package brotli import "math" /* Copyright 2010 Google Inc. All Rights Reserved. Distributed under MIT license. See file LICENSE for detail or copy at https://opensource.org/licenses/MIT */ /* Entropy encoding (Huffman) utilities. */ /* Copyright 2010 Google Inc. All Rights Reserved. Distributed under MIT license. See file LICENSE for detail or copy at https://opensource.org/licenses/MIT */ /* Entropy encoding (Huffman) utilities. */ /* A node of a Huffman tree. */ type huffmanTree struct { total_count_ uint32 index_left_ int16 index_right_or_value_ int16 } func initHuffmanTree(self *huffmanTree, count uint32, left int16, right int16) { self.total_count_ = count self.index_left_ = left self.index_right_or_value_ = right } /* Returns 1 is assignment of depths succeeded, otherwise 0. */ /* This function will create a Huffman tree. The (data,length) contains the population counts. The tree_limit is the maximum bit depth of the Huffman codes. The depth contains the tree, i.e., how many bits are used for the symbol. The actual Huffman tree is constructed in the tree[] array, which has to be at least 2 * length + 1 long. See http://en.wikipedia.org/wiki/Huffman_coding */ /* Change the population counts in a way that the consequent Huffman tree compression, especially its RLE-part will be more likely to compress this data more efficiently. length contains the size of the histogram. counts contains the population counts. good_for_rle is a buffer of at least length size */ /* Write a Huffman tree from bit depths into the bit-stream representation of a Huffman tree. The generated Huffman tree is to be compressed once more using a Huffman tree */ /* Get the actual bit values for a tree of bit depths. */ /* Input size optimized Shell sort. */ type huffmanTreeComparator func(*huffmanTree, *huffmanTree) bool var sortHuffmanTreeItems_gaps = []uint{132, 57, 23, 10, 4, 1} func sortHuffmanTreeItems(items []huffmanTree, n uint, comparator huffmanTreeComparator) { if n < 13 { /* Insertion sort. */ var i uint for i = 1; i < n; i++ { var tmp huffmanTree = items[i] var k uint = i var j uint = i - 1 for comparator(&tmp, &items[j]) { items[k] = items[j] k = j tmp10 := j j-- if tmp10 == 0 { break } } items[k] = tmp } return } else { var g int if n < 57 { g = 2 } else { g = 0 } for ; g < 6; g++ { var gap uint = sortHuffmanTreeItems_gaps[g] var i uint for i = gap; i < n; i++ { var j uint = i var tmp huffmanTree = items[i] for ; j >= gap && comparator(&tmp, &items[j-gap]); j -= gap { items[j] = items[j-gap] } items[j] = tmp } } } } func setDepth(p0 int, pool []huffmanTree, depth []byte, max_depth int) bool { var stack [16]int var level int = 0 var p int = p0 assert(max_depth <= 15) stack[0] = -1 for { if pool[p].index_left_ >= 0 { level++ if level > max_depth { return false } stack[level] = int(pool[p].index_right_or_value_) p = int(pool[p].index_left_) continue } else { depth[pool[p].index_right_or_value_] = byte(level) } for level >= 0 && stack[level] == -1 { level-- } if level < 0 { return true } p = stack[level] stack[level] = -1 } } /* Sort the root nodes, least popular first. */ func sortHuffmanTree(v0 *huffmanTree, v1 *huffmanTree) bool { if v0.total_count_ != v1.total_count_ { return v0.total_count_ < v1.total_count_ } return v0.index_right_or_value_ > v1.index_right_or_value_ } /* This function will create a Huffman tree. The catch here is that the tree cannot be arbitrarily deep. Brotli specifies a maximum depth of 15 bits for "code trees" and 7 bits for "code length code trees." count_limit is the value that is to be faked as the minimum value and this minimum value is raised until the tree matches the maximum length requirement. This algorithm is not of excellent performance for very long data blocks, especially when population counts are longer than 2**tree_limit, but we are not planning to use this with extremely long blocks. See http://en.wikipedia.org/wiki/Huffman_coding */ func createHuffmanTree(data []uint32, length uint, tree_limit int, tree []huffmanTree, depth []byte) { var count_limit uint32 var sentinel huffmanTree initHuffmanTree(&sentinel, math.MaxUint32, -1, -1) /* For block sizes below 64 kB, we never need to do a second iteration of this loop. Probably all of our block sizes will be smaller than that, so this loop is mostly of academic interest. If we actually would need this, we would be better off with the Katajainen algorithm. */ for count_limit = 1; ; count_limit *= 2 { var n uint = 0 var i uint var j uint var k uint for i = length; i != 0; { i-- if data[i] != 0 { var count uint32 = brotli_max_uint32_t(data[i], count_limit) initHuffmanTree(&tree[n], count, -1, int16(i)) n++ } } if n == 1 { depth[tree[0].index_right_or_value_] = 1 /* Only one element. */ break } sortHuffmanTreeItems(tree, n, huffmanTreeComparator(sortHuffmanTree)) /* The nodes are: [0, n): the sorted leaf nodes that we start with. [n]: we add a sentinel here. [n + 1, 2n): new parent nodes are added here, starting from (n+1). These are naturally in ascending order. [2n]: we add a sentinel at the end as well. There will be (2n+1) elements at the end. */ tree[n] = sentinel tree[n+1] = sentinel i = 0 /* Points to the next leaf node. */ j = n + 1 /* Points to the next non-leaf node. */ for k = n - 1; k != 0; k-- { var left uint var right uint if tree[i].total_count_ <= tree[j].total_count_ { left = i i++ } else { left = j j++ } if tree[i].total_count_ <= tree[j].total_count_ { right = i i++ } else { right = j j++ } { /* The sentinel node becomes the parent node. */ var j_end uint = 2*n - k tree[j_end].total_count_ = tree[left].total_count_ + tree[right].total_count_ tree[j_end].index_left_ = int16(left) tree[j_end].index_right_or_value_ = int16(right) /* Add back the last sentinel node. */ tree[j_end+1] = sentinel } } if setDepth(int(2*n-1), tree[0:], depth, tree_limit) { /* We need to pack the Huffman tree in tree_limit bits. If this was not successful, add fake entities to the lowest values and retry. */ break } } } func reverse(v []byte, start uint, end uint) { end-- for start < end { var tmp byte = v[start] v[start] = v[end] v[end] = tmp start++ end-- } } func writeHuffmanTreeRepetitions(previous_value byte, value byte, repetitions uint, tree_size *uint, tree []byte, extra_bits_data []byte) { assert(repetitions > 0) if previous_value != value { tree[*tree_size] = value extra_bits_data[*tree_size] = 0 (*tree_size)++ repetitions-- } if repetitions == 7 { tree[*tree_size] = value extra_bits_data[*tree_size] = 0 (*tree_size)++ repetitions-- } if repetitions < 3 { var i uint for i = 0; i < repetitions; i++ { tree[*tree_size] = value extra_bits_data[*tree_size] = 0 (*tree_size)++ } } else { var start uint = *tree_size repetitions -= 3 for { tree[*tree_size] = repeatPreviousCodeLength extra_bits_data[*tree_size] = byte(repetitions & 0x3) (*tree_size)++ repetitions >>= 2 if repetitions == 0 { break } repetitions-- } reverse(tree, start, *tree_size) reverse(extra_bits_data, start, *tree_size) } } func writeHuffmanTreeRepetitionsZeros(repetitions uint, tree_size *uint, tree []byte, extra_bits_data []byte) { if repetitions == 11 { tree[*tree_size] = 0 extra_bits_data[*tree_size] = 0 (*tree_size)++ repetitions-- } if repetitions < 3 { var i uint for i = 0; i < repetitions; i++ { tree[*tree_size] = 0 extra_bits_data[*tree_size] = 0 (*tree_size)++ } } else { var start uint = *tree_size repetitions -= 3 for { tree[*tree_size] = repeatZeroCodeLength extra_bits_data[*tree_size] = byte(repetitions & 0x7) (*tree_size)++ repetitions >>= 3 if repetitions == 0 { break } repetitions-- } reverse(tree, start, *tree_size) reverse(extra_bits_data, start, *tree_size) } } func optimizeHuffmanCountsForRLE(length uint, counts []uint32, good_for_rle []byte) { var nonzero_count uint = 0 var stride uint var limit uint var sum uint var streak_limit uint = 1240 var i uint /* Let's make the Huffman code more compatible with RLE encoding. */ for i = 0; i < length; i++ { if counts[i] != 0 { nonzero_count++ } } if nonzero_count < 16 { return } for length != 0 && counts[length-1] == 0 { length-- } if length == 0 { return /* All zeros. */ } /* Now counts[0..length - 1] does not have trailing zeros. */ { var nonzeros uint = 0 var smallest_nonzero uint32 = 1 << 30 for i = 0; i < length; i++ { if counts[i] != 0 { nonzeros++ if smallest_nonzero > counts[i] { smallest_nonzero = counts[i] } } } if nonzeros < 5 { /* Small histogram will model it well. */ return } if smallest_nonzero < 4 { var zeros uint = length - nonzeros if zeros < 6 { for i = 1; i < length-1; i++ { if counts[i-1] != 0 && counts[i] == 0 && counts[i+1] != 0 { counts[i] = 1 } } } } if nonzeros < 28 { return } } /* 2) Let's mark all population counts that already can be encoded with an RLE code. */ for i := 0; i < int(length); i++ { good_for_rle[i] = 0 } { var symbol uint32 = counts[0] /* Let's not spoil any of the existing good RLE codes. Mark any seq of 0's that is longer as 5 as a good_for_rle. Mark any seq of non-0's that is longer as 7 as a good_for_rle. */ var step uint = 0 for i = 0; i <= length; i++ { if i == length || counts[i] != symbol { if (symbol == 0 && step >= 5) || (symbol != 0 && step >= 7) { var k uint for k = 0; k < step; k++ { good_for_rle[i-k-1] = 1 } } step = 1 if i != length { symbol = counts[i] } } else { step++ } } } /* 3) Let's replace those population counts that lead to more RLE codes. Math here is in 24.8 fixed point representation. */ stride = 0 limit = uint(256*(counts[0]+counts[1]+counts[2])/3 + 420) sum = 0 for i = 0; i <= length; i++ { if i == length || good_for_rle[i] != 0 || (i != 0 && good_for_rle[i-1] != 0) || (256*counts[i]-uint32(limit)+uint32(streak_limit)) >= uint32(2*streak_limit) { if stride >= 4 || (stride >= 3 && sum == 0) { var k uint var count uint = (sum + stride/2) / stride /* The stride must end, collapse what we have, if we have enough (4). */ if count == 0 { count = 1 } if sum == 0 { /* Don't make an all zeros stride to be upgraded to ones. */ count = 0 } for k = 0; k < stride; k++ { /* We don't want to change value at counts[i], that is already belonging to the next stride. Thus - 1. */ counts[i-k-1] = uint32(count) } } stride = 0 sum = 0 if i < length-2 { /* All interesting strides have a count of at least 4, */ /* at least when non-zeros. */ limit = uint(256*(counts[i]+counts[i+1]+counts[i+2])/3 + 420) } else if i < length { limit = uint(256 * counts[i]) } else { limit = 0 } } stride++ if i != length { sum += uint(counts[i]) if stride >= 4 { limit = (256*sum + stride/2) / stride } if stride == 4 { limit += 120 } } } } func decideOverRLEUse(depth []byte, length uint, use_rle_for_non_zero *bool, use_rle_for_zero *bool) { var total_reps_zero uint = 0 var total_reps_non_zero uint = 0 var count_reps_zero uint = 1 var count_reps_non_zero uint = 1 var i uint for i = 0; i < length; { var value byte = depth[i] var reps uint = 1 var k uint for k = i + 1; k < length && depth[k] == value; k++ { reps++ } if reps >= 3 && value == 0 { total_reps_zero += reps count_reps_zero++ } if reps >= 4 && value != 0 { total_reps_non_zero += reps count_reps_non_zero++ } i += reps } *use_rle_for_non_zero = total_reps_non_zero > count_reps_non_zero*2 *use_rle_for_zero = total_reps_zero > count_reps_zero*2 } func writeHuffmanTree(depth []byte, length uint, tree_size *uint, tree []byte, extra_bits_data []byte) { var previous_value byte = initialRepeatedCodeLength var i uint var use_rle_for_non_zero bool = false var use_rle_for_zero bool = false var new_length uint = length /* Throw away trailing zeros. */ for i = 0; i < length; i++ { if depth[length-i-1] == 0 { new_length-- } else { break } } /* First gather statistics on if it is a good idea to do RLE. */ if length > 50 { /* Find RLE coding for longer codes. Shorter codes seem not to benefit from RLE. */ decideOverRLEUse(depth, new_length, &use_rle_for_non_zero, &use_rle_for_zero) } /* Actual RLE coding. */ for i = 0; i < new_length; { var value byte = depth[i] var reps uint = 1 if (value != 0 && use_rle_for_non_zero) || (value == 0 && use_rle_for_zero) { var k uint for k = i + 1; k < new_length && depth[k] == value; k++ { reps++ } } if value == 0 { writeHuffmanTreeRepetitionsZeros(reps, tree_size, tree, extra_bits_data) } else { writeHuffmanTreeRepetitions(previous_value, value, reps, tree_size, tree, extra_bits_data) previous_value = value } i += reps } } var reverseBits_kLut = [16]uint{ 0x00, 0x08, 0x04, 0x0C, 0x02, 0x0A, 0x06, 0x0E, 0x01, 0x09, 0x05, 0x0D, 0x03, 0x0B, 0x07, 0x0F, } func reverseBits(num_bits uint, bits uint16) uint16 { var retval uint = reverseBits_kLut[bits&0x0F] var i uint for i = 4; i < num_bits; i += 4 { retval <<= 4 bits = uint16(bits >> 4) retval |= reverseBits_kLut[bits&0x0F] } retval >>= ((0 - num_bits) & 0x03) return uint16(retval) } /* 0..15 are values for bits */ const maxHuffmanBits = 16 func convertBitDepthsToSymbols(depth []byte, len uint, bits []uint16) { var bl_count = [maxHuffmanBits]uint16{0} var next_code [maxHuffmanBits]uint16 var i uint /* In Brotli, all bit depths are [1..15] 0 bit depth means that the symbol does not exist. */ var code int = 0 for i = 0; i < len; i++ { bl_count[depth[i]]++ } bl_count[0] = 0 next_code[0] = 0 for i = 1; i < maxHuffmanBits; i++ { code = (code + int(bl_count[i-1])) << 1 next_code[i] = uint16(code) } for i = 0; i < len; i++ { if depth[i] != 0 { bits[i] = reverseBits(uint(depth[i]), next_code[depth[i]]) next_code[depth[i]]++ } } }