mirror of
https://gitlab.com/pulsechaincom/erigon-pulse.git
synced 2024-12-29 07:07:16 +00:00
792 lines
21 KiB
Go
792 lines
21 KiB
Go
/*
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Copyright 2021 Erigon contributors
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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limitations under the License.
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*/
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package patricia
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import (
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"fmt"
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"math/bits"
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"sort"
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"strings"
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"github.com/ledgerwatch/erigon-lib/sais"
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)
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// Implementation of paticia tree for efficient search of substrings from a dictionary in a given string
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type node struct {
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p0 uint32
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p1 uint32
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//size uint64
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n0 *node
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n1 *node
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val interface{} // value associated with the key
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}
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func tostr(x uint32) string {
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str := fmt.Sprintf("%b", x)
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for len(str) < 32 {
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str = "0" + str
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}
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return str[:x&0x1f]
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}
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// print assumes values are byte slices
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func (n *node) print(sb *strings.Builder, indent string) {
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sb.WriteString(indent)
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fmt.Fprintf(sb, "%p ", n)
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sb.WriteString(tostr(n.p0))
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sb.WriteString("\n")
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if n.n0 != nil {
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n.n0.print(sb, indent+" ")
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}
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sb.WriteString(indent)
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fmt.Fprintf(sb, "%p ", n)
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sb.WriteString(tostr(n.p1))
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sb.WriteString("\n")
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if n.n1 != nil {
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n.n1.print(sb, indent+" ")
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}
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if n.val != nil {
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sb.WriteString(indent)
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sb.WriteString("val:")
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fmt.Fprintf(sb, " %x", n.val.([]byte))
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sb.WriteString("\n")
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}
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}
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func (n *node) String() string {
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var sb strings.Builder
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n.print(&sb, "")
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return sb.String()
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}
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// state represent a position anywhere inside patricia tree
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// position can be identified by combination of node, and the partitioning
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// of that node's p0 or p1 into head and tail.
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// As with p0 and p1, head and tail are encoded as follows:
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// lowest 5 bits encode the length in bits, and the remaining 27 bits
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// encode the actual head or tail.
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// For example, if the position is at the beginning of a node,
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// head would be zero, and tail would be equal to either p0 or p1,
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// depending on whether the position corresponds to going left (0) or right (1).
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type state struct {
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n *node
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head uint32
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tail uint32
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}
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func (s *state) String() string {
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return fmt.Sprintf("%p head %s tail %s", s.n, tostr(s.head), tostr(s.tail))
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}
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func (s *state) reset(n *node) {
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s.n = n
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s.head = 0
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s.tail = 0
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}
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func makestate(n *node) *state {
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return &state{n: n, head: 0, tail: 0}
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}
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// transition consumes next byte of the key, moves the state to corresponding
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// node of the patricia tree and returns divergence prefix (0 if there is no divergence)
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func (s *state) transition(b byte, readonly bool) uint32 {
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bitsLeft := 8 // Bits in b to process
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b32 := uint32(b) << 24
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for bitsLeft > 0 {
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if s.head == 0 {
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// tail has not been determined yet, do it now
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if b32&0x80000000 == 0 {
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s.tail = s.n.p0
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} else {
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s.tail = s.n.p1
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}
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}
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if s.tail == 0 {
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// state positioned at the end of the current node
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return b32 | uint32(bitsLeft)
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}
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tailLen := int(s.tail & 0x1f)
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firstDiff := bits.LeadingZeros32(s.tail ^ b32) // First bit where b32 and tail are different
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if firstDiff < bitsLeft {
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// divergence (where the key being searched and the existing structure of patricia tree becomes incompatible) is within currently supplied byte of the search key, b
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if firstDiff >= tailLen {
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// divergence is within currently supplied byte of the search key, b, but outside of the current node
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bitsLeft -= tailLen
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b32 <<= tailLen
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// Need to switch to the next node
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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if s.n.n0 == nil {
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panic("")
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}
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s.n = s.n.n0
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} else {
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if s.n.n1 == nil {
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panic("")
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}
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s.n = s.n.n1
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}
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s.head = 0
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s.tail = 0
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} else {
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// divergence is within currently supplied byte of the search key, b, and within the current node
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bitsLeft -= firstDiff
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b32 <<= firstDiff
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// there is divergence, move head and tail
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mask := ^(uint32(1)<<(32-firstDiff) - 1)
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s.head |= (s.tail & mask) >> (s.head & 0x1f)
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s.head += uint32(firstDiff)
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s.tail = (s.tail&0xffffffe0)<<firstDiff | (s.tail & 0x1f)
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s.tail -= uint32(firstDiff)
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return b32 | uint32(bitsLeft)
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}
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} else if tailLen < bitsLeft {
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// divergence is outside of currently supplied byte of the search key, b
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bitsLeft -= tailLen
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b32 <<= tailLen
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// Switch to the next node
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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if s.n.n0 == nil {
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if readonly {
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return b32 | uint32(bitsLeft)
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}
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s.n.n0 = &node{}
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if b32&0x80000000 == 0 {
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s.n.n0.p0 = b32 | uint32(bitsLeft)
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} else {
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s.n.n0.p1 = b32 | uint32(bitsLeft)
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}
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}
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s.n = s.n.n0
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} else {
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if s.n.n1 == nil {
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if readonly {
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return b32 | uint32(bitsLeft)
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}
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s.n.n1 = &node{}
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if b32&0x80000000 == 0 {
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s.n.n1.p0 = b32 | uint32(bitsLeft)
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} else {
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s.n.n1.p1 = b32 | uint32(bitsLeft)
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}
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}
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s.n = s.n.n1
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}
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s.head = 0
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s.tail = 0
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} else {
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// key byte is consumed, but stay on the same node
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mask := ^(uint32(1)<<(32-bitsLeft) - 1)
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s.head |= (s.tail & mask) >> (s.head & 0x1f)
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s.head += uint32(bitsLeft)
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s.tail = (s.tail&0xffffffe0)<<bitsLeft | (s.tail & 0x1f)
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s.tail -= uint32(bitsLeft)
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bitsLeft = 0
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if s.tail == 0 {
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if s.head&0x80000000 == 0 {
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if s.n.n0 != nil {
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s.n = s.n.n0
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s.head = 0
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}
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} else {
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if s.n.n1 != nil {
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s.n = s.n.n1
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s.head = 0
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}
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}
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}
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}
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}
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return 0
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}
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func (s *state) diverge(divergence uint32) {
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if s.tail == 0 {
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// try to add to the existing head
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//fmt.Printf("adding divergence to existing head\n")
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dLen := int(divergence & 0x1f)
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headLen := int(s.head & 0x1f)
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d32 := divergence & 0xffffffe0
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//fmt.Printf("headLen %d + dLen %d = %d\n", headLen, dLen, headLen+dLen)
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if headLen+dLen > 27 {
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mask := ^(uint32(1)<<(headLen+5) - 1)
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//fmt.Printf("mask = %b\n", mask)
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s.head |= (d32 & mask) >> headLen
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s.head += uint32(27 - headLen)
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//fmt.Printf("s.head %s\n", tostr(s.head))
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var dn node
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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s.n.p0 = s.head
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s.n.n0 = &dn
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} else {
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s.n.p1 = s.head
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s.n.n1 = &dn
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}
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s.n = &dn
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s.head = 0
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s.tail = 0
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d32 <<= 27 - headLen
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dLen -= (27 - headLen)
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headLen = 0
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}
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//fmt.Printf("headLen %d + dLen %d = %d\n", headLen, dLen, headLen+dLen)
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mask := ^(uint32(1)<<(32-dLen) - 1)
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//fmt.Printf("mask = %b\n", mask)
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s.head |= (d32 & mask) >> headLen
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s.head += uint32(dLen)
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//fmt.Printf("s.head %s\n", tostr(s.head))
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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s.n.p0 = s.head
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} else {
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s.n.p1 = s.head
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}
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return
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}
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// create a new node
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var dn node
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if divergence&0x80000000 == 0 {
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dn.p0 = divergence
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dn.p1 = s.tail
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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dn.n1 = s.n.n0
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} else {
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dn.n1 = s.n.n1
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}
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} else {
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dn.p1 = divergence
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dn.p0 = s.tail
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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dn.n0 = s.n.n0
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} else {
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dn.n0 = s.n.n1
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}
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}
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if (s.head == 0 && s.tail&0x80000000 == 0) || (s.head != 0 && s.head&0x80000000 == 0) {
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s.n.n0 = &dn
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s.n.p0 = s.head
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} else {
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s.n.n1 = &dn
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s.n.p1 = s.head
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}
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s.n = &dn
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s.head = divergence
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s.tail = 0
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}
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func (n *node) insert(key []byte, value interface{}) {
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s := makestate(n)
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for _, b := range key {
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divergence := s.transition(b, false /* readonly */)
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if divergence != 0 {
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s.diverge(divergence)
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}
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}
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s.insert(value)
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}
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func (s *state) insert(value interface{}) {
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if s.tail != 0 {
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s.diverge(0)
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}
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if s.head != 0 {
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var dn node
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if s.head&0x80000000 == 0 {
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s.n.n0 = &dn
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} else {
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s.n.n1 = &dn
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}
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s.n = &dn
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s.head = 0
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}
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//fmt.Printf("set val to %p\n", s.n)
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s.n.val = value
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}
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func (n *node) get(key []byte) (interface{}, bool) {
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s := makestate(n)
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for _, b := range key {
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divergence := s.transition(b, true /* readonly */)
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//fmt.Printf("get %x, b = %x, divergence = %s\nstate=%s\n", key, b, tostr(divergence), s)
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if divergence != 0 {
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return nil, false
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}
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}
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if s.tail != 0 {
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return nil, false
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}
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return s.n.val, s.n.val != nil
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}
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type PatriciaTree struct {
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root node
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}
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func (pt *PatriciaTree) Insert(key []byte, value interface{}) {
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//fmt.Printf("%p Insert [%x]\n", pt, key)
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pt.root.insert(key, value)
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}
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func (pt PatriciaTree) Get(key []byte) (interface{}, bool) {
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return pt.root.get(key)
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}
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type Match struct {
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Start int
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End int
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Val interface{}
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}
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type Matches []Match
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func (m Matches) Len() int {
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return len(m)
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}
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func (m Matches) Less(i, j int) bool {
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return m[i].Start < m[j].Start
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}
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func (m *Matches) Swap(i, j int) {
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(*m)[i], (*m)[j] = (*m)[j], (*m)[i]
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}
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type MatchFinder struct {
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s state
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matches []Match
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pt *PatriciaTree
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}
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func NewMatchFinder(pt *PatriciaTree) *MatchFinder {
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return &MatchFinder{pt: pt}
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}
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type MatchFinder2 struct {
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nodeStack []*node
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matchStack []Match
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top *node // Top of nodeStack
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headLen int
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tailLen int
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side int // 0, 1, or 2 (if side is not determined yet)
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matches Matches
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pt *PatriciaTree
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sa, lcp, inv []int32
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}
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func NewMatchFinder2(pt *PatriciaTree) *MatchFinder2 {
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return &MatchFinder2{pt: pt, top: &pt.root, nodeStack: []*node{&pt.root}, side: 2}
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}
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// unfold consumes next byte of the key, moves the state to corresponding
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// node of the patricia tree and returns divergence prefix (0 if there is no divergence)
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func (mf2 *MatchFinder2) unfold(b byte) uint32 {
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//fmt.Printf("unfold %x, headLen = %d, tailLen = %d, nodeStackLen = %d\n", b, mf2.headLen, mf2.tailLen, len(mf2.nodeStack))
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//var sb strings.Builder
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bitsLeft := 8 // Bits in b to process
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b32 := uint32(b) << 24
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for bitsLeft > 0 {
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if mf2.side == 2 {
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// tail has not been determined yet, do it now
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if b32&0x80000000 == 0 {
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mf2.side = 0
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mf2.headLen = 0
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mf2.tailLen = int(mf2.top.p0 & 0x1f)
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} else {
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mf2.side = 1
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mf2.headLen = 0
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mf2.tailLen = int(mf2.top.p1 & 0x1f)
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}
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if mf2.tailLen == 0 {
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// state positioned at the end of the current node
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mf2.side = 2
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//fmt.Fprintf(&sb, "1 ")
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//fmt.Printf("%s\n", sb.String())
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return b32 | uint32(bitsLeft)
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}
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}
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if mf2.tailLen == 0 {
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// Need to switch to the next node
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if mf2.side == 0 {
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if mf2.top.n0 == nil {
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//fmt.Fprintf(&sb, "2 ")
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//fmt.Printf("%s\n", sb.String())
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return b32 | uint32(bitsLeft)
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}
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mf2.nodeStack = append(mf2.nodeStack, mf2.top.n0)
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mf2.top = mf2.top.n0
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//fmt.Fprintf(&sb, "a1,0,bl=%d ", bitsLeft)
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} else if mf2.side == 1 {
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if mf2.top.n1 == nil {
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//fmt.Fprintf(&sb, "3 ")
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//fmt.Printf("%s\n", sb.String())
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return b32 | uint32(bitsLeft)
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}
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mf2.nodeStack = append(mf2.nodeStack, mf2.top.n1)
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mf2.top = mf2.top.n1
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//fmt.Fprintf(&sb, "a1,1,bl=%d ", bitsLeft)
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} else {
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panic("")
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}
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mf2.headLen = 0
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mf2.side = 2
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}
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var tail uint32
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if mf2.side == 0 {
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tail = (mf2.top.p0 & 0xffffffe0) << mf2.headLen
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} else if mf2.side == 1 {
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tail = (mf2.top.p1 & 0xffffffe0) << mf2.headLen
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} else {
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return b32 | uint32(bitsLeft)
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}
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firstDiff := bits.LeadingZeros32(tail ^ b32) // First bit where b32 and tail are different
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if firstDiff < bitsLeft {
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// divergence (where the key being searched and the existing structure of patricia tree becomes incompatible) is within currently supplied byte of the search key, b
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if firstDiff >= mf2.tailLen {
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// divergence is within currently supplied byte of the search key, b, but outside of the current node
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//fmt.Fprintf(&sb, "4,tl=%d ", mf2.tailLen)
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bitsLeft -= mf2.tailLen
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b32 <<= mf2.tailLen
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mf2.headLen += mf2.tailLen
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mf2.tailLen = 0
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} else {
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// divergence is within currently supplied byte of the search key, b, and within the current node
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bitsLeft -= firstDiff
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b32 <<= firstDiff
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// there is divergence, move head and tail
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mf2.tailLen -= firstDiff
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mf2.headLen += firstDiff
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//fmt.Fprintf(&sb, "5 ")
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//fmt.Printf("%s\n", sb.String())
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return b32 | uint32(bitsLeft)
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}
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} else if mf2.tailLen < bitsLeft {
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// divergence is outside of currently supplied byte of the search key, b
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bitsLeft -= mf2.tailLen
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b32 <<= mf2.tailLen
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mf2.headLen += mf2.tailLen
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mf2.tailLen = 0
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//fmt.Fprintf(&sb, "6 ")
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} else {
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// key byte is consumed, but stay on the same node
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//fmt.Fprintf(&sb, "7,bl=%d ", bitsLeft)
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mf2.tailLen -= bitsLeft
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mf2.headLen += bitsLeft
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bitsLeft = 0
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b32 = 0
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}
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if mf2.tailLen == 0 {
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// Need to switch to the next node
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if mf2.side == 0 {
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if mf2.top.n0 == nil {
|
||
//fmt.Fprintf(&sb, "8 ")
|
||
//fmt.Printf("%s\n", sb.String())
|
||
return b32 | uint32(bitsLeft)
|
||
}
|
||
mf2.nodeStack = append(mf2.nodeStack, mf2.top.n0)
|
||
mf2.top = mf2.top.n0
|
||
//fmt.Fprintf(&sb, "a2,0,bl=%d ", bitsLeft)
|
||
} else if mf2.side == 1 {
|
||
if mf2.top.n1 == nil {
|
||
//fmt.Fprintf(&sb, "9 ")
|
||
//fmt.Printf("%s\n", sb.String())
|
||
return b32 | uint32(bitsLeft)
|
||
}
|
||
mf2.nodeStack = append(mf2.nodeStack, mf2.top.n1)
|
||
mf2.top = mf2.top.n1
|
||
//fmt.Fprintf(&sb, "a2,1,bl=%d ", bitsLeft)
|
||
} else {
|
||
panic("")
|
||
}
|
||
mf2.headLen = 0
|
||
mf2.side = 2
|
||
}
|
||
}
|
||
//fmt.Printf("%s\n", sb.String())
|
||
return 0
|
||
}
|
||
|
||
// unfold moves the match finder back up the stack by specified number of bits
|
||
func (mf2 *MatchFinder2) fold(bits int) {
|
||
//fmt.Printf("fold %d, headLen = %d, tailLen = %d, nodeStackLen = %d\n", bits, mf2.headLen, mf2.tailLen, len(mf2.nodeStack))
|
||
bitsLeft := bits
|
||
for bitsLeft > 0 {
|
||
//fmt.Printf("headLen = %d, bitsLeft = %d, head = %b, tail = %b, nodeStackLen = %d\n", headLen, bitsLeft, mf2.head, mf2.tail, len(mf2.nodeStack))
|
||
if mf2.headLen == bitsLeft {
|
||
mf2.headLen = 0
|
||
mf2.tailLen = 0
|
||
mf2.side = 2
|
||
bitsLeft = 0
|
||
} else if mf2.headLen >= bitsLeft {
|
||
// folding only affects top node, take bits from end of the head and prepend it to the tail
|
||
mf2.headLen -= bitsLeft
|
||
mf2.tailLen += bitsLeft
|
||
bitsLeft = 0
|
||
} else {
|
||
// folding affects not only top node, remove top node
|
||
bitsLeft -= mf2.headLen
|
||
mf2.nodeStack = mf2.nodeStack[:len(mf2.nodeStack)-1]
|
||
prevTop := mf2.top
|
||
mf2.top = mf2.nodeStack[len(mf2.nodeStack)-1]
|
||
if mf2.top.n0 == prevTop {
|
||
mf2.side = 0
|
||
mf2.headLen = int(mf2.top.p0 & 0x1f)
|
||
//fmt.Printf("mf2.head = p0 %b\n", mf2.head)
|
||
} else if mf2.top.n1 == prevTop {
|
||
mf2.side = 1
|
||
mf2.headLen = int(mf2.top.p1 & 0x1f)
|
||
//fmt.Printf("mf2.head = p1 %b\n", mf2.head)
|
||
} else {
|
||
panic("")
|
||
}
|
||
mf2.tailLen = 0
|
||
}
|
||
}
|
||
}
|
||
|
||
func (mf2 *MatchFinder2) FindLongestMatches(data []byte) []Match {
|
||
//fmt.Printf("mf2=%p pt=%p data=[%x]\n", mf2, mf2.pt, data)
|
||
mf2.matches = mf2.matches[:0]
|
||
if len(data) < 2 {
|
||
return mf2.matches
|
||
}
|
||
mf2.nodeStack = append(mf2.nodeStack[:0], &mf2.pt.root)
|
||
mf2.matchStack = mf2.matchStack[:0]
|
||
mf2.top = &mf2.pt.root
|
||
mf2.side = 2
|
||
mf2.tailLen = 0
|
||
mf2.headLen = 0
|
||
n := len(data)
|
||
if cap(mf2.sa) < n {
|
||
mf2.sa = make([]int32, n)
|
||
} else {
|
||
mf2.sa = mf2.sa[:n]
|
||
}
|
||
if err := sais.Sais(data, mf2.sa); err != nil {
|
||
panic(err)
|
||
}
|
||
if cap(mf2.inv) < n {
|
||
mf2.inv = make([]int32, n)
|
||
} else {
|
||
mf2.inv = mf2.inv[:n]
|
||
}
|
||
for i := 0; i < n; i++ {
|
||
mf2.inv[mf2.sa[i]] = int32(i)
|
||
}
|
||
var k int
|
||
// Process all suffixes one by one starting from
|
||
// first suffix in txt[]
|
||
if cap(mf2.lcp) < n {
|
||
mf2.lcp = make([]int32, n)
|
||
} else {
|
||
mf2.lcp = mf2.lcp[:n]
|
||
}
|
||
for i := 0; i < n; i++ {
|
||
/* If the current suffix is at n-1, then we don’t
|
||
have next substring to consider. So lcp is not
|
||
defined for this substring, we put zero. */
|
||
if mf2.inv[i] == int32(n-1) {
|
||
k = 0
|
||
continue
|
||
}
|
||
|
||
/* j contains index of the next substring to
|
||
be considered to compare with the present
|
||
substring, i.e., next string in suffix array */
|
||
j := int(mf2.sa[mf2.inv[i]+1])
|
||
|
||
// Directly start matching from k'th index as
|
||
// at-least k-1 characters will match
|
||
for i+k < n && j+k < n && data[i+k] == data[j+k] {
|
||
k++
|
||
}
|
||
mf2.lcp[mf2.inv[i]] = int32(k) // lcp for the present suffix.
|
||
|
||
// Deleting the starting character from the string.
|
||
if k > 0 {
|
||
k--
|
||
}
|
||
}
|
||
//fmt.Printf("sa=[%d]\n", mf2.sa)
|
||
//fmt.Printf("lcp=[%d]\n", mf2.lcp)
|
||
depth := 0 // Depth in bits
|
||
var lastMatch *Match
|
||
for i := 0; i < n; i++ {
|
||
// lcp[i] is the Longest Common Prefix of suffixes starting from sa[i] and sa[i+1]
|
||
//fmt.Printf("Suffix [%x], depth = %d\n", data[mf2.sa[i]:n], depth)
|
||
if i > 0 {
|
||
lcp := int(mf2.lcp[i-1])
|
||
// lcp[i-1] is the Longest Common Prefix of suffixes starting from sa[i-1] and sa[i]
|
||
if depth > 8*lcp {
|
||
//fmt.Printf("before fold depth = %d, mf2.lcp[i-1] = %d\n", depth, mf2.lcp[i-1])
|
||
mf2.fold(depth - 8*lcp)
|
||
depth = 8 * lcp
|
||
//b1, d1 := mf2.Current()
|
||
//fmt.Printf("current: [%x] %d, depth = %d\n", b1, d1, depth)
|
||
//fmt.Printf("after fold depth = %d\n", depth)
|
||
for lastMatch != nil && lastMatch.End-lastMatch.Start > lcp {
|
||
//fmt.Printf("Popped %d: [%d-%d] [%x]\n", len(mf2.matchStack)-1, lastMatch.Start, lastMatch.End, data[lastMatch.Start:lastMatch.End])
|
||
mf2.matchStack = mf2.matchStack[:len(mf2.matchStack)-1]
|
||
if len(mf2.matchStack) == 0 {
|
||
lastMatch = nil
|
||
} else {
|
||
lastMatch = &mf2.matchStack[len(mf2.matchStack)-1]
|
||
}
|
||
}
|
||
} else {
|
||
r := depth % 8
|
||
if r > 0 {
|
||
mf2.fold(r)
|
||
depth -= r
|
||
//b1, d1 := mf2.Current()
|
||
//fmt.Printf("current: [%x] %d, depth = %d\n", b1, d1, depth)
|
||
}
|
||
}
|
||
}
|
||
sa := int(mf2.sa[i])
|
||
start := sa + depth/8
|
||
for end := start + 1; end <= n; end++ {
|
||
//fmt.Printf("Looking at [%d-%d] [%x]\n", sa, end, data[sa:end])
|
||
d := mf2.unfold(data[end-1])
|
||
depth += 8 - int(d&0x1f)
|
||
//fmt.Printf("after unfold depth=%d\n", depth)
|
||
//b1, d1 := mf2.Current()
|
||
//fmt.Printf("current: [%x][%x] %d, depth = %d\n", b1, data[sa:end], d1, depth)
|
||
if d != 0 {
|
||
//fmt.Printf("divergence found: %b\n", d)
|
||
break
|
||
}
|
||
if mf2.tailLen != 0 || mf2.top.val == nil {
|
||
//fmt.Printf("tailLen = %d, val == nil %t, p=%p\n", mf2.tailLen, mf2.top.val == nil, mf2.top)
|
||
continue
|
||
}
|
||
if cap(mf2.matchStack) == len(mf2.matchStack) {
|
||
mf2.matchStack = append(mf2.matchStack, Match{})
|
||
} else {
|
||
mf2.matchStack = mf2.matchStack[:len(mf2.matchStack)+1]
|
||
}
|
||
lastMatch = &mf2.matchStack[len(mf2.matchStack)-1]
|
||
// This possibly overwrites previous match for the same start position
|
||
//fmt.Printf("Push on the match stack [%d-%d] [%x]\n", sa, end, data[sa:end])
|
||
lastMatch.Start = sa
|
||
lastMatch.End = end
|
||
lastMatch.Val = mf2.top.val
|
||
}
|
||
if lastMatch != nil {
|
||
mf2.matches = append(mf2.matches, Match{})
|
||
m := &mf2.matches[len(mf2.matches)-1]
|
||
m.Start = sa
|
||
m.End = sa + lastMatch.End - lastMatch.Start
|
||
m.Val = lastMatch.Val
|
||
//fmt.Printf("Added new Match: [%d-%d] [%x]\n", m.Start, m.End, data[m.Start:m.End])
|
||
}
|
||
}
|
||
//fmt.Printf("before sorting %d matches\n", len(mf2.matches))
|
||
if len(mf2.matches) < 2 {
|
||
return mf2.matches
|
||
}
|
||
sort.Sort(&mf2.matches)
|
||
lastEnd := mf2.matches[0].End
|
||
j := 1
|
||
for i, m := range mf2.matches {
|
||
if i > 0 {
|
||
if m.End > lastEnd {
|
||
if i != j {
|
||
mf2.matches[j] = m
|
||
}
|
||
lastEnd = m.End
|
||
j++
|
||
}
|
||
}
|
||
}
|
||
return mf2.matches[:j]
|
||
}
|
||
|
||
func (mf2 *MatchFinder2) Current() ([]byte, int) {
|
||
var b []byte
|
||
var depth int
|
||
last := len(mf2.nodeStack) - 1
|
||
for i, n := range mf2.nodeStack {
|
||
var p uint32
|
||
if i < last {
|
||
next := mf2.nodeStack[i+1]
|
||
if n.n0 == next {
|
||
p = n.p0
|
||
} else if n.n1 == next {
|
||
p = n.p1
|
||
} else {
|
||
panic("")
|
||
}
|
||
} else {
|
||
if mf2.side == 0 {
|
||
p = n.p0
|
||
} else if mf2.side == 1 {
|
||
p = n.p1
|
||
}
|
||
p = (p & 0xffffffe0) | uint32(mf2.headLen)
|
||
}
|
||
fmt.Printf("i,p=%d, %b\n", i, p)
|
||
// Add bit by bit
|
||
for (p & 0x1f) > 0 {
|
||
if depth >= 8*len(b) {
|
||
b = append(b, 0)
|
||
}
|
||
if p&0x80000000 != 0 {
|
||
b[depth/8] |= uint8(1) << (7 - (depth % 8))
|
||
}
|
||
depth++
|
||
p = ((p & 0xffffffe0) << 1) | (p & 0x1f) - 1
|
||
}
|
||
}
|
||
return b, depth
|
||
}
|
||
|
||
func (mf *MatchFinder) FindLongestMatches(data []byte) []Match {
|
||
matchCount := 0
|
||
s := &mf.s
|
||
lastEnd := 0
|
||
for start := 0; start < len(data); start++ {
|
||
s.reset(&mf.pt.root)
|
||
emitted := false
|
||
for end := start + 1; end <= len(data); end++ {
|
||
if d := s.transition(data[end-1], true /* readonly */); d != 0 {
|
||
break
|
||
}
|
||
if s.tail != 0 || s.n.val == nil || end <= lastEnd {
|
||
continue
|
||
}
|
||
var m *Match
|
||
if emitted {
|
||
m = &mf.matches[matchCount-1]
|
||
} else {
|
||
if matchCount == len(mf.matches) {
|
||
mf.matches = append(mf.matches, Match{})
|
||
m = &mf.matches[len(mf.matches)-1]
|
||
} else {
|
||
m = &mf.matches[matchCount]
|
||
}
|
||
matchCount++
|
||
emitted = true
|
||
}
|
||
// This possibly overwrites previous match for the same start position
|
||
m.Start = start
|
||
m.End = end
|
||
m.Val = s.n.val
|
||
lastEnd = end
|
||
}
|
||
}
|
||
return mf.matches[:matchCount]
|
||
}
|