xyosc/vendor/github.com/ebitengine/purego/struct_arm64.go

// SPDX-License-Identifier: Apache-2.0
// SPDX-FileCopyrightText: 2024 The Ebitengine Authors

package purego

import (
	"math"
	"reflect"
	"unsafe"
)

func getStruct(outType reflect.Type, syscall syscall15Args) (v reflect.Value) {
	outSize := outType.Size()
	switch {
	case outSize == 0:
		return reflect.New(outType).Elem()
	case outSize <= 8:
		r1 := syscall.a1
		if isAllFloats, numFields := isAllSameFloat(outType); isAllFloats {
			r1 = syscall.f1
			if numFields == 2 {
				r1 = syscall.f2<<32 | syscall.f1
			}
		}
		return reflect.NewAt(outType, unsafe.Pointer(&struct{ a uintptr }{r1})).Elem()
	case outSize <= 16:
		r1, r2 := syscall.a1, syscall.a2
		if isAllFloats, numFields := isAllSameFloat(outType); isAllFloats {
			switch numFields {
			case 4:
				r1 = syscall.f2<<32 | syscall.f1
				r2 = syscall.f4<<32 | syscall.f3
			case 3:
				r1 = syscall.f2<<32 | syscall.f1
				r2 = syscall.f3
			case 2:
				r1 = syscall.f1
				r2 = syscall.f2
			default:
				panic("unreachable")
			}
		}
		return reflect.NewAt(outType, unsafe.Pointer(&struct{ a, b uintptr }{r1, r2})).Elem()
	default:
		if isAllFloats, numFields := isAllSameFloat(outType); isAllFloats && numFields <= 4 {
			switch numFields {
			case 4:
				return reflect.NewAt(outType, unsafe.Pointer(&struct{ a, b, c, d uintptr }{syscall.f1, syscall.f2, syscall.f3, syscall.f4})).Elem()
			case 3:
				return reflect.NewAt(outType, unsafe.Pointer(&struct{ a, b, c uintptr }{syscall.f1, syscall.f2, syscall.f3})).Elem()
			default:
				panic("unreachable")
			}
		}
		// create struct from the Go pointer created in arm64_r8
		// weird pointer dereference to circumvent go vet
		return reflect.NewAt(outType, *(*unsafe.Pointer)(unsafe.Pointer(&syscall.arm64_r8))).Elem()
	}
}

// https://github.com/ARM-software/abi-aa/blob/main/sysvabi64/sysvabi64.rst
const (
	_NO_CLASS = 0b00
	_FLOAT    = 0b01
	_INT      = 0b11
)

func addStruct(v reflect.Value, numInts, numFloats, numStack *int, addInt, addFloat, addStack func(uintptr), keepAlive []interface{}) []interface{} {
	if v.Type().Size() == 0 {
		return keepAlive
	}

	if hva, hfa, size := isHVA(v.Type()), isHFA(v.Type()), v.Type().Size(); hva || hfa || size <= 16 {
		// if this doesn't fit entirely in registers then
		// each element goes onto the stack
		if hfa && *numFloats+v.NumField() > numOfFloats {
			*numFloats = numOfFloats
		} else if hva && *numInts+v.NumField() > numOfIntegerRegisters() {
			*numInts = numOfIntegerRegisters()
		}

		placeRegisters(v, addFloat, addInt)
	} else {
		keepAlive = placeStack(v, keepAlive, addInt)
	}
	return keepAlive // the struct was allocated so don't panic
}

func placeRegisters(v reflect.Value, addFloat func(uintptr), addInt func(uintptr)) {
	var val uint64
	var shift byte
	var flushed bool
	class := _NO_CLASS
	var place func(v reflect.Value)
	place = func(v reflect.Value) {
		var numFields int
		if v.Kind() == reflect.Struct {
			numFields = v.Type().NumField()
		} else {
			numFields = v.Type().Len()
		}
		for k := 0; k < numFields; k++ {
			flushed = false
			var f reflect.Value
			if v.Kind() == reflect.Struct {
				f = v.Field(k)
			} else {
				f = v.Index(k)
			}
			if shift >= 64 {
				shift = 0
				flushed = true
				if class == _FLOAT {
					addFloat(uintptr(val))
				} else {
					addInt(uintptr(val))
				}
			}
			switch f.Type().Kind() {
			case reflect.Struct:
				place(f)
			case reflect.Bool:
				if f.Bool() {
					val |= 1
				}
				shift += 8
				class |= _INT
			case reflect.Uint8:
				val |= f.Uint() << shift
				shift += 8
				class |= _INT
			case reflect.Uint16:
				val |= f.Uint() << shift
				shift += 16
				class |= _INT
			case reflect.Uint32:
				val |= f.Uint() << shift
				shift += 32
				class |= _INT
			case reflect.Uint64:
				addInt(uintptr(f.Uint()))
				shift = 0
				flushed = true
			case reflect.Int8:
				val |= uint64(f.Int()&0xFF) << shift
				shift += 8
				class |= _INT
			case reflect.Int16:
				val |= uint64(f.Int()&0xFFFF) << shift
				shift += 16
				class |= _INT
			case reflect.Int32:
				val |= uint64(f.Int()&0xFFFF_FFFF) << shift
				shift += 32
				class |= _INT
			case reflect.Int64:
				addInt(uintptr(f.Int()))
				shift = 0
				flushed = true
			case reflect.Float32:
				if class == _FLOAT {
					addFloat(uintptr(val))
					val = 0
					shift = 0
				}
				val |= uint64(math.Float32bits(float32(f.Float()))) << shift
				shift += 32
				class |= _FLOAT
			case reflect.Float64:
				addFloat(uintptr(math.Float64bits(float64(f.Float()))))
				shift = 0
				flushed = true
			case reflect.Array:
				place(f)
			default:
				panic("purego: unsupported kind " + f.Kind().String())
			}
		}
	}
	place(v)
	if !flushed {
		if class == _FLOAT {
			addFloat(uintptr(val))
		} else {
			addInt(uintptr(val))
		}
	}
}

func placeStack(v reflect.Value, keepAlive []interface{}, addInt func(uintptr)) []interface{} {
	// Struct is too big to be placed in registers.
	// Copy to heap and place the pointer in register
	ptrStruct := reflect.New(v.Type())
	ptrStruct.Elem().Set(v)
	ptr := ptrStruct.Elem().Addr().UnsafePointer()
	keepAlive = append(keepAlive, ptr)
	addInt(uintptr(ptr))
	return keepAlive
}

// isHFA reports a Homogeneous Floating-point Aggregate (HFA) which is a Fundamental Data Type that is a
// Floating-Point type and at most four uniquely addressable members (5.9.5.1 in [Arm64 Calling Convention]).
// This type of struct will be placed more compactly than the individual fields.
//
// [Arm64 Calling Convention]: https://github.com/ARM-software/abi-aa/blob/main/sysvabi64/sysvabi64.rst
func isHFA(t reflect.Type) bool {
	// round up struct size to nearest 8 see section B.4
	structSize := roundUpTo8(t.Size())
	if structSize == 0 || t.NumField() > 4 {
		return false
	}
	first := t.Field(0)
	switch first.Type.Kind() {
	case reflect.Float32, reflect.Float64:
		firstKind := first.Type.Kind()
		for i := 0; i < t.NumField(); i++ {
			if t.Field(i).Type.Kind() != firstKind {
				return false
			}
		}
		return true
	case reflect.Array:
		switch first.Type.Elem().Kind() {
		case reflect.Float32, reflect.Float64:
			return true
		default:
			return false
		}
	case reflect.Struct:
		for i := 0; i < first.Type.NumField(); i++ {
			if !isHFA(first.Type) {
				return false
			}
		}
		return true
	default:
		return false
	}
}

// isHVA reports a Homogeneous Aggregate with a Fundamental Data Type that is a Short-Vector type
// and at most four uniquely addressable members (5.9.5.2 in [Arm64 Calling Convention]).
// A short vector is a machine type that is composed of repeated instances of one fundamental integral or
// floating-point type. It may be 8 or 16 bytes in total size (5.4 in [Arm64 Calling Convention]).
// This type of struct will be placed more compactly than the individual fields.
//
// [Arm64 Calling Convention]: https://github.com/ARM-software/abi-aa/blob/main/sysvabi64/sysvabi64.rst
func isHVA(t reflect.Type) bool {
	// round up struct size to nearest 8 see section B.4
	structSize := roundUpTo8(t.Size())
	if structSize == 0 || (structSize != 8 && structSize != 16) {
		return false
	}
	first := t.Field(0)
	switch first.Type.Kind() {
	case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Int8, reflect.Int16, reflect.Int32:
		firstKind := first.Type.Kind()
		for i := 0; i < t.NumField(); i++ {
			if t.Field(i).Type.Kind() != firstKind {
				return false
			}
		}
		return true
	case reflect.Array:
		switch first.Type.Elem().Kind() {
		case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Int8, reflect.Int16, reflect.Int32:
			return true
		default:
			return false
		}
	default:
		return false
	}
}
add vendor 2024-12-21 17:38:26 +01:00			`// SPDX-License-Identifier: Apache-2.0`
			`// SPDX-FileCopyrightText: 2024 The Ebitengine Authors`

			`package purego`

			`import (`
			`"math"`
			`"reflect"`
			`"unsafe"`
			`)`

			`func getStruct(outType reflect.Type, syscall syscall15Args) (v reflect.Value) {`
			`outSize := outType.Size()`
			`switch {`
			`case outSize == 0:`
			`return reflect.New(outType).Elem()`
			`case outSize <= 8:`
			`r1 := syscall.a1`
			`if isAllFloats, numFields := isAllSameFloat(outType); isAllFloats {`
			`r1 = syscall.f1`
			`if numFields == 2 {`
			`r1 = syscall.f2<<32 \| syscall.f1`
			`}`
			`}`
			`return reflect.NewAt(outType, unsafe.Pointer(&struct{ a uintptr }{r1})).Elem()`
			`case outSize <= 16:`
			`r1, r2 := syscall.a1, syscall.a2`
			`if isAllFloats, numFields := isAllSameFloat(outType); isAllFloats {`
			`switch numFields {`
			`case 4:`
			`r1 = syscall.f2<<32 \| syscall.f1`
			`r2 = syscall.f4<<32 \| syscall.f3`
			`case 3:`
			`r1 = syscall.f2<<32 \| syscall.f1`
			`r2 = syscall.f3`
			`case 2:`
			`r1 = syscall.f1`
			`r2 = syscall.f2`
			`default:`
			`panic("unreachable")`
			`}`
			`}`
			`return reflect.NewAt(outType, unsafe.Pointer(&struct{ a, b uintptr }{r1, r2})).Elem()`
			`default:`
			`if isAllFloats, numFields := isAllSameFloat(outType); isAllFloats && numFields <= 4 {`
			`switch numFields {`
			`case 4:`
			`return reflect.NewAt(outType, unsafe.Pointer(&struct{ a, b, c, d uintptr }{syscall.f1, syscall.f2, syscall.f3, syscall.f4})).Elem()`
			`case 3:`
			`return reflect.NewAt(outType, unsafe.Pointer(&struct{ a, b, c uintptr }{syscall.f1, syscall.f2, syscall.f3})).Elem()`
			`default:`
			`panic("unreachable")`
			`}`
			`}`
			`// create struct from the Go pointer created in arm64_r8`
			`// weird pointer dereference to circumvent go vet`
			`return reflect.NewAt(outType, (unsafe.Pointer)(unsafe.Pointer(&syscall.arm64_r8))).Elem()`
			`}`
			`}`

			`// https://github.com/ARM-software/abi-aa/blob/main/sysvabi64/sysvabi64.rst`
			`const (`
			`_NO_CLASS = 0b00`
			`_FLOAT = 0b01`
			`_INT = 0b11`
			`)`

			`func addStruct(v reflect.Value, numInts, numFloats, numStack *int, addInt, addFloat, addStack func(uintptr), keepAlive []interface{}) []interface{} {`
			`if v.Type().Size() == 0 {`
			`return keepAlive`
			`}`

			`if hva, hfa, size := isHVA(v.Type()), isHFA(v.Type()), v.Type().Size(); hva \|\| hfa \|\| size <= 16 {`
			`// if this doesn't fit entirely in registers then`
			`// each element goes onto the stack`
			`if hfa && *numFloats+v.NumField() > numOfFloats {`
			`*numFloats = numOfFloats`
			`} else if hva && *numInts+v.NumField() > numOfIntegerRegisters() {`
			`*numInts = numOfIntegerRegisters()`
			`}`

			`placeRegisters(v, addFloat, addInt)`
			`} else {`
			`keepAlive = placeStack(v, keepAlive, addInt)`
			`}`
			`return keepAlive // the struct was allocated so don't panic`
			`}`

			`func placeRegisters(v reflect.Value, addFloat func(uintptr), addInt func(uintptr)) {`
			`var val uint64`
			`var shift byte`
			`var flushed bool`
			`class := _NO_CLASS`
			`var place func(v reflect.Value)`
			`place = func(v reflect.Value) {`
			`var numFields int`
			`if v.Kind() == reflect.Struct {`
			`numFields = v.Type().NumField()`
			`} else {`
			`numFields = v.Type().Len()`
			`}`
			`for k := 0; k < numFields; k++ {`
			`flushed = false`
			`var f reflect.Value`
			`if v.Kind() == reflect.Struct {`
			`f = v.Field(k)`
			`} else {`
			`f = v.Index(k)`
			`}`
			`if shift >= 64 {`
			`shift = 0`
			`flushed = true`
			`if class == _FLOAT {`
			`addFloat(uintptr(val))`
			`} else {`
			`addInt(uintptr(val))`
			`}`
			`}`
			`switch f.Type().Kind() {`
			`case reflect.Struct:`
			`place(f)`
			`case reflect.Bool:`
			`if f.Bool() {`
			`val \|= 1`
			`}`
			`shift += 8`
			`class \|= _INT`
			`case reflect.Uint8:`
			`val \|= f.Uint() << shift`
			`shift += 8`
			`class \|= _INT`
			`case reflect.Uint16:`
			`val \|= f.Uint() << shift`
			`shift += 16`
			`class \|= _INT`
			`case reflect.Uint32:`
			`val \|= f.Uint() << shift`
			`shift += 32`
			`class \|= _INT`
			`case reflect.Uint64:`
			`addInt(uintptr(f.Uint()))`
			`shift = 0`
			`flushed = true`
			`case reflect.Int8:`
			`val \|= uint64(f.Int()&0xFF) << shift`
			`shift += 8`
			`class \|= _INT`
			`case reflect.Int16:`
			`val \|= uint64(f.Int()&0xFFFF) << shift`
			`shift += 16`
			`class \|= _INT`
			`case reflect.Int32:`
			`val \|= uint64(f.Int()&0xFFFF_FFFF) << shift`
			`shift += 32`
			`class \|= _INT`
			`case reflect.Int64:`
			`addInt(uintptr(f.Int()))`
			`shift = 0`
			`flushed = true`
			`case reflect.Float32:`
			`if class == _FLOAT {`
			`addFloat(uintptr(val))`
			`val = 0`
			`shift = 0`
			`}`
			`val \|= uint64(math.Float32bits(float32(f.Float()))) << shift`
			`shift += 32`
			`class \|= _FLOAT`
			`case reflect.Float64:`
			`addFloat(uintptr(math.Float64bits(float64(f.Float()))))`
			`shift = 0`
			`flushed = true`
			`case reflect.Array:`
			`place(f)`
			`default:`
			`panic("purego: unsupported kind " + f.Kind().String())`
			`}`
			`}`
			`}`
			`place(v)`
			`if !flushed {`
			`if class == _FLOAT {`
			`addFloat(uintptr(val))`
			`} else {`
			`addInt(uintptr(val))`
			`}`
			`}`
			`}`

			`func placeStack(v reflect.Value, keepAlive []interface{}, addInt func(uintptr)) []interface{} {`
			`// Struct is too big to be placed in registers.`
			`// Copy to heap and place the pointer in register`
			`ptrStruct := reflect.New(v.Type())`
			`ptrStruct.Elem().Set(v)`
			`ptr := ptrStruct.Elem().Addr().UnsafePointer()`
			`keepAlive = append(keepAlive, ptr)`
			`addInt(uintptr(ptr))`
			`return keepAlive`
			`}`

			`// isHFA reports a Homogeneous Floating-point Aggregate (HFA) which is a Fundamental Data Type that is a`
			`// Floating-Point type and at most four uniquely addressable members (5.9.5.1 in [Arm64 Calling Convention]).`
			`// This type of struct will be placed more compactly than the individual fields.`
			`//`
			`// [Arm64 Calling Convention]: https://github.com/ARM-software/abi-aa/blob/main/sysvabi64/sysvabi64.rst`
			`func isHFA(t reflect.Type) bool {`
			`// round up struct size to nearest 8 see section B.4`
			`structSize := roundUpTo8(t.Size())`
			`if structSize == 0 \|\| t.NumField() > 4 {`
			`return false`
			`}`
			`first := t.Field(0)`
			`switch first.Type.Kind() {`
			`case reflect.Float32, reflect.Float64:`
			`firstKind := first.Type.Kind()`
			`for i := 0; i < t.NumField(); i++ {`
			`if t.Field(i).Type.Kind() != firstKind {`
			`return false`
			`}`
			`}`
			`return true`
			`case reflect.Array:`
			`switch first.Type.Elem().Kind() {`
			`case reflect.Float32, reflect.Float64:`
			`return true`
			`default:`
			`return false`
			`}`
			`case reflect.Struct:`
			`for i := 0; i < first.Type.NumField(); i++ {`
			`if !isHFA(first.Type) {`
			`return false`
			`}`
			`}`
			`return true`
			`default:`
			`return false`
			`}`
			`}`

			`// isHVA reports a Homogeneous Aggregate with a Fundamental Data Type that is a Short-Vector type`
			`// and at most four uniquely addressable members (5.9.5.2 in [Arm64 Calling Convention]).`
			`// A short vector is a machine type that is composed of repeated instances of one fundamental integral or`
			`// floating-point type. It may be 8 or 16 bytes in total size (5.4 in [Arm64 Calling Convention]).`
			`// This type of struct will be placed more compactly than the individual fields.`
			`//`
			`// [Arm64 Calling Convention]: https://github.com/ARM-software/abi-aa/blob/main/sysvabi64/sysvabi64.rst`
			`func isHVA(t reflect.Type) bool {`
			`// round up struct size to nearest 8 see section B.4`
			`structSize := roundUpTo8(t.Size())`
			`if structSize == 0 \|\| (structSize != 8 && structSize != 16) {`
			`return false`
			`}`
			`first := t.Field(0)`
			`switch first.Type.Kind() {`
			`case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Int8, reflect.Int16, reflect.Int32:`
			`firstKind := first.Type.Kind()`
			`for i := 0; i < t.NumField(); i++ {`
			`if t.Field(i).Type.Kind() != firstKind {`
			`return false`
			`}`
			`}`
			`return true`
			`case reflect.Array:`
			`switch first.Type.Elem().Kind() {`
			`case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Int8, reflect.Int16, reflect.Int32:`
			`return true`
			`default:`
			`return false`
			`}`
			`default:`
			`return false`
			`}`
			`}`