Example #1
0
func (tm *llvmTypeMap) basicLLVMType(b *types.Basic) llvm.Type {
	switch b.Kind() {
	case types.Bool:
		return llvm.Int1Type()
	case types.Int8, types.Uint8:
		return llvm.Int8Type()
	case types.Int16, types.Uint16:
		return llvm.Int16Type()
	case types.Int32, types.Uint32:
		return llvm.Int32Type()
	case types.Uint, types.Int:
		return tm.inttype
	case types.Int64, types.Uint64:
		return llvm.Int64Type()
	case types.Float32:
		return llvm.FloatType()
	case types.Float64:
		return llvm.DoubleType()
	case types.UnsafePointer, types.Uintptr:
		return tm.target.IntPtrType()
	case types.Complex64:
		f32 := llvm.FloatType()
		elements := []llvm.Type{f32, f32}
		return llvm.StructType(elements, false)
	case types.Complex128:
		f64 := llvm.DoubleType()
		elements := []llvm.Type{f64, f64}
		return llvm.StructType(elements, false)
	case types.String:
		i8ptr := llvm.PointerType(llvm.Int8Type(), 0)
		elements := []llvm.Type{i8ptr, tm.inttype}
		return llvm.StructType(elements, false)
	}
	panic(fmt.Sprint("unhandled kind: ", b.Kind))
}
Example #2
0
File: value.go Project: rvedam/llgo
func (v *LLVMValue) Convert(dsttyp types.Type) Value {
	b := v.compiler.builder

	// If it's a stack allocated value, we'll want to compare the
	// value type, not the pointer type.
	srctyp := v.typ

	// Get the underlying type, if any.
	origdsttyp := dsttyp
	dsttyp = dsttyp.Underlying()
	srctyp = srctyp.Underlying()

	// Identical (underlying) types? Just swap in the destination type.
	if types.Identical(srctyp, dsttyp) {
		return v.compiler.NewValue(v.LLVMValue(), origdsttyp)
	}

	// Both pointer types with identical underlying types? Same as above.
	if srctyp, ok := srctyp.(*types.Pointer); ok {
		if dsttyp, ok := dsttyp.(*types.Pointer); ok {
			srctyp := srctyp.Elem().Underlying()
			dsttyp := dsttyp.Elem().Underlying()
			if types.Identical(srctyp, dsttyp) {
				return v.compiler.NewValue(v.LLVMValue(), origdsttyp)
			}
		}
	}

	byteslice := types.NewSlice(types.Typ[types.Byte])
	runeslice := types.NewSlice(types.Typ[types.Rune])

	// string ->
	if isString(srctyp) {
		// (untyped) string -> string
		// XXX should untyped strings be able to escape go/types?
		if isString(dsttyp) {
			return v.compiler.NewValue(v.LLVMValue(), origdsttyp)
		}

		// string -> []byte
		if types.Identical(dsttyp, byteslice) {
			c := v.compiler
			value := v.LLVMValue()
			strdata := c.builder.CreateExtractValue(value, 0, "")
			strlen := c.builder.CreateExtractValue(value, 1, "")

			// Data must be copied, to prevent changes in
			// the byte slice from mutating the string.
			newdata := c.createMalloc(strlen)
			memcpy := c.runtime.memcpy.LLVMValue()
			c.builder.CreateCall(memcpy, []llvm.Value{
				newdata,
				c.builder.CreatePtrToInt(strdata, c.target.IntPtrType(), ""),
				strlen,
			}, "")
			strdata = c.builder.CreateIntToPtr(newdata, strdata.Type(), "")

			struct_ := llvm.Undef(c.types.ToLLVM(byteslice))
			struct_ = c.builder.CreateInsertValue(struct_, strdata, 0, "")
			struct_ = c.builder.CreateInsertValue(struct_, strlen, 1, "")
			struct_ = c.builder.CreateInsertValue(struct_, strlen, 2, "")
			return c.NewValue(struct_, byteslice)
		}

		// string -> []rune
		if types.Identical(dsttyp, runeslice) {
			return v.stringToRuneSlice()
		}
	}

	// []byte -> string
	if types.Identical(srctyp, byteslice) && isString(dsttyp) {
		c := v.compiler
		value := v.LLVMValue()
		data := c.builder.CreateExtractValue(value, 0, "")
		len := c.builder.CreateExtractValue(value, 1, "")

		// Data must be copied, to prevent changes in
		// the byte slice from mutating the string.
		newdata := c.createMalloc(len)
		memcpy := c.runtime.memcpy.LLVMValue()
		c.builder.CreateCall(memcpy, []llvm.Value{
			newdata,
			c.builder.CreatePtrToInt(data, c.target.IntPtrType(), ""),
			len,
		}, "")
		data = c.builder.CreateIntToPtr(newdata, data.Type(), "")

		struct_ := llvm.Undef(c.types.ToLLVM(types.Typ[types.String]))
		struct_ = c.builder.CreateInsertValue(struct_, data, 0, "")
		struct_ = c.builder.CreateInsertValue(struct_, len, 1, "")
		return c.NewValue(struct_, types.Typ[types.String])
	}

	// []rune -> string
	if types.Identical(srctyp, runeslice) && isString(dsttyp) {
		return v.runeSliceToString()
	}

	// rune -> string
	if isString(dsttyp) && isInteger(srctyp) {
		return v.runeToString()
	}

	// TODO other special conversions?
	llvm_type := v.compiler.types.ToLLVM(dsttyp)

	// Unsafe pointer conversions.
	if dsttyp == types.Typ[types.UnsafePointer] { // X -> unsafe.Pointer
		if _, isptr := srctyp.(*types.Pointer); isptr {
			value := b.CreatePtrToInt(v.LLVMValue(), llvm_type, "")
			return v.compiler.NewValue(value, origdsttyp)
		} else if srctyp == types.Typ[types.Uintptr] {
			return v.compiler.NewValue(v.LLVMValue(), origdsttyp)
		}
	} else if srctyp == types.Typ[types.UnsafePointer] { // unsafe.Pointer -> X
		if _, isptr := dsttyp.(*types.Pointer); isptr {
			value := b.CreateIntToPtr(v.LLVMValue(), llvm_type, "")
			return v.compiler.NewValue(value, origdsttyp)
		} else if dsttyp == types.Typ[types.Uintptr] {
			return v.compiler.NewValue(v.LLVMValue(), origdsttyp)
		}
	}

	lv := v.LLVMValue()
	srcType := lv.Type()
	switch srcType.TypeKind() {
	case llvm.IntegerTypeKind:
		switch llvm_type.TypeKind() {
		case llvm.IntegerTypeKind:
			srcBits := srcType.IntTypeWidth()
			dstBits := llvm_type.IntTypeWidth()
			delta := srcBits - dstBits
			switch {
			case delta < 0:
				if !isUnsigned(srctyp) {
					lv = b.CreateSExt(lv, llvm_type, "")
				} else {
					lv = b.CreateZExt(lv, llvm_type, "")
				}
			case delta > 0:
				lv = b.CreateTrunc(lv, llvm_type, "")
			}
			return v.compiler.NewValue(lv, origdsttyp)
		case llvm.FloatTypeKind, llvm.DoubleTypeKind:
			if !isUnsigned(v.Type()) {
				lv = b.CreateSIToFP(lv, llvm_type, "")
			} else {
				lv = b.CreateUIToFP(lv, llvm_type, "")
			}
			return v.compiler.NewValue(lv, origdsttyp)
		}
	case llvm.DoubleTypeKind:
		switch llvm_type.TypeKind() {
		case llvm.FloatTypeKind:
			lv = b.CreateFPTrunc(lv, llvm_type, "")
			return v.compiler.NewValue(lv, origdsttyp)
		case llvm.IntegerTypeKind:
			if !isUnsigned(dsttyp) {
				lv = b.CreateFPToSI(lv, llvm_type, "")
			} else {
				lv = b.CreateFPToUI(lv, llvm_type, "")
			}
			return v.compiler.NewValue(lv, origdsttyp)
		}
	case llvm.FloatTypeKind:
		switch llvm_type.TypeKind() {
		case llvm.DoubleTypeKind:
			lv = b.CreateFPExt(lv, llvm_type, "")
			return v.compiler.NewValue(lv, origdsttyp)
		case llvm.IntegerTypeKind:
			if !isUnsigned(dsttyp) {
				lv = b.CreateFPToSI(lv, llvm_type, "")
			} else {
				lv = b.CreateFPToUI(lv, llvm_type, "")
			}
			return v.compiler.NewValue(lv, origdsttyp)
		}
	}

	// Complex -> complex. Complexes are only convertible to other
	// complexes, contant conversions aside. So we can just check the
	// source type here; given that the types are not identical
	// (checked above), we can assume the destination type is the alternate
	// complex type.
	if isComplex(srctyp) {
		var fpcast func(llvm.Builder, llvm.Value, llvm.Type, string) llvm.Value
		var fptype llvm.Type
		if srctyp == types.Typ[types.Complex64] {
			fpcast = (llvm.Builder).CreateFPExt
			fptype = llvm.DoubleType()
		} else {
			fpcast = (llvm.Builder).CreateFPTrunc
			fptype = llvm.FloatType()
		}
		if fpcast != nil {
			realv := b.CreateExtractValue(lv, 0, "")
			imagv := b.CreateExtractValue(lv, 1, "")
			realv = fpcast(b, realv, fptype, "")
			imagv = fpcast(b, imagv, fptype, "")
			lv = llvm.Undef(v.compiler.types.ToLLVM(dsttyp))
			lv = b.CreateInsertValue(lv, realv, 0, "")
			lv = b.CreateInsertValue(lv, imagv, 1, "")
			return v.compiler.NewValue(lv, origdsttyp)
		}
	}
	panic(fmt.Sprintf("unimplemented conversion: %s (%s) -> %s", v.typ, lv.Type(), origdsttyp))
}