py::array_t<uint8_t, py::array::c_style> im, FT_Bitmap *bitmap, FT_Int x, FT_Int y)

{

auto buf = im.mutable_data(0);

FT_Int image_width = (FT_Int)im.shape(1);

FT_Int image_height = (FT_Int)im.shape(0);

FT_Int char_width = bitmap->width;

FT_Int char_height = bitmap->rows;

FT_Int x1 = std::min(std::max(x, 0), image_width);

FT_Int y1 = std::min(std::max(y, 0), image_height);

FT_Int x2 = std::min(std::max(x + char_width, 0), image_width);

FT_Int y2 = std::min(std::max(y + char_height, 0), image_height);

FT_Int x_start = std::max(0, -x);

FT_Int y_offset = y1 - std::max(0, -y);

if (bitmap->pixel_mode == FT_PIXEL_MODE_GRAY) {

for (FT_Int i = y1; i < y2; ++i) {

unsigned char *dst = buf + (i * image_width + x1);

unsigned char *src = bitmap->buffer + (((i - y_offset) * bitmap->pitch) + x_start);

for (FT_Int j = x1; j < x2; ++j, ++dst, ++src)

*dst |= *src;

}

} else if (bitmap->pixel_mode == FT_PIXEL_MODE_MONO) {

for (FT_Int i = y1; i < y2; ++i) {

unsigned char *dst = buf + (i * image_width + x1);

unsigned char *src = bitmap->buffer + ((i - y_offset) * bitmap->pitch);

for (FT_Int j = x1; j < x2; ++j, ++dst) {

int x = (j - x1 + x_start);

int val = *(src + (x >> 3)) & (1 << (7 - (x & 0x7)));

*dst = val ? 255 : *dst;

}

}

} else {

throw std::runtime_error("Unknown pixel mode");

}

{

x0 = std::min(x0, m_width);

y0 = std::min(y0, m_height);

x1 = std::min(x1 + 1, m_width);

y1 = std::min(y1 + 1, m_height);

for (size_t j = y0; j < y1; j++) {

for (size_t i = x0; i < x1; i++) {

m_buffer[i + j * m_width] = 255;

}

}

{

std::vector<double> &vertices;

std::vector<unsigned char> &codes;

{

ft_outline_decomposer* d = reinterpret_cast<ft_outline_decomposer*>(user);

if (!d->vertices.empty()) {

// Appending CLOSEPOLY is important to make patheffects work.

d->vertices.push_back(0);

d->vertices.push_back(0);

d->codes.push_back(CLOSEPOLY);

}

d->vertices.push_back(to->x * (1. / 64.));

d->vertices.push_back(to->y * (1. / 64.));

d->codes.push_back(MOVETO);

return 0;

{

ft_outline_decomposer* d = reinterpret_cast<ft_outline_decomposer*>(user);

d->vertices.push_back(to->x * (1. / 64.));

d->vertices.push_back(to->y * (1. / 64.));

d->codes.push_back(LINETO);

return 0;

{

ft_outline_decomposer* d = reinterpret_cast<ft_outline_decomposer*>(user);

d->vertices.push_back(control->x * (1. / 64.));

d->vertices.push_back(control->y * (1. / 64.));

d->vertices.push_back(to->x * (1. / 64.));

d->vertices.push_back(to->y * (1. / 64.));

d->codes.push_back(CURVE3);

d->codes.push_back(CURVE3);

return 0;

FT_Vector const* c1, FT_Vector const* c2, FT_Vector const* to, void* user)

{

ft_outline_decomposer* d = reinterpret_cast<ft_outline_decomposer*>(user);

d->vertices.push_back(c1->x * (1. / 64.));

d->vertices.push_back(c1->y * (1. / 64.));

d->vertices.push_back(c2->x * (1. / 64.));

d->vertices.push_back(c2->y * (1. / 64.));

d->vertices.push_back(to->x * (1. / 64.));

d->vertices.push_back(to->y * (1. / 64.));

d->codes.push_back(CURVE4);

d->codes.push_back(CURVE4);

d->codes.push_back(CURVE4);

return 0;

{

if (!face->glyph) {

throw std::runtime_error("No glyph loaded");

}

ft_outline_decomposer decomposer = {

vertices,

codes,

};

// We can make a close-enough estimate based on number of points and number of

// contours (which produce a MOVETO each), though it's slightly underestimating due

// to higher-order curves.

size_t estimated_points = static_cast<size_t>(face->glyph->outline.n_contours) +

static_cast<size_t>(face->glyph->outline.n_points);

vertices.reserve(2 * estimated_points);

codes.reserve(estimated_points);

if (FT_Error error = FT_Outline_Decompose(

&face->glyph->outline, &ft_outline_funcs, &decomposer)) {

throw std::runtime_error("FT_Outline_Decompose failed with error " +

std::to_string(error));

}

if (vertices.empty()) { // Don't append CLOSEPOLY to null glyphs.

return;

}

vertices.push_back(0);

vertices.push_back(0);

codes.push_back(CLOSEPOLY);

long hinting_factor_,

std::vector<FT2Font *> &fallback_list,

FT2Font::WarnFunc warn, bool warn_if_used)

: ft_glyph_warn(warn), warn_if_used(warn_if_used), image({1, 1}), face(nullptr),

hinting_factor(hinting_factor_),

// set default kerning factor to 0, i.e., no kerning manipulation

kerning_factor(0)

{

clear();

FT_CHECK(FT_Open_Face, _ft2Library, &open_args, 0, &face);

if (open_args.stream != nullptr) {

face->face_flags |= FT_FACE_FLAG_EXTERNAL_STREAM;

}

try {

set_size(12., 72.); // Set a default fontsize 12 pt at 72dpi.

} catch (...) {

FT_Done_Face(face);

throw;

}

// Set fallbacks

std::copy(fallback_list.begin(), fallback_list.end(), std::back_inserter(fallbacks));

{

pen.x = pen.y = 0;

bbox.xMin = bbox.yMin = bbox.xMax = bbox.yMax = 0;

advance = 0;

for (auto & glyph : glyphs) {

FT_Done_Glyph(glyph);

}

glyphs.clear();

glyph_to_font.clear();

char_to_font.clear();

for (auto & fallback : fallbacks) {

fallback->clear();

}

{

FT_CHECK(

FT_Set_Char_Size,

face, (FT_F26Dot6)(ptsize * 64), 0, (FT_UInt)(dpi * hinting_factor), (FT_UInt)dpi);

FT_Matrix transform = { 65536 / hinting_factor, 0, 0, 65536 };

FT_Set_Transform(face, &transform, nullptr);

for (auto & fallback : fallbacks) {

fallback->set_size(ptsize, dpi);

}

{

if (i >= face->num_charmaps) {

throw std::runtime_error("i exceeds the available number of char maps");

}

FT_CHECK(FT_Set_Charmap, face, face->charmaps[i]);

bool fallback = false)

{

if (fallback && glyph_to_font.find(left) != glyph_to_font.end() &&

glyph_to_font.find(right) != glyph_to_font.end()) {

FT2Font *left_ft_object = glyph_to_font[left];

FT2Font *right_ft_object = glyph_to_font[right];

if (left_ft_object != right_ft_object) {

// we do not know how to do kerning between different fonts

return 0;

}

// if left_ft_object is the same as right_ft_object,

// do the exact same thing which set_text does.

return right_ft_object->get_kerning(left, right, mode, false);

}

else

{

FT_Vector delta;

return get_kerning(left, right, mode, delta);

}

FT_Vector &delta)

{

if (!FT_HAS_KERNING(face)) {

return 0;

}

if (!FT_Get_Kerning(face, left, right, mode, &delta)) {

return (int)(delta.x) / (hinting_factor << kerning_factor);

} else {

return 0;

}

{

kerning_factor = factor;

for (auto & fallback : fallbacks) {

fallback->set_kerning_factor(factor);

}

std::u32string_view text, double angle, FT_Int32 flags, std::vector<double> &xys)

{

FT_Matrix matrix; /* transformation matrix */

angle = angle * (2 * M_PI / 360.0);

// this computes width and height in subpixels so we have to multiply by 64

double cosangle = cos(angle) * 0x10000L;

double sinangle = sin(angle) * 0x10000L;

matrix.xx = (FT_Fixed)cosangle;

matrix.xy = (FT_Fixed)-sinangle;

matrix.yx = (FT_Fixed)sinangle;

matrix.yy = (FT_Fixed)cosangle;

clear();

bbox.xMin = bbox.yMin = 32000;

bbox.xMax = bbox.yMax = -32000;

FT_UInt previous = 0;

FT2Font *previous_ft_object = nullptr;

for (auto codepoint : text) {

FT_UInt glyph_index = 0;

FT_BBox glyph_bbox;

FT_Pos last_advance;

FT_Error charcode_error, glyph_error;

std::set<FT_String*> glyph_seen_fonts;

FT2Font *ft_object_with_glyph = this;

bool was_found = load_char_with_fallback(ft_object_with_glyph, glyph_index, glyphs,

char_to_font, glyph_to_font, codepoint, flags,

charcode_error, glyph_error, glyph_seen_fonts, false);

if (!was_found) {

ft_glyph_warn((FT_ULong)codepoint, glyph_seen_fonts);

// render missing glyph tofu

// come back to top-most font

ft_object_with_glyph = this;

char_to_font[codepoint] = ft_object_with_glyph;

glyph_to_font[glyph_index] = ft_object_with_glyph;

ft_object_with_glyph->load_glyph(glyph_index, flags, ft_object_with_glyph, false);

} else if (ft_object_with_glyph->warn_if_used) {

ft_glyph_warn((FT_ULong)codepoint, glyph_seen_fonts);

}

// retrieve kerning distance and move pen position

if ((ft_object_with_glyph == previous_ft_object) && // if both fonts are the same

ft_object_with_glyph->has_kerning() && // if the font knows how to kern

previous && glyph_index // and we really have 2 glyphs

) {

FT_Vector delta;

pen.x += ft_object_with_glyph->get_kerning(previous, glyph_index, FT_KERNING_DEFAULT, delta);

}

// extract glyph image and store it in our table

FT_Glyph &thisGlyph = glyphs[glyphs.size() - 1];

last_advance = ft_object_with_glyph->get_face()->glyph->advance.x;

FT_Glyph_Transform(thisGlyph, nullptr, &pen);

FT_Glyph_Transform(thisGlyph, &matrix, nullptr);

xys.push_back(pen.x);

xys.push_back(pen.y);

FT_Glyph_Get_CBox(thisGlyph, FT_GLYPH_BBOX_SUBPIXELS, &glyph_bbox);

bbox.xMin = std::min(bbox.xMin, glyph_bbox.xMin);

bbox.xMax = std::max(bbox.xMax, glyph_bbox.xMax);

bbox.yMin = std::min(bbox.yMin, glyph_bbox.yMin);

bbox.yMax = std::max(bbox.yMax, glyph_bbox.yMax);

pen.x += last_advance;

previous = glyph_index;

previous_ft_object = ft_object_with_glyph;

}

FT_Vector_Transform(&pen, &matrix);

advance = pen.x;

if (bbox.xMin > bbox.xMax) {

bbox.xMin = bbox.yMin = bbox.xMax = bbox.yMax = 0;

}

{

// if this is parent FT2Font, cache will be filled in 2 ways:

// 1. set_text was previously called

// 2. set_text was not called and fallback was enabled

std::set <FT_String *> glyph_seen_fonts;

if (fallback && char_to_font.find(charcode) != char_to_font.end()) {

ft_object = char_to_font[charcode];

// since it will be assigned to ft_object anyway

FT2Font *throwaway = nullptr;

ft_object->load_char(charcode, flags, throwaway, false);

} else if (fallback) {

FT_UInt final_glyph_index;

FT_Error charcode_error, glyph_error;

FT2Font *ft_object_with_glyph = this;

bool was_found = load_char_with_fallback(ft_object_with_glyph, final_glyph_index,

glyphs, char_to_font, glyph_to_font,

charcode, flags, charcode_error, glyph_error,

glyph_seen_fonts, true);

if (!was_found) {

ft_glyph_warn(charcode, glyph_seen_fonts);

if (charcode_error) {

THROW_FT_ERROR("charcode loading", charcode_error);

}

else if (glyph_error) {

THROW_FT_ERROR("charcode loading", glyph_error);

}

} else if (ft_object_with_glyph->warn_if_used) {

ft_glyph_warn(charcode, glyph_seen_fonts);

}

ft_object = ft_object_with_glyph;

} else {

//no fallback case

ft_object = this;

FT_UInt glyph_index = FT_Get_Char_Index(face, (FT_ULong) charcode);

if (!glyph_index){

glyph_seen_fonts.insert((face != nullptr)?face->family_name: nullptr);

ft_glyph_warn((FT_ULong)charcode, glyph_seen_fonts);

}

FT_CHECK(FT_Load_Glyph, face, glyph_index, flags);

FT_Glyph thisGlyph;

FT_CHECK(FT_Get_Glyph, face->glyph, &thisGlyph);

glyphs.push_back(thisGlyph);

}

{

FT_UInt glyph_index = FT_Get_Char_Index(face, charcode);

if (glyph_index) {

// -1 means the host has the char and we do not need to fallback

index = -1;

return true;

} else {

int inner_index = 0;

bool was_found;

for (size_t i = 0; i < fallbacks.size(); ++i) {

// TODO handle recursion somehow!

was_found = fallbacks[i]->get_char_fallback_index(charcode, inner_index);

if (was_found) {

index = i;

return true;

}

}

}

return false;

FT_UInt &final_glyph_index,

std::vector<FT_Glyph> &parent_glyphs,

std::unordered_map<long, FT2Font *> &parent_char_to_font,

std::unordered_map<FT_UInt, FT2Font *> &parent_glyph_to_font,

long charcode,

FT_Int32 flags,

FT_Error &charcode_error,

FT_Error &glyph_error,

std::set<FT_String*> &glyph_seen_fonts,

bool override = false)

{

FT_UInt glyph_index = FT_Get_Char_Index(face, charcode);

if (!warn_if_used) {

glyph_seen_fonts.insert(face->family_name);

}

if (glyph_index || override) {

charcode_error = FT_Load_Glyph(face, glyph_index, flags);

if (charcode_error) {

return false;

}

FT_Glyph thisGlyph;

glyph_error = FT_Get_Glyph(face->glyph, &thisGlyph);

if (glyph_error) {

return false;

}

final_glyph_index = glyph_index;

// cache the result for future

// need to store this for anytime a character is loaded from a parent

// FT2Font object or to generate a mapping of individual characters to fonts

ft_object_with_glyph = this;

parent_glyph_to_font[final_glyph_index] = this;

parent_char_to_font[charcode] = this;

parent_glyphs.push_back(thisGlyph);

return true;

}

else {

for (auto & fallback : fallbacks) {

bool was_found = fallback->load_char_with_fallback(

ft_object_with_glyph, final_glyph_index, parent_glyphs,

parent_char_to_font, parent_glyph_to_font, charcode, flags,

charcode_error, glyph_error, glyph_seen_fonts, override);

if (was_found) {

return true;

}

}

return false;

}

FT_Int32 flags,

FT2Font *&ft_object,

bool fallback = false)

{

// cache is only for parent FT2Font

if (fallback && glyph_to_font.find(glyph_index) != glyph_to_font.end()) {

ft_object = glyph_to_font[glyph_index];

} else {

ft_object = this;

}

ft_object->load_glyph(glyph_index, flags);

{

FT_CHECK(FT_Load_Glyph, face, glyph_index, flags);

FT_Glyph thisGlyph;

FT_CHECK(FT_Get_Glyph, face->glyph, &thisGlyph);

glyphs.push_back(thisGlyph);

{

FT2Font *ft_object = nullptr;

if (fallback && char_to_font.find(charcode) != char_to_font.end()) {

// fallback denotes whether we want to search fallback list.

// should call set_text/load_char_with_fallback to parent FT2Font before

// wanting to use fallback list here. (since that populates the cache)

ft_object = char_to_font[charcode];

} else {

// set as self

ft_object = this;

}

return FT_Get_Char_Index(ft_object->get_face(), charcode);

{

*width = advance;

*height = bbox.yMax - bbox.yMin;

{

*x = bbox.xMin;

*y = 0;

{

long width = (bbox.xMax - bbox.xMin) / 64 + 2;

long height = (bbox.yMax - bbox.yMin) / 64 + 2;

image = py::array_t<uint8_t>{{height, width}};

std::memset(image.mutable_data(0), 0, image.nbytes());

for (auto & glyph: glyphs) {

FT_CHECK(

FT_Glyph_To_Bitmap,

&glyph, antialiased ? FT_RENDER_MODE_NORMAL : FT_RENDER_MODE_MONO, nullptr, 1);

FT_BitmapGlyph bitmap = (FT_BitmapGlyph)glyph;

// now, draw to our target surface (convert position)

// bitmap left and top in pixel, string bbox in subpixel

FT_Int x = (FT_Int)(bitmap->left - (bbox.xMin * (1. / 64.)));

FT_Int y = (FT_Int)((bbox.yMax * (1. / 64.)) - bitmap->top + 1);

draw_bitmap(image, &bitmap->bitmap, x, y);

}

py::array_t<uint8_t, py::array::c_style> im,

int x, int y, size_t glyphInd, bool antialiased)

{

FT_Vector sub_offset;

sub_offset.x = 0; // int((xd - (double)x) * 64.0);

sub_offset.y = 0; // int((yd - (double)y) * 64.0);

if (glyphInd >= glyphs.size()) {

throw std::runtime_error("glyph num is out of range");

}

FT_CHECK(

FT_Glyph_To_Bitmap,

&glyphs[glyphInd],

antialiased ? FT_RENDER_MODE_NORMAL : FT_RENDER_MODE_MONO,

&sub_offset, // additional translation

1); // destroy image

FT_BitmapGlyph bitmap = (FT_BitmapGlyph)glyphs[glyphInd];

draw_bitmap(im, &bitmap->bitmap, x + bitmap->left, y);

bool fallback = false)

{

if (fallback && glyph_to_font.find(glyph_number) != glyph_to_font.end()) {

// cache is only for parent FT2Font

FT2Font *ft_object = glyph_to_font[glyph_number];

ft_object->get_glyph_name(glyph_number, buffer, false);

return;

}

if (!FT_HAS_GLYPH_NAMES(face)) {

/* Note that this generated name must match the name that

auto len = snprintf(buffer.data(), buffer.size(), "uni%08x", glyph_number);

if (len >= 0) {

buffer.resize(len);

} else {

throw std::runtime_error("Failed to convert glyph to standard name");

}

} else {

FT_CHECK(FT_Get_Glyph_Name, face, glyph_number, buffer.data(), buffer.size());

auto len = buffer.find('\0');

if (len != buffer.npos) {

buffer.resize(len);

}

}