package compiler // This file contains helper functions to create calls to LLVM intrinsics. import ( "go/token" "strconv" "strings" "tinygo.org/x/go-llvm" ) // Define unimplemented intrinsic functions. // // Some functions are either normally implemented in Go assembly (like // sync/atomic functions) or intentionally left undefined to be implemented // directly in the compiler (like runtime/volatile functions). Either way, look // for these and implement them if this is the case. func (b *builder) defineIntrinsicFunction() { name := b.fn.RelString(nil) switch { case name == "runtime.memcpy" || name == "runtime.memmove": b.createMemoryCopyImpl() case name == "runtime.memzero": b.createMemoryZeroImpl() case name == "runtime.KeepAlive": b.createKeepAliveImpl() case strings.HasPrefix(name, "runtime/volatile.Load"): b.createVolatileLoad() case strings.HasPrefix(name, "runtime/volatile.Store"): b.createVolatileStore() case strings.HasPrefix(name, "sync/atomic.") && token.IsExported(b.fn.Name()): b.createFunctionStart(true) returnValue := b.createAtomicOp(b.fn.Name()) if !returnValue.IsNil() { b.CreateRet(returnValue) } else { b.CreateRetVoid() } } } // createMemoryCopyImpl creates a call to a builtin LLVM memcpy or memmove // function, declaring this function if needed. These calls are treated // specially by optimization passes possibly resulting in better generated code, // and will otherwise be lowered to regular libc memcpy/memmove calls. func (b *builder) createMemoryCopyImpl() { b.createFunctionStart(true) fnName := "llvm." + b.fn.Name() + ".p0.p0.i" + strconv.Itoa(b.uintptrType.IntTypeWidth()) llvmFn := b.mod.NamedFunction(fnName) if llvmFn.IsNil() { fnType := llvm.FunctionType(b.ctx.VoidType(), []llvm.Type{b.dataPtrType, b.dataPtrType, b.uintptrType, b.ctx.Int1Type()}, false) llvmFn = llvm.AddFunction(b.mod, fnName, fnType) } var params []llvm.Value for _, param := range b.fn.Params { params = append(params, b.getValue(param, getPos(b.fn))) } params = append(params, llvm.ConstInt(b.ctx.Int1Type(), 0, false)) b.CreateCall(llvmFn.GlobalValueType(), llvmFn, params, "") b.CreateRetVoid() } // createMemoryZeroImpl creates calls to llvm.memset.* to zero a block of // memory, declaring the function if needed. These calls will be lowered to // regular libc memset calls if they aren't optimized out in a different way. func (b *builder) createMemoryZeroImpl() { b.createFunctionStart(true) llvmFn := b.getMemsetFunc() params := []llvm.Value{ b.getValue(b.fn.Params[0], getPos(b.fn)), llvm.ConstInt(b.ctx.Int8Type(), 0, false), b.getValue(b.fn.Params[1], getPos(b.fn)), llvm.ConstInt(b.ctx.Int1Type(), 0, false), } b.CreateCall(llvmFn.GlobalValueType(), llvmFn, params, "") b.CreateRetVoid() } // Return the llvm.memset.p0.i8 function declaration. func (c *compilerContext) getMemsetFunc() llvm.Value { fnName := "llvm.memset.p0.i" + strconv.Itoa(c.uintptrType.IntTypeWidth()) llvmFn := c.mod.NamedFunction(fnName) if llvmFn.IsNil() { fnType := llvm.FunctionType(c.ctx.VoidType(), []llvm.Type{c.dataPtrType, c.ctx.Int8Type(), c.uintptrType, c.ctx.Int1Type()}, false) llvmFn = llvm.AddFunction(c.mod, fnName, fnType) } return llvmFn } // createKeepAlive creates the runtime.KeepAlive function. It is implemented // using inline assembly. func (b *builder) createKeepAliveImpl() { b.createFunctionStart(true) // Get the underlying value of the interface value. interfaceValue := b.getValue(b.fn.Params[0], getPos(b.fn)) pointerValue := b.CreateExtractValue(interfaceValue, 1, "") // Create an equivalent of the following C code, which is basically just a // nop but ensures the pointerValue is kept alive: // // __asm__ __volatile__("" : : "r"(pointerValue)) // // It should be portable to basically everything as the "r" register type // exists basically everywhere. asmType := llvm.FunctionType(b.ctx.VoidType(), []llvm.Type{b.dataPtrType}, false) asmFn := llvm.InlineAsm(asmType, "", "r", true, false, 0, false) b.createCall(asmType, asmFn, []llvm.Value{pointerValue}, "") b.CreateRetVoid() } var mathToLLVMMapping = map[string]string{ "math.Ceil": "llvm.ceil.f64", "math.Exp": "llvm.exp.f64", "math.Exp2": "llvm.exp2.f64", "math.Floor": "llvm.floor.f64", "math.Log": "llvm.log.f64", "math.Sqrt": "llvm.sqrt.f64", "math.Trunc": "llvm.trunc.f64", } // defineMathOp defines a math function body as a call to a LLVM intrinsic, // instead of the regular Go implementation. This allows LLVM to reason about // the math operation and (depending on the architecture) allows it to lower the // operation to very fast floating point instructions. If this is not possible, // LLVM will emit a call to a libm function that implements the same operation. // // One example of an optimization that LLVM can do is to convert // float32(math.Sqrt(float64(v))) to a 32-bit floating point operation, which is // beneficial on architectures where 64-bit floating point operations are (much) // more expensive than 32-bit ones. func (b *builder) defineMathOp() { b.createFunctionStart(true) llvmName := mathToLLVMMapping[b.fn.RelString(nil)] if llvmName == "" { panic("unreachable: unknown math operation") // sanity check } llvmFn := b.mod.NamedFunction(llvmName) if llvmFn.IsNil() { // The intrinsic doesn't exist yet, so declare it. // At the moment, all supported intrinsics have the form "double // foo(double %x)" so we can hardcode the signature here. llvmType := llvm.FunctionType(b.ctx.DoubleType(), []llvm.Type{b.ctx.DoubleType()}, false) llvmFn = llvm.AddFunction(b.mod, llvmName, llvmType) } // Create a call to the intrinsic. args := make([]llvm.Value, len(b.fn.Params)) for i, param := range b.fn.Params { args[i] = b.getValue(param, getPos(b.fn)) } result := b.CreateCall(llvmFn.GlobalValueType(), llvmFn, args, "") b.CreateRet(result) } // Implement most math/bits functions. // // This implements all the functions that operate on bits. It does not yet // implement the arithmetic functions (like bits.Add), which also have LLVM // intrinsics. func (b *builder) defineMathBitsIntrinsic() bool { if b.fn.Pkg.Pkg.Path() != "math/bits" { return false } name := b.fn.Name() switch name { case "LeadingZeros", "LeadingZeros8", "LeadingZeros16", "LeadingZeros32", "LeadingZeros64", "TrailingZeros", "TrailingZeros8", "TrailingZeros16", "TrailingZeros32", "TrailingZeros64": b.createFunctionStart(true) param := b.getValue(b.fn.Params[0], b.fn.Pos()) valueType := param.Type() var intrinsicName string if strings.HasPrefix(name, "Leading") { // LeadingZeros intrinsicName = "llvm.ctlz.i" + strconv.Itoa(valueType.IntTypeWidth()) } else { // TrailingZeros intrinsicName = "llvm.cttz.i" + strconv.Itoa(valueType.IntTypeWidth()) } llvmFn := b.mod.NamedFunction(intrinsicName) llvmFnType := llvm.FunctionType(valueType, []llvm.Type{valueType, b.ctx.Int1Type()}, false) if llvmFn.IsNil() { llvmFn = llvm.AddFunction(b.mod, intrinsicName, llvmFnType) } result := b.createCall(llvmFnType, llvmFn, []llvm.Value{ param, llvm.ConstInt(b.ctx.Int1Type(), 0, false), }, "") result = b.createZExtOrTrunc(result, b.intType) b.CreateRet(result) return true case "Len", "Len8", "Len16", "Len32", "Len64": // bits.Len can be implemented as: // (unsafe.Sizeof(v) * 8) - bits.LeadingZeros(n) // Not sure why this isn't already done in the standard library, as it // is much simpler than a lookup table. b.createFunctionStart(true) param := b.getValue(b.fn.Params[0], b.fn.Pos()) valueType := param.Type() valueBits := valueType.IntTypeWidth() intrinsicName := "llvm.ctlz.i" + strconv.Itoa(valueBits) llvmFn := b.mod.NamedFunction(intrinsicName) llvmFnType := llvm.FunctionType(valueType, []llvm.Type{valueType, b.ctx.Int1Type()}, false) if llvmFn.IsNil() { llvmFn = llvm.AddFunction(b.mod, intrinsicName, llvmFnType) } result := b.createCall(llvmFnType, llvmFn, []llvm.Value{ param, llvm.ConstInt(b.ctx.Int1Type(), 0, false), }, "") result = b.createZExtOrTrunc(result, b.intType) maxLen := llvm.ConstInt(b.intType, uint64(valueBits), false) // number of bits in the value result = b.CreateSub(maxLen, result, "") b.CreateRet(result) return true case "OnesCount", "OnesCount8", "OnesCount16", "OnesCount32", "OnesCount64": b.createFunctionStart(true) param := b.getValue(b.fn.Params[0], b.fn.Pos()) valueType := param.Type() intrinsicName := "llvm.ctpop.i" + strconv.Itoa(valueType.IntTypeWidth()) llvmFn := b.mod.NamedFunction(intrinsicName) llvmFnType := llvm.FunctionType(valueType, []llvm.Type{valueType}, false) if llvmFn.IsNil() { llvmFn = llvm.AddFunction(b.mod, intrinsicName, llvmFnType) } result := b.createCall(llvmFnType, llvmFn, []llvm.Value{param}, "") result = b.createZExtOrTrunc(result, b.intType) b.CreateRet(result) return true case "Reverse", "Reverse8", "Reverse16", "Reverse32", "Reverse64", "ReverseBytes", "ReverseBytes16", "ReverseBytes32", "ReverseBytes64": b.createFunctionStart(true) param := b.getValue(b.fn.Params[0], b.fn.Pos()) valueType := param.Type() var intrinsicName string if strings.HasPrefix(name, "ReverseBytes") { intrinsicName = "llvm.bswap.i" + strconv.Itoa(valueType.IntTypeWidth()) } else { // Reverse intrinsicName = "llvm.bitreverse.i" + strconv.Itoa(valueType.IntTypeWidth()) } llvmFn := b.mod.NamedFunction(intrinsicName) llvmFnType := llvm.FunctionType(valueType, []llvm.Type{valueType}, false) if llvmFn.IsNil() { llvmFn = llvm.AddFunction(b.mod, intrinsicName, llvmFnType) } result := b.createCall(llvmFnType, llvmFn, []llvm.Value{param}, "") b.CreateRet(result) return true case "RotateLeft", "RotateLeft8", "RotateLeft16", "RotateLeft32", "RotateLeft64": // Warning: the documentation says these functions must be constant time. // I do not think LLVM guarantees this, but there's a good chance LLVM // already recognized the rotate instruction so it probably won't get // any _worse_ by implementing these rotate functions. b.createFunctionStart(true) x := b.getValue(b.fn.Params[0], b.fn.Pos()) k := b.getValue(b.fn.Params[1], b.fn.Pos()) valueType := x.Type() intrinsicName := "llvm.fshl.i" + strconv.Itoa(valueType.IntTypeWidth()) llvmFn := b.mod.NamedFunction(intrinsicName) llvmFnType := llvm.FunctionType(valueType, []llvm.Type{valueType, valueType, valueType}, false) if llvmFn.IsNil() { llvmFn = llvm.AddFunction(b.mod, intrinsicName, llvmFnType) } k = b.createZExtOrTrunc(k, valueType) result := b.createCall(llvmFnType, llvmFn, []llvm.Value{x, x, k}, "") b.CreateRet(result) return true default: return false } }