblyRegNumbering.cpp | ||
WebAssemblyRegStackify.cpp | ||
WebAssemblySelectionDAGInfo.cpp | ||
WebAssemblySelectionDAGInfo.h | ||
WebAssemblySetP2AlignOperands.cpp | ||
WebAssemblyStoreResults.cpp | ||
WebAssemblySubtarget.cpp | ||
WebAssemblySubtarget.h | ||
WebAssemblyTargetMachine.cpp | ||
WebAssemblyTargetMachine.h | ||
WebAssemblyTargetObjectFile.cpp | ||
WebAssemblyTargetObjectFile.h | ||
WebAssemblyTargetTransformInfo.cpp | ||
WebAssemblyTargetTransformInfo.h |
//===-- README.txt - Notes for WebAssembly code gen -----------------------===// This WebAssembly backend is presently in a very early stage of development. The code should build and not break anything else, but don't expect a lot more at this point. For more information on WebAssembly itself, see the design documents: * https://github.com/WebAssembly/design/blob/master/README.md The following documents contain some information on the planned semantics and binary encoding of WebAssembly itself: * https://github.com/WebAssembly/design/blob/master/AstSemantics.md * https://github.com/WebAssembly/design/blob/master/BinaryEncoding.md The backend is built, tested and archived on the following waterfall: https://wasm-stat.us The backend's bringup is done using the GCC torture test suite first since it doesn't require C library support. Current known failures are in known_gcc_test_failures.txt, all other tests should pass. The waterfall will turn red if not. Once most of these pass, further testing will use LLVM's own test suite. The tests can be run locally using: https://github.com/WebAssembly/waterfall/blob/master/src/compile_torture_tests.py //===---------------------------------------------------------------------===// Br, br_if, and br_table instructions can support having a value on the expression stack across the jump (sometimes). We should (a) model this, and (b) extend the stackifier to utilize it. //===---------------------------------------------------------------------===// The min/max operators aren't exactly a<b?a:b because of NaN and negative zero behavior. The ARM target has the same kind of min/max instructions and has implemented optimizations for them; we should do similar optimizations for WebAssembly. //===---------------------------------------------------------------------===// AArch64 runs SeparateConstOffsetFromGEPPass, followed by EarlyCSE and LICM. Would these be useful to run for WebAssembly too? Also, it has an option to run SimplifyCFG after running the AtomicExpand pass. Would this be useful for us too? //===---------------------------------------------------------------------===// Register stackification uses the EXPR_STACK physical register to impose ordering dependencies on instructions with stack operands. This is pessimistic; we should consider alternate ways to model stack dependencies. //===---------------------------------------------------------------------===// Lots of things could be done in WebAssemblyTargetTransformInfo.cpp. Similarly, there are numerous optimization-related hooks that can be overridden in WebAssemblyTargetLowering. //===---------------------------------------------------------------------===// Instead of the OptimizeReturned pass, which should consider preserving the "returned" attribute through to MachineInstrs and extending the StoreResults pass to do this optimization on calls too. That would also let the WebAssemblyPeephole pass clean up dead defs for such calls, as it does for stores. //===---------------------------------------------------------------------===// Consider implementing optimizeSelect, optimizeCompareInstr, optimizeCondBranch, optimizeLoadInstr, and/or getMachineCombinerPatterns. //===---------------------------------------------------------------------===// Find a clean way to fix the problem which leads to the Shrink Wrapping pass being run after the WebAssembly PEI pass. //===---------------------------------------------------------------------===// When setting multiple local variables to the same constant, we currently get code like this: i32.const $4=, 0 i32.const $3=, 0 It could be done with a smaller encoding like this: i32.const $push5=, 0 tee_local $push6=, $4=, $pop5 copy_local $3=, $pop6 //===---------------------------------------------------------------------===// WebAssembly registers are implicitly initialized to zero. Explicit zeroing is therefore often redundant and could be optimized away. //===---------------------------------------------------------------------===// Small indices may use smaller encodings than large indices. WebAssemblyRegColoring and/or WebAssemblyRegRenumbering should sort registers according to their usage frequency to maximize the usage of smaller encodings. //===---------------------------------------------------------------------===// When the last statement in a function body computes the return value, it can just let that value be the exit value of the outermost block, rather than needing an explicit return operation. //===---------------------------------------------------------------------===// Many cases of irreducible control flow could be transformed more optimally than via the transform in WebAssemblyFixIrreducibleControlFlow.cpp. It may also be worthwhile to do transforms before register coloring, particularly when duplicating code, to allow register coloring to be aware of the duplication. //===---------------------------------------------------------------------===//