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@ -1,3 +1,10 @@
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/**
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* consteval_huffman.hpp - Provides compile-time text compression.
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* Written by Clyne Sullivan.
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* https://github.com/tcsullivan/consteval-huffman
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*/
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#ifndef TCSULLIVAN_CONSTEVAL_HUFFMAN_HPP_
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#define TCSULLIVAN_CONSTEVAL_HUFFMAN_HPP_
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@ -5,106 +12,130 @@
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#include <span>
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/**
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* Compresses given data at compile-time, while also providing utilities for decoding.
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* @tparam data Expected to be a null-terminated `char` of data to be compressed.
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* Compresses the given character string using Huffman coding, providing a
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* minimal run-time interface for decompressing the data.
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* @tparam data The string of data to be compressed.
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* @tparam data_length The size in bytes of the data, defaults to using strlen().
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*/
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template<const char *data>
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template<const char *data, std::size_t data_length = std::char_traits<char>::length(data)>
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class huffman_compress
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{
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using size_t = unsigned long int;
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// The internals for this class needed to be defined before they're used in
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// the public interface. Scroll to the next `public` section for usable variables/functions.
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// Jump to the bottom of this header for the public-facing features of this
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// class.
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// The internals needed to be defined before they were used.
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private:
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// Node structure used for tree-building.
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// Node structure used to build a tree for calculating Huffman codes.
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struct node {
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int value = 0;
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size_t freq = 0;
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// Below values are indices into the node list
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int parent = -1;
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int left = -1;
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int right = -1;
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};
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// Builds a list of nodes for every character that appears in the data.
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// This list is sorted by increasing frequency.
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/**
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* Builds a list of nodes for every character that appears in the given data.
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* This list is sorted by increasing frequency.
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* @return Compile-time allocated array of nodes
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*/
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consteval static auto build_node_list() {
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auto table = std::span(new node[256] {}, 256);
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for (int i = 0; i < 256; i++)
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table[i].value = i;
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for (size_t i = 0; data[i]; i++)
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for (size_t i = 0; i < data_length; i++)
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table[data[i]].freq++;
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std::sort(table.begin(), table.end(), [](auto& a, auto& b) { return a.freq < b.freq; });
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int empty_count;
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for (empty_count = 0; table[empty_count].freq == 0; empty_count++);
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auto iter = std::copy(table.begin() + empty_count, table.end(), table.begin());
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auto first_valid_node = std::find_if(table.begin(), table.end(),
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[](const auto& n) { return n.freq != 0; });
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auto iter = std::copy(first_valid_node, table.end(), table.begin());
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std::fill(iter, table.end(), node());
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return table;
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}
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// Returns the count of how many nodes in build_node_list() are valid nodes.
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/**
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* Counts how many nodes in build_node_list() are valid.
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* @return Number of valid nodes, i.e. the "size" of the list.
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*/
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consteval static auto node_count() {
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auto table = build_node_list();
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size_t i;
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for (i = 0; table[i].value != 0; i++);
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for (i = 0; table[i].freq != 0; i++);
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delete[] table.data();
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return i;
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}
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// Builds a tree out of the node list, allowing for compression and decompression.
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// Returns the count of how many nodes are in the node tree.
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public:
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consteval static auto tree_count() {
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return node_count() * 2 - 1;
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}
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/**
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* Builds a tree out of the node list, allowing for the calculation of
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* Huffman codes.
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* @return Compile-time allocated tree of nodes, root node at index zero.
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*/
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consteval static auto build_node_tree() {
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auto table = build_node_list();
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auto list = build_node_list();
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auto tree = std::span(new node[tree_count()] {}, tree_count());
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auto end = node_count();
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size_t endend = 255;
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unsigned char endv = 0xFE;
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while (table[1].freq != 0) {
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node n { endv--,
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table[0].freq + table[1].freq,
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auto list_end = node_count();
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auto tree_begin = tree.end();
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int next_merged_node_value = 0x100;
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while (list[1].freq != 0) {
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// Create the merged parent node
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node new_node {
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next_merged_node_value++,
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list[0].freq + list[1].freq,
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-1,
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table[0].value,
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table[1].value };
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table[endend--] = table[0];
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table[endend--] = table[1];
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size_t insert;
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for (insert = 0;
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table[insert].freq != 0 && table[insert].freq < n.freq;
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insert++);
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std::copy_backward(table.begin() + insert,
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table.begin() + end,
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table.begin() + end + 1);
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table[insert] = n;
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std::copy(table.begin() + 2, table.begin() + end + 1, table.begin());
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table[end - 1] = node();
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table[end--] = node();
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}
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std::copy(table.begin() + endend + 1, table.end(), table.begin() + 1);
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for (size_t i = 1; i < 256 - endend; i++) {
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if (table[i].parent == -1) {
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for (size_t j = 0; j < i; j++) {
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if (table[j].left == table[i].value || table[j].right == table[i].value) {
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table[i].parent = j;
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break;
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}
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list[0].value,
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list[1].value
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};
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*--tree_begin = list[0];
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*--tree_begin = list[1];
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auto insertion_point = list.begin();
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while (insertion_point->freq != 0 && insertion_point->freq < new_node.freq)
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insertion_point++;
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std::copy_backward(insertion_point, list.begin() + list_end, list.begin() + list_end + 1);
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*insertion_point = new_node;
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std::copy(list.begin() + 2, list.begin() + list_end + 1, list.begin());
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list[list_end - 1] = node();
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list[list_end--] = node();
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}
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// Connect child nodes to their parents
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tree[0] = list[0];
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for (auto iter = tree.begin(); ++iter != tree.end();) {
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if (iter->parent == -1) {
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auto parent = std::find_if(tree.begin(), iter,
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[&iter](const auto& n) { return n.left == iter->value || n.right == iter->value; });
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if (parent != iter)
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iter->parent = std::distance(tree.begin(), parent);
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}
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}
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return table;
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}
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// Returns the count of how many nodes are in the node tree.
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consteval static auto tree_count() {
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auto table = build_node_tree();
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size_t i;
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for (i = 0; i < 256 && table[i].value != 0; i++);
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delete[] table.data();
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return i;
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delete[] list.data();
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return tree;
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}
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// Determines the size of the compressed data.
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// Returns a pair: [total byte size, bits used in last byte].
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/**
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* Determines the size of the compressed data.
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* Returns a pair: [total byte size, bits used in last byte].
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*/
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consteval static auto output_size() {
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auto tree = build_node_tree();
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size_t bytes = 1, bits = 0;
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for (size_t i = 0; i < std::char_traits<char>::length(data); i++) {
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for (size_t i = 0; i < data_length; i++) {
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auto leaf = std::find_if(tree.begin(), tree.end(),
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[c = data[i]](auto& n) { return n.value == c; });
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while (leaf->parent != -1) {
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@ -121,14 +152,14 @@ private:
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consteval void compress()
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{
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auto tree = build_node_tree();
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size_t bytes = size();
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size_t bytes = output_size().first;
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int bits;
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if (auto bitscount = output_size().second; bitscount > 0)
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bits = 8 - bitscount;
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else
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bits = 0, bytes--;
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for (size_t i = std::char_traits<char>::length(data); i > 0; i--) {
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auto leaf = std::find_if(tree.begin(), tree.begin() + tree_count(),
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for (size_t i = data_length; i > 0; i--) {
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auto leaf = std::find_if(tree.begin(), tree.end(),
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[c = data[i - 1]](auto& n) { return n.value == c; });
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while (leaf->parent != -1) {
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auto parent = tree.begin() + leaf->parent;
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@ -146,48 +177,39 @@ private:
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auto tree = build_node_tree();
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for (size_t i = 0; i < tree_count(); i++) {
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decode_tree[i * 3] = tree[i].value;
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decode_tree[i * 3] = tree[i].value <= 0xFF ? tree[i].value : 0;
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size_t j;
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for (j = i + 1; j < tree_count(); j++) {
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if (tree[i].left == tree[j].value)
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break;
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}
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decode_tree[i * 3 + 1] = j < tree_count() ? j : 0;
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decode_tree[i * 3 + 1] = j < tree_count() ? j - i : 0;
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for (j = i + 1; j < tree_count(); j++) {
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if (tree[i].right == tree[j].value)
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break;
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}
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decode_tree[i * 3 + 2] = j < tree_count() ? j : 0;
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decode_tree[i * 3 + 2] = j < tree_count() ? j - i : 0;
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}
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delete[] tree.data();
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}
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public:
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// Returns the size of the compressed data, in bytes.
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consteval static auto size() { return output_size().first; }
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// Returns how many of the bits in the last byte of `output` are actually part of the data.
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consteval static auto lastbitscount() { return output_size().second; }
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// Contains the compressed data.
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unsigned char output[size()] = {};
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unsigned char output[output_size().first] = {};
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// Contains a 'tree' that can be used to decompress the data.
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unsigned char decode_tree[3 * tree_count()] = {};
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consteval huffman_compress() {
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build_decode_tree();
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compress();
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}
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public:
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unsigned char decode_tree[3 * tree_count()] = {};
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// Utility for decoding compressed data.
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class decode_info {
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public:
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decode_info(const huffman_compress<data>& data_) :
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m_data(data_) { get_next(); }
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decode_info(const huffman_compress<data, data_length>& comp_data) :
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m_data(comp_data) { get_next(); }
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// Checks if another byte is available
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operator bool() const {
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return m_pos < (m_data.size() - 1) || m_bit > (8 - m_data.lastbitscount());
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const auto [size_bytes, last_bits_count] = m_data.output_size();
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return m_pos < (size_bytes - 1) || m_bit > (8 - last_bits_count);
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}
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// Gets the current byte
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int operator*() const { return m_current; }
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@ -200,12 +222,12 @@ public:
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private:
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// Internal: moves to next byte
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void get_next() {
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auto node = m_data.decode_tree;
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auto *node = m_data.decode_tree;
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do {
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bool bit = m_data.output[m_pos] & (1 << (m_bit - 1));
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if (--m_bit == 0)
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m_bit = 8, m_pos++;
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node = m_data.decode_tree + 3 * node[bit ? 2 : 1];
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node += 3 * node[bit ? 2 : 1];
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} while (node[1] != 0);
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m_current = *node;
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}
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@ -214,8 +236,25 @@ public:
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size_t m_pos = 0;
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unsigned char m_bit = 8;
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int m_current = -1;
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friend class huffman_compress;
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};
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consteval huffman_compress() {
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build_decode_tree();
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compress();
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}
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consteval static auto compressed_size() {
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return output_size().first + output_size().second;
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}
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consteval static auto uncompressed_size() {
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return data_length;
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}
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consteval static auto bytes_saved() {
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return uncompressed_size() - compressed_size();
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}
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// Creates a decoder object for iteratively decompressing the data.
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auto get_decoder() const {
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return decode_info(*this);
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@ -223,3 +262,4 @@ public:
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};
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#endif // TCSULLIVAN_CONSTEVAL_HUFFMAN_HPP_
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