forgejo-federation/vendor/github.com/andybalholm/brotli/backward_references_hq.go

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package brotli
import "math"
type zopfliNode struct {
length uint32
distance uint32
dcode_insert_length uint32
u struct {
cost float32
next uint32
shortcut uint32
}
}
const maxEffectiveDistanceAlphabetSize = 544
const kInfinity float32 = 1.7e38 /* ~= 2 ^ 127 */
var kDistanceCacheIndex = []uint32{0, 1, 2, 3, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1}
var kDistanceCacheOffset = []int{0, 0, 0, 0, -1, 1, -2, 2, -3, 3, -1, 1, -2, 2, -3, 3}
func initZopfliNodes(array []zopfliNode, length uint) {
var stub zopfliNode
var i uint
stub.length = 1
stub.distance = 0
stub.dcode_insert_length = 0
stub.u.cost = kInfinity
for i = 0; i < length; i++ {
array[i] = stub
}
}
func zopfliNodeCopyLength(self *zopfliNode) uint32 {
return self.length & 0x1FFFFFF
}
func zopfliNodeLengthCode(self *zopfliNode) uint32 {
var modifier uint32 = self.length >> 25
return zopfliNodeCopyLength(self) + 9 - modifier
}
func zopfliNodeCopyDistance(self *zopfliNode) uint32 {
return self.distance
}
func zopfliNodeDistanceCode(self *zopfliNode) uint32 {
var short_code uint32 = self.dcode_insert_length >> 27
if short_code == 0 {
return zopfliNodeCopyDistance(self) + numDistanceShortCodes - 1
} else {
return short_code - 1
}
}
func zopfliNodeCommandLength(self *zopfliNode) uint32 {
return zopfliNodeCopyLength(self) + (self.dcode_insert_length & 0x7FFFFFF)
}
/* Histogram based cost model for zopflification. */
type zopfliCostModel struct {
cost_cmd_ [numCommandSymbols]float32
cost_dist_ []float32
distance_histogram_size uint32
literal_costs_ []float32
min_cost_cmd_ float32
num_bytes_ uint
}
func initZopfliCostModel(self *zopfliCostModel, dist *distanceParams, num_bytes uint) {
var distance_histogram_size uint32 = dist.alphabet_size
if distance_histogram_size > maxEffectiveDistanceAlphabetSize {
distance_histogram_size = maxEffectiveDistanceAlphabetSize
}
self.num_bytes_ = num_bytes
self.literal_costs_ = make([]float32, (num_bytes + 2))
self.cost_dist_ = make([]float32, (dist.alphabet_size))
self.distance_histogram_size = distance_histogram_size
}
func cleanupZopfliCostModel(self *zopfliCostModel) {
self.literal_costs_ = nil
self.cost_dist_ = nil
}
func setCost(histogram []uint32, histogram_size uint, literal_histogram bool, cost []float32) {
var sum uint = 0
var missing_symbol_sum uint
var log2sum float32
var missing_symbol_cost float32
var i uint
for i = 0; i < histogram_size; i++ {
sum += uint(histogram[i])
}
log2sum = float32(fastLog2(sum))
missing_symbol_sum = sum
if !literal_histogram {
for i = 0; i < histogram_size; i++ {
if histogram[i] == 0 {
missing_symbol_sum++
}
}
}
missing_symbol_cost = float32(fastLog2(missing_symbol_sum)) + 2
for i = 0; i < histogram_size; i++ {
if histogram[i] == 0 {
cost[i] = missing_symbol_cost
continue
}
/* Shannon bits for this symbol. */
cost[i] = log2sum - float32(fastLog2(uint(histogram[i])))
/* Cannot be coded with less than 1 bit */
if cost[i] < 1 {
cost[i] = 1
}
}
}
func zopfliCostModelSetFromCommands(self *zopfliCostModel, position uint, ringbuffer []byte, ringbuffer_mask uint, commands []command, num_commands uint, last_insert_len uint) {
var histogram_literal [numLiteralSymbols]uint32
var histogram_cmd [numCommandSymbols]uint32
var histogram_dist [maxEffectiveDistanceAlphabetSize]uint32
var cost_literal [numLiteralSymbols]float32
var pos uint = position - last_insert_len
var min_cost_cmd float32 = kInfinity
var i uint
var cost_cmd []float32 = self.cost_cmd_[:]
var literal_costs []float32
histogram_literal = [numLiteralSymbols]uint32{}
histogram_cmd = [numCommandSymbols]uint32{}
histogram_dist = [maxEffectiveDistanceAlphabetSize]uint32{}
for i = 0; i < num_commands; i++ {
var inslength uint = uint(commands[i].insert_len_)
var copylength uint = uint(commandCopyLen(&commands[i]))
var distcode uint = uint(commands[i].dist_prefix_) & 0x3FF
var cmdcode uint = uint(commands[i].cmd_prefix_)
var j uint
histogram_cmd[cmdcode]++
if cmdcode >= 128 {
histogram_dist[distcode]++
}
for j = 0; j < inslength; j++ {
histogram_literal[ringbuffer[(pos+j)&ringbuffer_mask]]++
}
pos += inslength + copylength
}
setCost(histogram_literal[:], numLiteralSymbols, true, cost_literal[:])
setCost(histogram_cmd[:], numCommandSymbols, false, cost_cmd)
setCost(histogram_dist[:], uint(self.distance_histogram_size), false, self.cost_dist_)
for i = 0; i < numCommandSymbols; i++ {
min_cost_cmd = brotli_min_float(min_cost_cmd, cost_cmd[i])
}
self.min_cost_cmd_ = min_cost_cmd
{
literal_costs = self.literal_costs_
var literal_carry float32 = 0.0
var num_bytes uint = self.num_bytes_
literal_costs[0] = 0.0
for i = 0; i < num_bytes; i++ {
literal_carry += cost_literal[ringbuffer[(position+i)&ringbuffer_mask]]
literal_costs[i+1] = literal_costs[i] + literal_carry
literal_carry -= literal_costs[i+1] - literal_costs[i]
}
}
}
func zopfliCostModelSetFromLiteralCosts(self *zopfliCostModel, position uint, ringbuffer []byte, ringbuffer_mask uint) {
var literal_costs []float32 = self.literal_costs_
var literal_carry float32 = 0.0
var cost_dist []float32 = self.cost_dist_
var cost_cmd []float32 = self.cost_cmd_[:]
var num_bytes uint = self.num_bytes_
var i uint
estimateBitCostsForLiterals(position, num_bytes, ringbuffer_mask, ringbuffer, literal_costs[1:])
literal_costs[0] = 0.0
for i = 0; i < num_bytes; i++ {
literal_carry += literal_costs[i+1]
literal_costs[i+1] = literal_costs[i] + literal_carry
literal_carry -= literal_costs[i+1] - literal_costs[i]
}
for i = 0; i < numCommandSymbols; i++ {
cost_cmd[i] = float32(fastLog2(uint(11 + uint32(i))))
}
for i = 0; uint32(i) < self.distance_histogram_size; i++ {
cost_dist[i] = float32(fastLog2(uint(20 + uint32(i))))
}
self.min_cost_cmd_ = float32(fastLog2(11))
}
func zopfliCostModelGetCommandCost(self *zopfliCostModel, cmdcode uint16) float32 {
return self.cost_cmd_[cmdcode]
}
func zopfliCostModelGetDistanceCost(self *zopfliCostModel, distcode uint) float32 {
return self.cost_dist_[distcode]
}
func zopfliCostModelGetLiteralCosts(self *zopfliCostModel, from uint, to uint) float32 {
return self.literal_costs_[to] - self.literal_costs_[from]
}
func zopfliCostModelGetMinCostCmd(self *zopfliCostModel) float32 {
return self.min_cost_cmd_
}
/* REQUIRES: len >= 2, start_pos <= pos */
/* REQUIRES: cost < kInfinity, nodes[start_pos].cost < kInfinity */
/* Maintains the "ZopfliNode array invariant". */
func updateZopfliNode(nodes []zopfliNode, pos uint, start_pos uint, len uint, len_code uint, dist uint, short_code uint, cost float32) {
var next *zopfliNode = &nodes[pos+len]
next.length = uint32(len | (len+9-len_code)<<25)
next.distance = uint32(dist)
next.dcode_insert_length = uint32(short_code<<27 | (pos - start_pos))
next.u.cost = cost
}
type posData struct {
pos uint
distance_cache [4]int
costdiff float32
cost float32
}
/* Maintains the smallest 8 cost difference together with their positions */
type startPosQueue struct {
q_ [8]posData
idx_ uint
}
func initStartPosQueue(self *startPosQueue) {
self.idx_ = 0
}
func startPosQueueSize(self *startPosQueue) uint {
return brotli_min_size_t(self.idx_, 8)
}
func startPosQueuePush(self *startPosQueue, posdata *posData) {
var offset uint = ^(self.idx_) & 7
self.idx_++
var len uint = startPosQueueSize(self)
var i uint
var q []posData = self.q_[:]
q[offset] = *posdata
/* Restore the sorted order. In the list of |len| items at most |len - 1|
adjacent element comparisons / swaps are required. */
for i = 1; i < len; i++ {
if q[offset&7].costdiff > q[(offset+1)&7].costdiff {
var tmp posData = q[offset&7]
q[offset&7] = q[(offset+1)&7]
q[(offset+1)&7] = tmp
}
offset++
}
}
func startPosQueueAt(self *startPosQueue, k uint) *posData {
return &self.q_[(k-self.idx_)&7]
}
/* Returns the minimum possible copy length that can improve the cost of any */
/* future position. */
func computeMinimumCopyLength(start_cost float32, nodes []zopfliNode, num_bytes uint, pos uint) uint {
var min_cost float32 = start_cost
var len uint = 2
var next_len_bucket uint = 4
/* Compute the minimum possible cost of reaching any future position. */
var next_len_offset uint = 10
for pos+len <= num_bytes && nodes[pos+len].u.cost <= min_cost {
/* We already reached (pos + len) with no more cost than the minimum
possible cost of reaching anything from this pos, so there is no point in
looking for lengths <= len. */
len++
if len == next_len_offset {
/* We reached the next copy length code bucket, so we add one more
extra bit to the minimum cost. */
min_cost += 1.0
next_len_offset += next_len_bucket
next_len_bucket *= 2
}
}
return uint(len)
}
/* REQUIRES: nodes[pos].cost < kInfinity
REQUIRES: nodes[0..pos] satisfies that "ZopfliNode array invariant". */
func computeDistanceShortcut(block_start uint, pos uint, max_backward_limit uint, gap uint, nodes []zopfliNode) uint32 {
var clen uint = uint(zopfliNodeCopyLength(&nodes[pos]))
var ilen uint = uint(nodes[pos].dcode_insert_length & 0x7FFFFFF)
var dist uint = uint(zopfliNodeCopyDistance(&nodes[pos]))
/* Since |block_start + pos| is the end position of the command, the copy part
starts from |block_start + pos - clen|. Distances that are greater than
this or greater than |max_backward_limit| + |gap| are static dictionary
references, and do not update the last distances.
Also distance code 0 (last distance) does not update the last distances. */
if pos == 0 {
return 0
} else if dist+clen <= block_start+pos+gap && dist <= max_backward_limit+gap && zopfliNodeDistanceCode(&nodes[pos]) > 0 {
return uint32(pos)
} else {
return nodes[pos-clen-ilen].u.shortcut
}
}
/* Fills in dist_cache[0..3] with the last four distances (as defined by
Section 4. of the Spec) that would be used at (block_start + pos) if we
used the shortest path of commands from block_start, computed from
nodes[0..pos]. The last four distances at block_start are in
starting_dist_cache[0..3].
REQUIRES: nodes[pos].cost < kInfinity
REQUIRES: nodes[0..pos] satisfies that "ZopfliNode array invariant". */
func computeDistanceCache(pos uint, starting_dist_cache []int, nodes []zopfliNode, dist_cache []int) {
var idx int = 0
var p uint = uint(nodes[pos].u.shortcut)
for idx < 4 && p > 0 {
var ilen uint = uint(nodes[p].dcode_insert_length & 0x7FFFFFF)
var clen uint = uint(zopfliNodeCopyLength(&nodes[p]))
var dist uint = uint(zopfliNodeCopyDistance(&nodes[p]))
dist_cache[idx] = int(dist)
idx++
/* Because of prerequisite, p >= clen + ilen >= 2. */
p = uint(nodes[p-clen-ilen].u.shortcut)
}
for ; idx < 4; idx++ {
dist_cache[idx] = starting_dist_cache[0]
starting_dist_cache = starting_dist_cache[1:]
}
}
/* Maintains "ZopfliNode array invariant" and pushes node to the queue, if it
is eligible. */
func evaluateNode(block_start uint, pos uint, max_backward_limit uint, gap uint, starting_dist_cache []int, model *zopfliCostModel, queue *startPosQueue, nodes []zopfliNode) {
/* Save cost, because ComputeDistanceCache invalidates it. */
var node_cost float32 = nodes[pos].u.cost
nodes[pos].u.shortcut = computeDistanceShortcut(block_start, pos, max_backward_limit, gap, nodes)
if node_cost <= zopfliCostModelGetLiteralCosts(model, 0, pos) {
var posdata posData
posdata.pos = pos
posdata.cost = node_cost
posdata.costdiff = node_cost - zopfliCostModelGetLiteralCosts(model, 0, pos)
computeDistanceCache(pos, starting_dist_cache, nodes, posdata.distance_cache[:])
startPosQueuePush(queue, &posdata)
}
}
/* Returns longest copy length. */
func updateNodes(num_bytes uint, block_start uint, pos uint, ringbuffer []byte, ringbuffer_mask uint, params *encoderParams, max_backward_limit uint, starting_dist_cache []int, num_matches uint, matches []backwardMatch, model *zopfliCostModel, queue *startPosQueue, nodes []zopfliNode) uint {
var cur_ix uint = block_start + pos
var cur_ix_masked uint = cur_ix & ringbuffer_mask
var max_distance uint = brotli_min_size_t(cur_ix, max_backward_limit)
var max_len uint = num_bytes - pos
var max_zopfli_len uint = maxZopfliLen(params)
var max_iters uint = maxZopfliCandidates(params)
var min_len uint
var result uint = 0
var k uint
var gap uint = 0
evaluateNode(block_start, pos, max_backward_limit, gap, starting_dist_cache, model, queue, nodes)
{
var posdata *posData = startPosQueueAt(queue, 0)
var min_cost float32 = (posdata.cost + zopfliCostModelGetMinCostCmd(model) + zopfliCostModelGetLiteralCosts(model, posdata.pos, pos))
min_len = computeMinimumCopyLength(min_cost, nodes, num_bytes, pos)
}
/* Go over the command starting positions in order of increasing cost
difference. */
for k = 0; k < max_iters && k < startPosQueueSize(queue); k++ {
var posdata *posData = startPosQueueAt(queue, k)
var start uint = posdata.pos
var inscode uint16 = getInsertLengthCode(pos - start)
var start_costdiff float32 = posdata.costdiff
var base_cost float32 = start_costdiff + float32(getInsertExtra(inscode)) + zopfliCostModelGetLiteralCosts(model, 0, pos)
var best_len uint = min_len - 1
var j uint = 0
/* Look for last distance matches using the distance cache from this
starting position. */
for ; j < numDistanceShortCodes && best_len < max_len; j++ {
var idx uint = uint(kDistanceCacheIndex[j])
var backward uint = uint(posdata.distance_cache[idx] + kDistanceCacheOffset[j])
var prev_ix uint = cur_ix - backward
var len uint = 0
var continuation byte = ringbuffer[cur_ix_masked+best_len]
if cur_ix_masked+best_len > ringbuffer_mask {
break
}
if backward > max_distance+gap {
/* Word dictionary -> ignore. */
continue
}
if backward <= max_distance {
/* Regular backward reference. */
if prev_ix >= cur_ix {
continue
}
prev_ix &= ringbuffer_mask
if prev_ix+best_len > ringbuffer_mask || continuation != ringbuffer[prev_ix+best_len] {
continue
}
len = findMatchLengthWithLimit(ringbuffer[prev_ix:], ringbuffer[cur_ix_masked:], max_len)
} else {
continue
}
{
var dist_cost float32 = base_cost + zopfliCostModelGetDistanceCost(model, j)
var l uint
for l = best_len + 1; l <= len; l++ {
var copycode uint16 = getCopyLengthCode(l)
var cmdcode uint16 = combineLengthCodes(inscode, copycode, j == 0)
var tmp float32
if cmdcode < 128 {
tmp = base_cost
} else {
tmp = dist_cost
}
var cost float32 = tmp + float32(getCopyExtra(copycode)) + zopfliCostModelGetCommandCost(model, cmdcode)
if cost < nodes[pos+l].u.cost {
updateZopfliNode(nodes, pos, start, l, l, backward, j+1, cost)
result = brotli_max_size_t(result, l)
}
best_len = l
}
}
}
/* At higher iterations look only for new last distance matches, since
looking only for new command start positions with the same distances
does not help much. */
if k >= 2 {
continue
}
{
/* Loop through all possible copy lengths at this position. */
var len uint = min_len
for j = 0; j < num_matches; j++ {
var match backwardMatch = matches[j]
var dist uint = uint(match.distance)
var is_dictionary_match bool = (dist > max_distance+gap)
var dist_code uint = dist + numDistanceShortCodes - 1
var dist_symbol uint16
var distextra uint32
var distnumextra uint32
var dist_cost float32
var max_match_len uint
/* We already tried all possible last distance matches, so we can use
normal distance code here. */
prefixEncodeCopyDistance(dist_code, uint(params.dist.num_direct_distance_codes), uint(params.dist.distance_postfix_bits), &dist_symbol, &distextra)
distnumextra = uint32(dist_symbol) >> 10
dist_cost = base_cost + float32(distnumextra) + zopfliCostModelGetDistanceCost(model, uint(dist_symbol)&0x3FF)
/* Try all copy lengths up until the maximum copy length corresponding
to this distance. If the distance refers to the static dictionary, or
the maximum length is long enough, try only one maximum length. */
max_match_len = backwardMatchLength(&match)
if len < max_match_len && (is_dictionary_match || max_match_len > max_zopfli_len) {
len = max_match_len
}
for ; len <= max_match_len; len++ {
var len_code uint
if is_dictionary_match {
len_code = backwardMatchLengthCode(&match)
} else {
len_code = len
}
var copycode uint16 = getCopyLengthCode(len_code)
var cmdcode uint16 = combineLengthCodes(inscode, copycode, false)
var cost float32 = dist_cost + float32(getCopyExtra(copycode)) + zopfliCostModelGetCommandCost(model, cmdcode)
if cost < nodes[pos+len].u.cost {
updateZopfliNode(nodes, pos, start, uint(len), len_code, dist, 0, cost)
result = brotli_max_size_t(result, uint(len))
}
}
}
}
}
return result
}
func computeShortestPathFromNodes(num_bytes uint, nodes []zopfliNode) uint {
var index uint = num_bytes
var num_commands uint = 0
for nodes[index].dcode_insert_length&0x7FFFFFF == 0 && nodes[index].length == 1 {
index--
}
nodes[index].u.next = math.MaxUint32
for index != 0 {
var len uint = uint(zopfliNodeCommandLength(&nodes[index]))
index -= uint(len)
nodes[index].u.next = uint32(len)
num_commands++
}
return num_commands
}
/* REQUIRES: nodes != NULL and len(nodes) >= num_bytes + 1 */
func zopfliCreateCommands(num_bytes uint, block_start uint, nodes []zopfliNode, dist_cache []int, last_insert_len *uint, params *encoderParams, commands []command, num_literals *uint) {
var max_backward_limit uint = maxBackwardLimit(params.lgwin)
var pos uint = 0
var offset uint32 = nodes[0].u.next
var i uint
var gap uint = 0
for i = 0; offset != math.MaxUint32; i++ {
var next *zopfliNode = &nodes[uint32(pos)+offset]
var copy_length uint = uint(zopfliNodeCopyLength(next))
var insert_length uint = uint(next.dcode_insert_length & 0x7FFFFFF)
pos += insert_length
offset = next.u.next
if i == 0 {
insert_length += *last_insert_len
*last_insert_len = 0
}
{
var distance uint = uint(zopfliNodeCopyDistance(next))
var len_code uint = uint(zopfliNodeLengthCode(next))
var max_distance uint = brotli_min_size_t(block_start+pos, max_backward_limit)
var is_dictionary bool = (distance > max_distance+gap)
var dist_code uint = uint(zopfliNodeDistanceCode(next))
initCommand(&commands[i], &params.dist, insert_length, copy_length, int(len_code)-int(copy_length), dist_code)
if !is_dictionary && dist_code > 0 {
dist_cache[3] = dist_cache[2]
dist_cache[2] = dist_cache[1]
dist_cache[1] = dist_cache[0]
dist_cache[0] = int(distance)
}
}
*num_literals += insert_length
pos += copy_length
}
*last_insert_len += num_bytes - pos
}
func zopfliIterate(num_bytes uint, position uint, ringbuffer []byte, ringbuffer_mask uint, params *encoderParams, gap uint, dist_cache []int, model *zopfliCostModel, num_matches []uint32, matches []backwardMatch, nodes []zopfliNode) uint {
var max_backward_limit uint = maxBackwardLimit(params.lgwin)
var max_zopfli_len uint = maxZopfliLen(params)
var queue startPosQueue
var cur_match_pos uint = 0
var i uint
nodes[0].length = 0
nodes[0].u.cost = 0
initStartPosQueue(&queue)
for i = 0; i+3 < num_bytes; i++ {
var skip uint = updateNodes(num_bytes, position, i, ringbuffer, ringbuffer_mask, params, max_backward_limit, dist_cache, uint(num_matches[i]), matches[cur_match_pos:], model, &queue, nodes)
if skip < longCopyQuickStep {
skip = 0
}
cur_match_pos += uint(num_matches[i])
if num_matches[i] == 1 && backwardMatchLength(&matches[cur_match_pos-1]) > max_zopfli_len {
skip = brotli_max_size_t(backwardMatchLength(&matches[cur_match_pos-1]), skip)
}
if skip > 1 {
skip--
for skip != 0 {
i++
if i+3 >= num_bytes {
break
}
evaluateNode(position, i, max_backward_limit, gap, dist_cache, model, &queue, nodes)
cur_match_pos += uint(num_matches[i])
skip--
}
}
}
return computeShortestPathFromNodes(num_bytes, nodes)
}
/* Computes the shortest path of commands from position to at most
position + num_bytes.
On return, path->size() is the number of commands found and path[i] is the
length of the i-th command (copy length plus insert length).
Note that the sum of the lengths of all commands can be less than num_bytes.
On return, the nodes[0..num_bytes] array will have the following
"ZopfliNode array invariant":
For each i in [1..num_bytes], if nodes[i].cost < kInfinity, then
(1) nodes[i].copy_length() >= 2
(2) nodes[i].command_length() <= i and
(3) nodes[i - nodes[i].command_length()].cost < kInfinity
REQUIRES: nodes != nil and len(nodes) >= num_bytes + 1 */
func zopfliComputeShortestPath(num_bytes uint, position uint, ringbuffer []byte, ringbuffer_mask uint, params *encoderParams, dist_cache []int, hasher *h10, nodes []zopfliNode) uint {
var max_backward_limit uint = maxBackwardLimit(params.lgwin)
var max_zopfli_len uint = maxZopfliLen(params)
var model zopfliCostModel
var queue startPosQueue
var matches [2 * (maxNumMatchesH10 + 64)]backwardMatch
var store_end uint
if num_bytes >= hasher.StoreLookahead() {
store_end = position + num_bytes - hasher.StoreLookahead() + 1
} else {
store_end = position
}
var i uint
var gap uint = 0
var lz_matches_offset uint = 0
nodes[0].length = 0
nodes[0].u.cost = 0
initZopfliCostModel(&model, &params.dist, num_bytes)
zopfliCostModelSetFromLiteralCosts(&model, position, ringbuffer, ringbuffer_mask)
initStartPosQueue(&queue)
for i = 0; i+hasher.HashTypeLength()-1 < num_bytes; i++ {
var pos uint = position + i
var max_distance uint = brotli_min_size_t(pos, max_backward_limit)
var skip uint
var num_matches uint
num_matches = findAllMatchesH10(hasher, &params.dictionary, ringbuffer, ringbuffer_mask, pos, num_bytes-i, max_distance, gap, params, matches[lz_matches_offset:])
if num_matches > 0 && backwardMatchLength(&matches[num_matches-1]) > max_zopfli_len {
matches[0] = matches[num_matches-1]
num_matches = 1
}
skip = updateNodes(num_bytes, position, i, ringbuffer, ringbuffer_mask, params, max_backward_limit, dist_cache, num_matches, matches[:], &model, &queue, nodes)
if skip < longCopyQuickStep {
skip = 0
}
if num_matches == 1 && backwardMatchLength(&matches[0]) > max_zopfli_len {
skip = brotli_max_size_t(backwardMatchLength(&matches[0]), skip)
}
if skip > 1 {
/* Add the tail of the copy to the hasher. */
hasher.StoreRange(ringbuffer, ringbuffer_mask, pos+1, brotli_min_size_t(pos+skip, store_end))
skip--
for skip != 0 {
i++
if i+hasher.HashTypeLength()-1 >= num_bytes {
break
}
evaluateNode(position, i, max_backward_limit, gap, dist_cache, &model, &queue, nodes)
skip--
}
}
}
cleanupZopfliCostModel(&model)
return computeShortestPathFromNodes(num_bytes, nodes)
}
func createZopfliBackwardReferences(num_bytes uint, position uint, ringbuffer []byte, ringbuffer_mask uint, params *encoderParams, hasher *h10, dist_cache []int, last_insert_len *uint, commands []command, num_commands *uint, num_literals *uint) {
var nodes []zopfliNode
nodes = make([]zopfliNode, (num_bytes + 1))
initZopfliNodes(nodes, num_bytes+1)
*num_commands += zopfliComputeShortestPath(num_bytes, position, ringbuffer, ringbuffer_mask, params, dist_cache, hasher, nodes)
zopfliCreateCommands(num_bytes, position, nodes, dist_cache, last_insert_len, params, commands, num_literals)
nodes = nil
}
func createHqZopfliBackwardReferences(num_bytes uint, position uint, ringbuffer []byte, ringbuffer_mask uint, params *encoderParams, hasher hasherHandle, dist_cache []int, last_insert_len *uint, commands []command, num_commands *uint, num_literals *uint) {
var max_backward_limit uint = maxBackwardLimit(params.lgwin)
var num_matches []uint32 = make([]uint32, num_bytes)
var matches_size uint = 4 * num_bytes
var store_end uint
if num_bytes >= hasher.StoreLookahead() {
store_end = position + num_bytes - hasher.StoreLookahead() + 1
} else {
store_end = position
}
var cur_match_pos uint = 0
var i uint
var orig_num_literals uint
var orig_last_insert_len uint
var orig_dist_cache [4]int
var orig_num_commands uint
var model zopfliCostModel
var nodes []zopfliNode
var matches []backwardMatch = make([]backwardMatch, matches_size)
var gap uint = 0
var shadow_matches uint = 0
var new_array []backwardMatch
for i = 0; i+hasher.HashTypeLength()-1 < num_bytes; i++ {
var pos uint = position + i
var max_distance uint = brotli_min_size_t(pos, max_backward_limit)
var max_length uint = num_bytes - i
var num_found_matches uint
var cur_match_end uint
var j uint
/* Ensure that we have enough free slots. */
if matches_size < cur_match_pos+maxNumMatchesH10+shadow_matches {
var new_size uint = matches_size
if new_size == 0 {
new_size = cur_match_pos + maxNumMatchesH10 + shadow_matches
}
for new_size < cur_match_pos+maxNumMatchesH10+shadow_matches {
new_size *= 2
}
new_array = make([]backwardMatch, new_size)
if matches_size != 0 {
copy(new_array, matches[:matches_size])
}
matches = new_array
matches_size = new_size
}
num_found_matches = findAllMatchesH10(hasher.(*h10), &params.dictionary, ringbuffer, ringbuffer_mask, pos, max_length, max_distance, gap, params, matches[cur_match_pos+shadow_matches:])
cur_match_end = cur_match_pos + num_found_matches
for j = cur_match_pos; j+1 < cur_match_end; j++ {
assert(backwardMatchLength(&matches[j]) <= backwardMatchLength(&matches[j+1]))
}
num_matches[i] = uint32(num_found_matches)
if num_found_matches > 0 {
var match_len uint = backwardMatchLength(&matches[cur_match_end-1])
if match_len > maxZopfliLenQuality11 {
var skip uint = match_len - 1
matches[cur_match_pos] = matches[cur_match_end-1]
cur_match_pos++
num_matches[i] = 1
/* Add the tail of the copy to the hasher. */
hasher.StoreRange(ringbuffer, ringbuffer_mask, pos+1, brotli_min_size_t(pos+match_len, store_end))
var pos uint = i
for i := 0; i < int(skip); i++ {
num_matches[pos+1:][i] = 0
}
i += skip
} else {
cur_match_pos = cur_match_end
}
}
}
orig_num_literals = *num_literals
orig_last_insert_len = *last_insert_len
copy(orig_dist_cache[:], dist_cache[:4])
orig_num_commands = *num_commands
nodes = make([]zopfliNode, (num_bytes + 1))
initZopfliCostModel(&model, &params.dist, num_bytes)
for i = 0; i < 2; i++ {
initZopfliNodes(nodes, num_bytes+1)
if i == 0 {
zopfliCostModelSetFromLiteralCosts(&model, position, ringbuffer, ringbuffer_mask)
} else {
zopfliCostModelSetFromCommands(&model, position, ringbuffer, ringbuffer_mask, commands, *num_commands-orig_num_commands, orig_last_insert_len)
}
*num_commands = orig_num_commands
*num_literals = orig_num_literals
*last_insert_len = orig_last_insert_len
copy(dist_cache, orig_dist_cache[:4])
*num_commands += zopfliIterate(num_bytes, position, ringbuffer, ringbuffer_mask, params, gap, dist_cache, &model, num_matches, matches, nodes)
zopfliCreateCommands(num_bytes, position, nodes, dist_cache, last_insert_len, params, commands, num_literals)
}
cleanupZopfliCostModel(&model)
nodes = nil
matches = nil
num_matches = nil
}