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ugfx/tools/mcufontencoder/src/encode_rlefont.cc

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#include "encode_rlefont.hh"
#include <algorithm>
#include <stdexcept>
#include "ccfixes.hh"
// Number of reserved codes before the dictionary entries.
#define DICT_START 24
// Special reference to mean "fill with zeros to the end of the glyph"
#define REF_FILLZEROS 16
// RLE codes
#define RLE_CODEMASK 0xC0
#define RLE_VALMASK 0x3F
#define RLE_ZEROS 0x00 // 0 to 63 zeros
#define RLE_64ZEROS 0x40 // (1 to 64) * 64 zeros
#define RLE_ONES 0x80 // 1 to 64 full alphas
#define RLE_SHADE 0xC0 // 1 to 4 partial alphas
// Dictionary "fill entries" for encoding bits directly.
#define DICT_START7BIT 4
#define DICT_START6BIT 132
#define DICT_START5BIT 196
#define DICT_START4BIT 228
#define DICT_START3BIT 244
#define DICT_START2BIT 252
namespace mcufont {
namespace rlefont {
// Get bit count for the "fill entries"
static size_t fillentry_bitcount(size_t index)
{
if (index >= DICT_START2BIT)
return 2;
else if (index >= DICT_START3BIT)
return 3;
else if (index >= DICT_START4BIT)
return 4;
else if (index >= DICT_START5BIT)
return 5;
else if (index >= DICT_START6BIT)
return 6;
else
return 7;
}
// Count the number of equal pixels at the beginning of the pixelstring.
static size_t prefix_length(const DataFile::pixels_t &pixels, size_t pos)
{
uint8_t pixel = pixels.at(pos);
size_t count = 1;
while (pos + count < pixels.size() &&
pixels.at(pos + count) == pixel)
{
count++;
}
return count;
}
// Perform the RLE encoding for a dictionary entry.
static encoded_font_t::rlestring_t encode_rle(const DataFile::pixels_t &pixels)
{
encoded_font_t::rlestring_t result;
size_t pos = 0;
while (pos < pixels.size())
{
uint8_t pixel = pixels.at(pos);
size_t count = prefix_length(pixels, pos);
pos += count;
if (pixel == 0)
{
// Up to 63 zeros can be encoded with RLE_ZEROS. If there are more,
// encode using RLE_64ZEROS, and then whatever remains with RLE_ZEROS.
while (count >= 64)
{
size_t c = (count > 4096) ? 64 : (count / 64);
result.push_back(RLE_64ZEROS | (c - 1));
count -= c * 64;
}
if (count)
{
result.push_back(RLE_ZEROS | count);
}
}
else if (pixel == 15)
{
// Encode ones.
while (count)
{
size_t c = (count > 64) ? 64 : count;
result.push_back(RLE_ONES | (c - 1));
count -= c;
}
}
else
{
// Encode shades.
while (count)
{
size_t c = (count > 4) ? 4 : count;
result.push_back(RLE_SHADE | ((c - 1) << 4) | pixel);
count -= c;
}
}
}
return result;
}
// We use a tree structure to represent the dictionary entries.
// Using this tree, we can perform a combined Aho-Corasick string matching
// and breadth-first search to find the optimal encoding of glyph data.
class DictTreeNode
{
public:
constexpr DictTreeNode():
m_index(-1),
m_ref(false),
m_length(0),
m_child0(nullptr),
m_child15(nullptr),
m_suffix(nullptr)
{}
void SetChild(uint8_t p, DictTreeNode *child)
{
if (p == 0)
m_child0 = child;
else if (p == 15)
m_child15 = child;
else if (p > 15)
throw std::logic_error("invalid pixel alpha: " + std::to_string(p));
else
{
if (!m_children)
{
m_children.reset(new DictTreeNode*[14]());
}
m_children[p - 1] = child;
}
}
DictTreeNode* GetChild(uint8_t p) const
{
if (p == 0)
return m_child0;
else if (p == 15)
return m_child15;
else if (p > 15)
throw std::logic_error("invalid pixel alpha: " + std::to_string(p));
else if (!m_children)
return nullptr;
else
return m_children[p - 1];
}
bool HasIntermediateChildren() const { return m_children != nullptr; }
int GetIndex() const { return m_index; }
void SetIndex(int index) { m_index = index; }
bool GetRef() const { return m_ref; }
void SetRef(bool ref) { m_ref = ref; }
size_t GetLength() const { return m_length; }
void SetLength(size_t length) { m_length = length; }
DictTreeNode *GetSuffix() const { return m_suffix; }
void SetSuffix(DictTreeNode *suffix) { m_suffix = suffix; }
private:
// Index of dictionary entry or -1 if just a intermediate node.
int m_index;
// True for ref-encoded dictionary entries. Used to avoid recursion when
// encoding them.
bool m_ref;
// Length of the corresponding dictionary entry replacement.
// Equals the distance from the tree root.
size_t m_length;
// Most tree nodes will only ever contains children for 0 or 15.
// Therefore the array for other nodes is allocated only on demand.
DictTreeNode *m_child0;
DictTreeNode *m_child15;
std::unique_ptr<DictTreeNode*[]> m_children;
// Pointer to the longest suffix of this entry that exists in the
// dictionary.
DictTreeNode *m_suffix;
};
// Preallocated array for tree nodes
class TreeAllocator
{
public:
TreeAllocator(size_t count)
{
m_storage.reset(new DictTreeNode[count]);
m_next = m_storage.get();
m_left = count;
}
DictTreeNode *allocate()
{
if (m_left == 0)
throw std::logic_error("Ran out of preallocated entries");
m_left--;
return m_next++;
}
private:
std::unique_ptr<DictTreeNode[]> m_storage;
DictTreeNode *m_next;
size_t m_left;
};
// Add a new dictionary entry to the tree. Adds the intermediate nodes, but
// does not yet fill the suffix pointers.
static DictTreeNode* add_tree_entry(const DataFile::pixels_t &entry, int index,
bool ref_encoded, DictTreeNode *root,
TreeAllocator &storage)
{
DictTreeNode* node = root;
for (uint8_t p : entry)
{
DictTreeNode* branch = node->GetChild(p);
if (!branch)
{
branch = storage.allocate();
node->SetChild(p, branch);
}
node = branch;
}
// Replace the entry if it either does not yet have an encoding, or if
// the new entry is non-ref (i.e. can be used in more situations).
if (node->GetIndex() < 0 || (node->GetRef() && !ref_encoded))
{
node->SetIndex(index);
node->SetRef(ref_encoded);
node->SetLength(entry.size());
}
return node;
}
// Walk the tree and find if the entry exists in the tree. If it does,
// returns a pointer to it, otherwise nullptr.
static DictTreeNode *find_tree_node(DataFile::pixels_t::const_iterator begin,
DataFile::pixels_t::const_iterator end,
DictTreeNode *root)
{
DictTreeNode* node = root;
while (begin != end)
{
uint8_t pixel = *begin++;
node = node->GetChild(pixel);
if (!node)
return nullptr;
}
return node;
}
// Fill in the suffix pointers recursively for the given subtree.
static void fill_tree_suffixes(DictTreeNode *root, DictTreeNode *subtree,
const DataFile::pixels_t &entry)
{
for (size_t i = 1; i < entry.size(); i++)
{
DictTreeNode *node = find_tree_node(entry.begin() + i, entry.end(), root);
if (node)
{
subtree->SetSuffix(node);
break;
}
}
if (!subtree->GetSuffix())
subtree->SetSuffix(root);
DataFile::pixels_t newentry(entry);
newentry.resize(entry.size() + 1);
for (uint8_t i = 0; i < 16; i++)
{
// Speed-up for the common case of 0 and 15 alphas.
if (i == 1 && !subtree->HasIntermediateChildren())
i += 14;
DictTreeNode *child = subtree->GetChild(i);
if (child)
{
newentry.at(entry.size()) = i;
fill_tree_suffixes(root, child, newentry);
}
}
}
// Construct a lookup tree from the dictionary entries.
static DictTreeNode* construct_tree(const std::vector<DataFile::dictentry_t> &dictionary,
TreeAllocator &storage, bool fast)
{
DictTreeNode* root = storage.allocate();
// Populate the hardcoded entries for 0 to 15 alpha.
for (int j = 0; j < 16; j++)
{
DictTreeNode *node = storage.allocate();
node->SetIndex(j);
node->SetRef(false);
node->SetLength(1);
root->SetChild(j, node);
}
// Populate the actual dictionary entries
size_t i = DICT_START;
for (DataFile::dictentry_t d : dictionary)
{
if (!d.replacement.size())
break;
add_tree_entry(d.replacement, i, d.ref_encode, root, storage);
i++;
}
if (!fast)
{
// Populate the fill entries for rest of dictionary
for (; i < 256; i++)
{
DataFile::pixels_t pixels;
size_t bitcount = fillentry_bitcount(i);
uint8_t byte = i - DICT_START7BIT;
for (size_t j = 0; j < bitcount; j++)
{
uint8_t p = (byte & (1 << j)) ? 15 : 0;
pixels.push_back(p);
}
add_tree_entry(pixels, i, false, root, storage);
}
// Fill in the suffix pointers for optimal encoding
DataFile::pixels_t nullentry;
fill_tree_suffixes(root, root, nullentry);
}
return root;
}
// Structure for keeping track of the shortest encoding to reach particular
// point of the pixel string.
struct encoding_link_t
{
// Index of the position prior to the last dictionary entry.
size_t previous;
// Index of the dictionary entry that brings us to this point.
int index;
// Number of links to get here from the start of the string.
size_t length;
constexpr encoding_link_t(): previous(0), index(-1), length(9999999) {}
};
// Perform the reference encoding for a glyph entry (optimal version).
// Uses a modified Aho-Corasick algorithm combined with breadth first search
// to find the shortest representation.
static encoded_font_t::refstring_t encode_ref_slow(const DataFile::pixels_t &pixels,
const DictTreeNode *root,
bool is_glyph)
{
// Chain of encodings. Each entry in this array corresponds to a position
// in the pixel string.
std::unique_ptr<encoding_link_t[]> chain(new encoding_link_t[pixels.size() + 1]);
chain[0].previous = 0;
chain[0].index = 0;
chain[0].length = 0;
// Read the pixels one-by-one and update the encoding links accordingly.
const DictTreeNode *node = root;
for (size_t pos = 0; pos < pixels.size(); pos++)
{
uint8_t pixel = pixels.at(pos);
const DictTreeNode *branch = node->GetChild(pixel);
while (!branch)
{
// Cannot expand this sequence, defer to suffix.
node = node->GetSuffix();
branch = node->GetChild(pixel);
}
node = branch;
// We have arrived at a new node, add it and any proper suffixes to
// the link chain.
const DictTreeNode *suffix = node;
while (suffix != root)
{
if (suffix->GetIndex() >= 0 && (is_glyph || !suffix->GetRef()))
{
encoding_link_t link;
link.previous = pos + 1 - suffix->GetLength();
link.index = suffix->GetIndex();
link.length = chain[link.previous].length + 1;
if (link.length < chain[pos + 1].length)
chain[pos + 1] = link;
}
suffix = suffix->GetSuffix();
}
}
// Check if we can shorten the final encoding using REF_FILLZEROS.
if (is_glyph)
{
for (size_t pos = pixels.size() - 1; pos > 0; pos--)
{
if (pixels.at(pos) != 0)
break;
encoding_link_t link;
link.previous = pos;
link.index = REF_FILLZEROS;
link.length = chain[pos].length + 1;
if (link.length <= chain[pixels.size()].length)
chain[pixels.size()] = link;
}
}
// Backtrack from the final link back to the start and construct the
// encoded string.
encoded_font_t::refstring_t result;
size_t len = chain[pixels.size()].length;
result.resize(len);
size_t pos = pixels.size();
for (size_t i = len; i > 0; i--)
{
result.at(i - 1) = chain[pos].index;
pos = chain[pos].previous;
}
return result;
}
// Walk the tree as far as possible following the given pixel string iterator.
// Returns number of pixels encoded, and index is set to the dictionary reference.
static size_t walk_tree(const DictTreeNode *tree,
DataFile::pixels_t::const_iterator pixels,
DataFile::pixels_t::const_iterator pixelsend,
int &index, bool is_glyph)
{
size_t best_length = 0;
size_t length = 0;
index = -1;
const DictTreeNode* node = tree;
while (pixels != pixelsend)
{
uint8_t pixel = *pixels++;
node = node->GetChild(pixel);
if (!node)
break;
length++;
if (is_glyph || !node->GetRef())
{
if (node->GetIndex() >= 0)
{
index = node->GetIndex();
best_length = length;
}
}
}
if (index < 0)
throw std::logic_error("walk_tree failed to find a valid encoding");
return best_length;
}
// Perform the reference encoding for a glyph entry (fast version).
// Uses a simple greedy search to find select the encodings.
static encoded_font_t::refstring_t encode_ref_fast(const DataFile::pixels_t &pixels,
const DictTreeNode *tree,
bool is_glyph)
{
encoded_font_t::refstring_t result;
// Strip any zeroes from end
size_t end = pixels.size();
if (is_glyph)
{
while (end > 0 && pixels.at(end - 1) == 0) end--;
}
size_t i = 0;
while (i < end)
{
int index;
i += walk_tree(tree, pixels.begin() + i, pixels.end(), index, is_glyph);
result.push_back(index);
}
if (i < pixels.size())
result.push_back(REF_FILLZEROS);
return result;
}
static encoded_font_t::refstring_t encode_ref(const DataFile::pixels_t &pixels,
const DictTreeNode *tree,
bool is_glyph, bool fast)
{
if (fast)
return encode_ref_fast(pixels, tree, is_glyph);
else
return encode_ref_slow(pixels, tree, is_glyph);
}
// Compare dictionary entries by their coding type.
// Sorts RLE-encoded entries first and any empty entries last.
static bool cmp_dict_coding(const DataFile::dictentry_t &a,
const DataFile::dictentry_t &b)
{
if (a.replacement.size() == 0 && b.replacement.size() != 0)
return false;
else if (a.replacement.size() != 0 && b.replacement.size() == 0)
return true;
else if (a.ref_encode == false && b.ref_encode == true)
return true;
else
return false;
}
size_t estimate_tree_node_count(const std::vector<DataFile::dictentry_t> &dict)
{
size_t count = DICT_START; // Preallocated entries
for (const DataFile::dictentry_t &d: dict)
{
count += d.replacement.size();
}
count += 128 * 7; // Fill entries
return count;
}
std::unique_ptr<encoded_font_t> encode_font(const DataFile &datafile,
bool fast)
{
std::unique_ptr<encoded_font_t> result(new encoded_font_t);
// Sort the dictionary so that RLE-coded entries come first.
// This way the two are easy to distinguish based on index.
std::vector<DataFile::dictentry_t> sorted_dict = datafile.GetDictionary();
std::stable_sort(sorted_dict.begin(), sorted_dict.end(), cmp_dict_coding);
// Build the binary tree for looking up references.
size_t count = estimate_tree_node_count(sorted_dict);
TreeAllocator allocator(count);
DictTreeNode* tree = construct_tree(sorted_dict, allocator, fast);
// Encode the dictionary entries, using either RLE or reference method.
for (const DataFile::dictentry_t &d : sorted_dict)
{
if (d.replacement.size() == 0)
{
continue;
}
else if (d.ref_encode)
{
result->ref_dictionary.push_back(encode_ref(d.replacement, tree, false, fast));
}
else
{
result->rle_dictionary.push_back(encode_rle(d.replacement));
}
}
// Then reference-encode the glyphs
for (const DataFile::glyphentry_t &g : datafile.GetGlyphTable())
{
result->glyphs.push_back(encode_ref(g.data, tree, true, fast));
}
// Optionally verify that the encoding was correct.
if (!fast)
{
for (size_t i = 0; i < datafile.GetGlyphCount(); i++)
{
std::unique_ptr<DataFile::pixels_t> decoded =
decode_glyph(*result, i, datafile.GetFontInfo());
if (*decoded != datafile.GetGlyphEntry(i).data)
{
auto iter = std::mismatch(decoded->begin(), decoded->end(),
datafile.GetGlyphEntry(i).data.begin());
size_t pos = iter.first - decoded->begin();
throw std::logic_error("verification of glyph " + std::to_string(i) +
" failed at position " + std::to_string(pos));
}
}
}
return result;
}
size_t get_encoded_size(const encoded_font_t &encoded)
{
size_t total = 0;
for (const encoded_font_t::rlestring_t &r : encoded.rle_dictionary)
{
total += r.size();
if (r.size() != 0)
total += 2; // Offset table entry
}
for (const encoded_font_t::refstring_t &r : encoded.ref_dictionary)
{
total += r.size();
if (r.size() != 0)
total += 2; // Offset table entry
}
for (const encoded_font_t::refstring_t &r : encoded.glyphs)
{
total += r.size();
total += 2; // Offset table entry
total += 1; // Width table entry
}
return total;
}
std::unique_ptr<DataFile::pixels_t> decode_glyph(
const encoded_font_t &encoded,
const encoded_font_t::refstring_t &refstring,
const DataFile::fontinfo_t &fontinfo)
{
std::unique_ptr<DataFile::pixels_t> result(new DataFile::pixels_t);
for (uint8_t ref : refstring)
{
if (ref <= 15)
{
result->push_back(ref);
}
else if (ref == REF_FILLZEROS)
{
result->resize(fontinfo.max_width * fontinfo.max_height, 0);
}
else if (ref < DICT_START)
{
throw std::logic_error("unknown code: " + std::to_string(ref));
}
else if (ref - DICT_START < (int)encoded.rle_dictionary.size())
{
for (uint8_t rle : encoded.rle_dictionary.at(ref - DICT_START))
{
if ((rle & RLE_CODEMASK) == RLE_ZEROS)
{
for (int i = 0; i < (rle & RLE_VALMASK); i++)
{
result->push_back(0);
}
}
else if ((rle & RLE_CODEMASK) == RLE_64ZEROS)
{
for (int i = 0; i < ((rle & RLE_VALMASK) + 1) * 64; i++)
{
result->push_back(0);
}
}
else if ((rle & RLE_CODEMASK) == RLE_ONES)
{
for (int i = 0; i < (rle & RLE_VALMASK) + 1; i++)
{
result->push_back(15);
}
}
else if ((rle & RLE_CODEMASK) == RLE_SHADE)
{
uint8_t count, alpha;
count = ((rle & RLE_VALMASK) >> 4) + 1;
alpha = ((rle & RLE_VALMASK) & 0xF);
for (int i = 0; i < count; i++)
{
result->push_back(alpha);
}
}
}
}
else if (ref - DICT_START - encoded.rle_dictionary.size() < encoded.ref_dictionary.size())
{
size_t index = ref - DICT_START - encoded.rle_dictionary.size();
std::unique_ptr<DataFile::pixels_t> part =
decode_glyph(encoded, encoded.ref_dictionary.at(index),
fontinfo);
result->insert(result->end(), part->begin(), part->end());
}
else
{
size_t bitcount = fillentry_bitcount(ref);
uint8_t byte = ref - DICT_START7BIT;
for (size_t i = 0; i < bitcount; i++)
{
uint8_t p = (byte & (1 << i)) ? 15 : 0;
result->push_back(p);
}
}
}
return result;
}
std::unique_ptr<DataFile::pixels_t> decode_glyph(
const encoded_font_t &encoded, size_t index,
const DataFile::fontinfo_t &fontinfo)
{
return decode_glyph(encoded, encoded.glyphs.at(index), fontinfo);
}
}}
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