mirror of
https://github.com/superseriousbusiness/gotosocial.git
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ed46224573
* Add SQLite support, fix un-thread-safe DB caches, small performance fixes Signed-off-by: kim (grufwub) <grufwub@gmail.com> * add SQLite licenses to README Signed-off-by: kim (grufwub) <grufwub@gmail.com> * appease the linter, and fix my dumbass-ery Signed-off-by: kim (grufwub) <grufwub@gmail.com> * make requested changes Signed-off-by: kim (grufwub) <grufwub@gmail.com> * add back comment Signed-off-by: kim (grufwub) <grufwub@gmail.com>
418 lines
9.4 KiB
Go
418 lines
9.4 KiB
Go
package uint128 // import "lukechampine.com/uint128"
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import (
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"encoding/binary"
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"math"
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"math/big"
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"math/bits"
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)
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// Zero is a zero-valued uint128.
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var Zero Uint128
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// Max is the largest possible uint128 value.
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var Max = New(math.MaxUint64, math.MaxUint64)
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// A Uint128 is an unsigned 128-bit number.
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type Uint128 struct {
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Lo, Hi uint64
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}
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// IsZero returns true if u == 0.
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func (u Uint128) IsZero() bool {
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// NOTE: we do not compare against Zero, because that is a global variable
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// that could be modified.
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return u == Uint128{}
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}
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// Equals returns true if u == v.
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//
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// Uint128 values can be compared directly with ==, but use of the Equals method
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// is preferred for consistency.
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func (u Uint128) Equals(v Uint128) bool {
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return u == v
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}
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// Equals64 returns true if u == v.
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func (u Uint128) Equals64(v uint64) bool {
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return u.Lo == v && u.Hi == 0
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}
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// Cmp compares u and v and returns:
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//
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// -1 if u < v
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// 0 if u == v
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// +1 if u > v
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//
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func (u Uint128) Cmp(v Uint128) int {
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if u == v {
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return 0
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} else if u.Hi < v.Hi || (u.Hi == v.Hi && u.Lo < v.Lo) {
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return -1
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} else {
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return 1
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}
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}
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// Cmp64 compares u and v and returns:
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//
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// -1 if u < v
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// 0 if u == v
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// +1 if u > v
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//
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func (u Uint128) Cmp64(v uint64) int {
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if u.Hi == 0 && u.Lo == v {
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return 0
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} else if u.Hi == 0 && u.Lo < v {
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return -1
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} else {
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return 1
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}
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}
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// And returns u&v.
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func (u Uint128) And(v Uint128) Uint128 {
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return Uint128{u.Lo & v.Lo, u.Hi & v.Hi}
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}
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// And64 returns u&v.
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func (u Uint128) And64(v uint64) Uint128 {
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return Uint128{u.Lo & v, u.Hi & 0}
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}
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// Or returns u|v.
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func (u Uint128) Or(v Uint128) Uint128 {
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return Uint128{u.Lo | v.Lo, u.Hi | v.Hi}
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}
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// Or64 returns u|v.
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func (u Uint128) Or64(v uint64) Uint128 {
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return Uint128{u.Lo | v, u.Hi | 0}
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}
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// Xor returns u^v.
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func (u Uint128) Xor(v Uint128) Uint128 {
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return Uint128{u.Lo ^ v.Lo, u.Hi ^ v.Hi}
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}
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// Xor64 returns u^v.
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func (u Uint128) Xor64(v uint64) Uint128 {
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return Uint128{u.Lo ^ v, u.Hi ^ 0}
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}
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// Add returns u+v.
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func (u Uint128) Add(v Uint128) Uint128 {
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lo, carry := bits.Add64(u.Lo, v.Lo, 0)
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hi, carry := bits.Add64(u.Hi, v.Hi, carry)
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if carry != 0 {
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panic("overflow")
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}
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return Uint128{lo, hi}
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}
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// AddWrap returns u+v with wraparound semantics; for example,
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// Max.AddWrap(From64(1)) == Zero.
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func (u Uint128) AddWrap(v Uint128) Uint128 {
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lo, carry := bits.Add64(u.Lo, v.Lo, 0)
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hi, _ := bits.Add64(u.Hi, v.Hi, carry)
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return Uint128{lo, hi}
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}
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// Add64 returns u+v.
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func (u Uint128) Add64(v uint64) Uint128 {
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lo, carry := bits.Add64(u.Lo, v, 0)
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hi, carry := bits.Add64(u.Hi, 0, carry)
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if carry != 0 {
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panic("overflow")
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}
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return Uint128{lo, hi}
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}
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// AddWrap64 returns u+v with wraparound semantics; for example,
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// Max.AddWrap64(1) == Zero.
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func (u Uint128) AddWrap64(v uint64) Uint128 {
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lo, carry := bits.Add64(u.Lo, v, 0)
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hi := u.Hi + carry
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return Uint128{lo, hi}
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}
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// Sub returns u-v.
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func (u Uint128) Sub(v Uint128) Uint128 {
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lo, borrow := bits.Sub64(u.Lo, v.Lo, 0)
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hi, borrow := bits.Sub64(u.Hi, v.Hi, borrow)
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if borrow != 0 {
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panic("underflow")
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}
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return Uint128{lo, hi}
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}
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// SubWrap returns u-v with wraparound semantics; for example,
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// Zero.SubWrap(From64(1)) == Max.
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func (u Uint128) SubWrap(v Uint128) Uint128 {
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lo, borrow := bits.Sub64(u.Lo, v.Lo, 0)
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hi, _ := bits.Sub64(u.Hi, v.Hi, borrow)
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return Uint128{lo, hi}
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}
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// Sub64 returns u-v.
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func (u Uint128) Sub64(v uint64) Uint128 {
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lo, borrow := bits.Sub64(u.Lo, v, 0)
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hi, borrow := bits.Sub64(u.Hi, 0, borrow)
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if borrow != 0 {
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panic("underflow")
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}
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return Uint128{lo, hi}
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}
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// SubWrap64 returns u-v with wraparound semantics; for example,
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// Zero.SubWrap64(1) == Max.
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func (u Uint128) SubWrap64(v uint64) Uint128 {
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lo, borrow := bits.Sub64(u.Lo, v, 0)
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hi := u.Hi - borrow
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return Uint128{lo, hi}
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}
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// Mul returns u*v, panicking on overflow.
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func (u Uint128) Mul(v Uint128) Uint128 {
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hi, lo := bits.Mul64(u.Lo, v.Lo)
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p0, p1 := bits.Mul64(u.Hi, v.Lo)
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p2, p3 := bits.Mul64(u.Lo, v.Hi)
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hi, c0 := bits.Add64(hi, p1, 0)
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hi, c1 := bits.Add64(hi, p3, c0)
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if (u.Hi != 0 && v.Hi != 0) || p0 != 0 || p2 != 0 || c1 != 0 {
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panic("overflow")
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}
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return Uint128{lo, hi}
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}
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// MulWrap returns u*v with wraparound semantics; for example,
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// Max.MulWrap(Max) == 1.
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func (u Uint128) MulWrap(v Uint128) Uint128 {
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hi, lo := bits.Mul64(u.Lo, v.Lo)
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hi += u.Hi*v.Lo + u.Lo*v.Hi
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return Uint128{lo, hi}
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}
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// Mul64 returns u*v, panicking on overflow.
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func (u Uint128) Mul64(v uint64) Uint128 {
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hi, lo := bits.Mul64(u.Lo, v)
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p0, p1 := bits.Mul64(u.Hi, v)
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hi, c0 := bits.Add64(hi, p1, 0)
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if p0 != 0 || c0 != 0 {
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panic("overflow")
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}
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return Uint128{lo, hi}
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}
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// MulWrap64 returns u*v with wraparound semantics; for example,
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// Max.MulWrap64(2) == Max.Sub64(1).
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func (u Uint128) MulWrap64(v uint64) Uint128 {
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hi, lo := bits.Mul64(u.Lo, v)
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hi += u.Hi * v
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return Uint128{lo, hi}
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}
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// Div returns u/v.
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func (u Uint128) Div(v Uint128) Uint128 {
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q, _ := u.QuoRem(v)
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return q
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}
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// Div64 returns u/v.
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func (u Uint128) Div64(v uint64) Uint128 {
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q, _ := u.QuoRem64(v)
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return q
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}
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// QuoRem returns q = u/v and r = u%v.
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func (u Uint128) QuoRem(v Uint128) (q, r Uint128) {
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if v.Hi == 0 {
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var r64 uint64
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q, r64 = u.QuoRem64(v.Lo)
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r = From64(r64)
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} else {
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// generate a "trial quotient," guaranteed to be within 1 of the actual
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// quotient, then adjust.
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n := uint(bits.LeadingZeros64(v.Hi))
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v1 := v.Lsh(n)
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u1 := u.Rsh(1)
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tq, _ := bits.Div64(u1.Hi, u1.Lo, v1.Hi)
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tq >>= 63 - n
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if tq != 0 {
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tq--
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}
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q = From64(tq)
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// calculate remainder using trial quotient, then adjust if remainder is
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// greater than divisor
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r = u.Sub(v.Mul64(tq))
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if r.Cmp(v) >= 0 {
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q = q.Add64(1)
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r = r.Sub(v)
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}
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}
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return
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}
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// QuoRem64 returns q = u/v and r = u%v.
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func (u Uint128) QuoRem64(v uint64) (q Uint128, r uint64) {
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if u.Hi < v {
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q.Lo, r = bits.Div64(u.Hi, u.Lo, v)
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} else {
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q.Hi, r = bits.Div64(0, u.Hi, v)
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q.Lo, r = bits.Div64(r, u.Lo, v)
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}
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return
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}
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// Mod returns r = u%v.
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func (u Uint128) Mod(v Uint128) (r Uint128) {
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_, r = u.QuoRem(v)
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return
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}
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// Mod64 returns r = u%v.
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func (u Uint128) Mod64(v uint64) (r uint64) {
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_, r = u.QuoRem64(v)
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return
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}
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// Lsh returns u<<n.
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func (u Uint128) Lsh(n uint) (s Uint128) {
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if n > 64 {
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s.Lo = 0
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s.Hi = u.Lo << (n - 64)
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} else {
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s.Lo = u.Lo << n
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s.Hi = u.Hi<<n | u.Lo>>(64-n)
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}
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return
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}
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// Rsh returns u>>n.
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func (u Uint128) Rsh(n uint) (s Uint128) {
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if n > 64 {
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s.Lo = u.Hi >> (n - 64)
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s.Hi = 0
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} else {
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s.Lo = u.Lo>>n | u.Hi<<(64-n)
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s.Hi = u.Hi >> n
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}
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return
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}
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// LeadingZeros returns the number of leading zero bits in u; the result is 128
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// for u == 0.
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func (u Uint128) LeadingZeros() int {
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if u.Hi > 0 {
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return bits.LeadingZeros64(u.Hi)
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}
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return 64 + bits.LeadingZeros64(u.Lo)
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}
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// TrailingZeros returns the number of trailing zero bits in u; the result is
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// 128 for u == 0.
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func (u Uint128) TrailingZeros() int {
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if u.Lo > 0 {
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return bits.TrailingZeros64(u.Lo)
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}
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return 64 + bits.TrailingZeros64(u.Hi)
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}
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// OnesCount returns the number of one bits ("population count") in u.
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func (u Uint128) OnesCount() int {
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return bits.OnesCount64(u.Hi) + bits.OnesCount64(u.Lo)
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}
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// RotateLeft returns the value of u rotated left by (k mod 128) bits.
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func (u Uint128) RotateLeft(k int) Uint128 {
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const n = 128
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s := uint(k) & (n - 1)
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return u.Lsh(s).Or(u.Rsh(n - s))
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}
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// RotateRight returns the value of u rotated left by (k mod 128) bits.
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func (u Uint128) RotateRight(k int) Uint128 {
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return u.RotateLeft(-k)
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}
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// Reverse returns the value of u with its bits in reversed order.
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func (u Uint128) Reverse() Uint128 {
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return Uint128{bits.Reverse64(u.Hi), bits.Reverse64(u.Lo)}
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}
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// ReverseBytes returns the value of u with its bytes in reversed order.
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func (u Uint128) ReverseBytes() Uint128 {
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return Uint128{bits.ReverseBytes64(u.Hi), bits.ReverseBytes64(u.Lo)}
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}
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// Len returns the minimum number of bits required to represent u; the result is
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// 0 for u == 0.
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func (u Uint128) Len() int {
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return 128 - u.LeadingZeros()
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}
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// String returns the base-10 representation of u as a string.
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func (u Uint128) String() string {
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if u.IsZero() {
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return "0"
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}
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buf := []byte("0000000000000000000000000000000000000000") // log10(2^128) < 40
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for i := len(buf); ; i -= 19 {
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q, r := u.QuoRem64(1e19) // largest power of 10 that fits in a uint64
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var n int
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for ; r != 0; r /= 10 {
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n++
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buf[i-n] += byte(r % 10)
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}
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if q.IsZero() {
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return string(buf[i-n:])
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}
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u = q
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}
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}
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// PutBytes stores u in b in little-endian order. It panics if len(b) < 16.
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func (u Uint128) PutBytes(b []byte) {
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binary.LittleEndian.PutUint64(b[:8], u.Lo)
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binary.LittleEndian.PutUint64(b[8:], u.Hi)
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}
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// Big returns u as a *big.Int.
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func (u Uint128) Big() *big.Int {
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i := new(big.Int).SetUint64(u.Hi)
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i = i.Lsh(i, 64)
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i = i.Xor(i, new(big.Int).SetUint64(u.Lo))
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return i
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}
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// New returns the Uint128 value (lo,hi).
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func New(lo, hi uint64) Uint128 {
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return Uint128{lo, hi}
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}
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// From64 converts v to a Uint128 value.
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func From64(v uint64) Uint128 {
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return New(v, 0)
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}
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// FromBytes converts b to a Uint128 value.
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func FromBytes(b []byte) Uint128 {
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return New(
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binary.LittleEndian.Uint64(b[:8]),
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binary.LittleEndian.Uint64(b[8:]),
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)
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}
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// FromBig converts i to a Uint128 value. It panics if i is negative or
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// overflows 128 bits.
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func FromBig(i *big.Int) (u Uint128) {
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if i.Sign() < 0 {
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panic("value cannot be negative")
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} else if i.BitLen() > 128 {
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panic("value overflows Uint128")
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}
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u.Lo = i.Uint64()
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u.Hi = new(big.Int).Rsh(i, 64).Uint64()
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return u
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}
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