src/cmd/internal/obj/s390x/rotate.go - go - Git at Google

 // Copyright 2019 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package s390x

 import (
 	"math/bits"
 )

 // RotateParams represents the immediates required for a "rotate
 // then ... selected bits instruction".
 //
 // The Start and End values are the indexes that represent
 // the masked region. They are inclusive and are in big-
 // endian order (bit 0 is the MSB, bit 63 is the LSB). They
 // may wrap around.
 //
 // Some examples:
 //
 // Masked region             | Start | End
 // --------------------------+-------+----
 // 0x00_00_00_00_00_00_00_0f | 60    | 63
 // 0xf0_00_00_00_00_00_00_00 | 0     | 3
 // 0xf0_00_00_00_00_00_00_0f | 60    | 3
 //
 // The Amount value represents the amount to rotate the
 // input left by. Note that this rotation is performed
 // before the masked region is used.
 type RotateParams struct {
 	Start  uint8 // big-endian start bit index [0..63]
 	End    uint8 // big-endian end bit index [0..63]
 	Amount uint8 // amount to rotate left
 }

 // NewRotateParams creates a set of parameters representing a
 // rotation left by the amount provided and a selection of the bits
 // between the provided start and end indexes (inclusive).
 //
 // The start and end indexes and the rotation amount must all
 // be in the range 0-63 inclusive or this function will panic.
 func NewRotateParams(start, end, amount uint8) RotateParams {
 	if start&^63 != 0 {
 		panic("start out of bounds")
 	}
 	if end&^63 != 0 {
 		panic("end out of bounds")
 	}
 	if amount&^63 != 0 {
 		panic("amount out of bounds")
 	}
 	return RotateParams{
 		Start:  start,
 		End:    end,
 		Amount: amount,
 	}
 }

 // RotateLeft generates a new set of parameters with the rotation amount
 // increased by the given value. The selected bits are left unchanged.
 func (r RotateParams) RotateLeft(amount uint8) RotateParams {
 	r.Amount += amount
 	r.Amount &= 63
 	return r
 }

 // OutMask provides a mask representing the selected bits.
 func (r RotateParams) OutMask() uint64 {
 	// Note: z must be unsigned for bootstrap compiler
 	z := uint8(63-r.End+r.Start) & 63 // number of zero bits in mask
 	return bits.RotateLeft64(^uint64(0)<<z, -int(r.Start))
 }

 // InMask provides a mask representing the selected bits relative
 // to the source value (i.e. pre-rotation).
 func (r RotateParams) InMask() uint64 {
 	return bits.RotateLeft64(r.OutMask(), -int(r.Amount))
 }

 // OutMerge tries to generate a new set of parameters representing
 // the intersection between the selected bits and the provided mask.
 // If the intersection is unrepresentable (0 or not contiguous) nil
 // will be returned.
 func (r RotateParams) OutMerge(mask uint64) *RotateParams {
 	mask &= r.OutMask()
 	if mask == 0 {
 		return nil
 	}

 	// normalize the mask so that the set bits are left aligned
 	o := bits.LeadingZeros64(^mask)
 	mask = bits.RotateLeft64(mask, o)
 	z := bits.LeadingZeros64(mask)
 	mask = bits.RotateLeft64(mask, z)

 	// check that the normalized mask is contiguous
 	l := bits.LeadingZeros64(^mask)
 	if l+bits.TrailingZeros64(mask) != 64 {
 		return nil
 	}

 	// update start and end positions (rotation amount remains the same)
 	r.Start = uint8(o+z) & 63
 	r.End = (r.Start + uint8(l) - 1) & 63
 	return &r
 }

 // InMerge tries to generate a new set of parameters representing
 // the intersection between the selected bits and the provided mask
 // as applied to the source value (i.e. pre-rotation).
 // If the intersection is unrepresentable (0 or not contiguous) nil
 // will be returned.
 func (r RotateParams) InMerge(mask uint64) *RotateParams {
 	return r.OutMerge(bits.RotateLeft64(mask, int(r.Amount)))
 }

 func (RotateParams) CanBeAnSSAAux() {}
	// Copyright 2019 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package s390x

	import (
	"math/bits"
	)

	// RotateParams represents the immediates required for a "rotate
	// then ... selected bits instruction".
	//
	// The Start and End values are the indexes that represent
	// the masked region. They are inclusive and are in big-
	// endian order (bit 0 is the MSB, bit 63 is the LSB). They
	// may wrap around.
	//
	// Some examples:
	//
	// Masked region \| Start \| End
	// --------------------------+-------+----
	// 0x00_00_00_00_00_00_00_0f \| 60 \| 63
	// 0xf0_00_00_00_00_00_00_00 \| 0 \| 3
	// 0xf0_00_00_00_00_00_00_0f \| 60 \| 3
	//
	// The Amount value represents the amount to rotate the
	// input left by. Note that this rotation is performed
	// before the masked region is used.
	type RotateParams struct {
	Start uint8 // big-endian start bit index [0..63]
	End uint8 // big-endian end bit index [0..63]
	Amount uint8 // amount to rotate left
	}

	// NewRotateParams creates a set of parameters representing a
	// rotation left by the amount provided and a selection of the bits
	// between the provided start and end indexes (inclusive).
	//
	// The start and end indexes and the rotation amount must all
	// be in the range 0-63 inclusive or this function will panic.
	func NewRotateParams(start, end, amount uint8) RotateParams {
	if start&^63 != 0 {
	panic("start out of bounds")
	}
	if end&^63 != 0 {
	panic("end out of bounds")
	}
	if amount&^63 != 0 {
	panic("amount out of bounds")
	}
	return RotateParams{
	Start: start,
	End: end,
	Amount: amount,
	}
	}

	// RotateLeft generates a new set of parameters with the rotation amount
	// increased by the given value. The selected bits are left unchanged.
	func (r RotateParams) RotateLeft(amount uint8) RotateParams {
	r.Amount += amount
	r.Amount &= 63
	return r
	}

	// OutMask provides a mask representing the selected bits.
	func (r RotateParams) OutMask() uint64 {
	// Note: z must be unsigned for bootstrap compiler
	z := uint8(63-r.End+r.Start) & 63 // number of zero bits in mask
	return bits.RotateLeft64(^uint64(0)<<z, -int(r.Start))
	}

	// InMask provides a mask representing the selected bits relative
	// to the source value (i.e. pre-rotation).
	func (r RotateParams) InMask() uint64 {
	return bits.RotateLeft64(r.OutMask(), -int(r.Amount))
	}

	// OutMerge tries to generate a new set of parameters representing
	// the intersection between the selected bits and the provided mask.
	// If the intersection is unrepresentable (0 or not contiguous) nil
	// will be returned.
	func (r RotateParams) OutMerge(mask uint64) *RotateParams {
	mask &= r.OutMask()
	if mask == 0 {
	return nil
	}

	// normalize the mask so that the set bits are left aligned
	o := bits.LeadingZeros64(^mask)
	mask = bits.RotateLeft64(mask, o)
	z := bits.LeadingZeros64(mask)
	mask = bits.RotateLeft64(mask, z)

	// check that the normalized mask is contiguous
	l := bits.LeadingZeros64(^mask)
	if l+bits.TrailingZeros64(mask) != 64 {
	return nil
	}

	// update start and end positions (rotation amount remains the same)
	r.Start = uint8(o+z) & 63
	r.End = (r.Start + uint8(l) - 1) & 63
	return &r
	}

	// InMerge tries to generate a new set of parameters representing
	// the intersection between the selected bits and the provided mask
	// as applied to the source value (i.e. pre-rotation).
	// If the intersection is unrepresentable (0 or not contiguous) nil
	// will be returned.
	func (r RotateParams) InMerge(mask uint64) *RotateParams {
	return r.OutMerge(bits.RotateLeft64(mask, int(r.Amount)))
	}

	func (RotateParams) CanBeAnSSAAux() {}