/*
* Copyright (c) 2021-2022, Matthew Olsson <mattco@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Utf8View.h>
#include <LibPDF/CommonNames.h>
#include <LibPDF/Fonts/PDFFont.h>
#include <LibPDF/Interpolation.h>
#include <LibPDF/Renderer.h>
#define RENDERER_HANDLER(name) \
PDFErrorOr<void> Renderer::handle_##name([[maybe_unused]] Vector<Value> const& args, [[maybe_unused]] Optional<NonnullRefPtr<DictObject>> extra_resources)
#define RENDERER_TODO(name) \
RENDERER_HANDLER(name) \
{ \
return Error(Error::Type::RenderingUnsupported, "draw operation: " #name); \
}
namespace PDF {
PDFErrorsOr<void> Renderer::render(Document& document, Page const& page, RefPtr<Gfx::Bitmap> bitmap, RenderingPreferences rendering_preferences)
{
return Renderer(document, page, bitmap, rendering_preferences).render();
}
static void rect_path(Gfx::Path& path, float x, float y, float width, float height)
{
path.move_to({ x, y });
path.line_to({ x + width, y });
path.line_to({ x + width, y + height });
path.line_to({ x, y + height });
path.close();
}
template<typename T>
static void rect_path(Gfx::Path& path, Gfx::Rect<T> rect)
{
return rect_path(path, rect.x(), rect.y(), rect.width(), rect.height());
}
template<typename T>
static Gfx::Path rect_path(Gfx::Rect<T> const& rect)
{
Gfx::Path path;
rect_path(path, rect);
return path;
}
Renderer::Renderer(RefPtr<Document> document, Page const& page, RefPtr<Gfx::Bitmap> bitmap, RenderingPreferences rendering_preferences)
: m_document(document)
, m_bitmap(bitmap)
, m_page(page)
, m_painter(*bitmap)
, m_anti_aliasing_painter(m_painter)
, m_rendering_preferences(rendering_preferences)
{
auto media_box = m_page.media_box;
Gfx::AffineTransform userspace_matrix;
userspace_matrix.translate(media_box.lower_left_x, media_box.lower_left_y);
float width = media_box.width();
float height = media_box.height();
float scale_x = static_cast<float>(bitmap->width()) / width;
float scale_y = static_cast<float>(bitmap->height()) / height;
userspace_matrix.scale(scale_x, scale_y);
// PDF user-space coordinate y axis increases from bottom to top, so we have to
// insert a horizontal reflection about the vertical midpoint into our transformation
// matrix
static Gfx::AffineTransform horizontal_reflection_matrix = { 1, 0, 0, -1, 0, 0 };
userspace_matrix.multiply(horizontal_reflection_matrix);
userspace_matrix.translate(0.0f, -height);
auto initial_clipping_path = rect_path(userspace_matrix.map(Gfx::FloatRect(0, 0, width, height)));
m_graphics_state_stack.append(GraphicsState { userspace_matrix, { initial_clipping_path, initial_clipping_path } });
m_bitmap->fill(Gfx::Color::NamedColor::White);
}
PDFErrorsOr<void> Renderer::render()
{
auto operators = TRY(Parser::parse_operators(m_document, TRY(m_page.page_contents(*m_document))));
Errors errors;
for (auto& op : operators) {
auto maybe_error = handle_operator(op);
if (maybe_error.is_error()) {
errors.add_error(maybe_error.release_error());
}
}
if (!errors.errors().is_empty())
return errors;
return {};
}
PDFErrorOr<void> Renderer::handle_operator(Operator const& op, Optional<NonnullRefPtr<DictObject>> extra_resources)
{
switch (op.type()) {
#define V(name, snake_name, symbol) \
case OperatorType::name: \
TRY(handle_##snake_name(op.arguments(), extra_resources)); \
break;
ENUMERATE_OPERATORS(V)
#undef V
case OperatorType::TextNextLineShowString:
TRY(handle_text_next_line_show_string(op.arguments()));
break;
case OperatorType::TextNextLineShowStringSetSpacing:
TRY(handle_text_next_line_show_string_set_spacing(op.arguments()));
break;
}
return {};
}
RENDERER_HANDLER(save_state)
{
m_graphics_state_stack.append(state());
return {};
}
RENDERER_HANDLER(restore_state)
{
m_graphics_state_stack.take_last();
return {};
}
RENDERER_HANDLER(concatenate_matrix)
{
Gfx::AffineTransform new_transform(
args[0].to_float(),
args[1].to_float(),
args[2].to_float(),
args[3].to_float(),
args[4].to_float(),
args[5].to_float());
state().ctm.multiply(new_transform);
m_text_rendering_matrix_is_dirty = true;
return {};
}
RENDERER_HANDLER(set_line_width)
{
state().line_width = args[0].to_float();
return {};
}
RENDERER_HANDLER(set_line_cap)
{
state().line_cap_style = static_cast<LineCapStyle>(args[0].get<int>());
return {};
}
RENDERER_HANDLER(set_line_join)
{
state().line_join_style = static_cast<LineJoinStyle>(args[0].get<int>());
return {};
}
RENDERER_HANDLER(set_miter_limit)
{
state().miter_limit = args[0].to_float();
return {};
}
RENDERER_HANDLER(set_dash_pattern)
{
auto dash_array = MUST(m_document->resolve_to<ArrayObject>(args[0]));
Vector<int> pattern;
for (auto& element : *dash_array)
pattern.append(element.to_int());
state().line_dash_pattern = LineDashPattern { pattern, args[1].to_int() };
return {};
}
RENDERER_TODO(set_color_rendering_intent)
RENDERER_HANDLER(set_flatness_tolerance)
{
state().flatness_tolerance = args[0].to_float();
return {};
}
RENDERER_HANDLER(set_graphics_state_from_dict)
{
auto resources = extra_resources.value_or(m_page.resources);
auto dict_name = MUST(m_document->resolve_to<NameObject>(args[0]))->name();
auto ext_gstate_dict = MUST(resources->get_dict(m_document, CommonNames::ExtGState));
auto target_dict = MUST(ext_gstate_dict->get_dict(m_document, dict_name));
TRY(set_graphics_state_from_dict(target_dict));
return {};
}
RENDERER_HANDLER(path_move)
{
m_current_path.move_to(map(args[0].to_float(), args[1].to_float()));
return {};
}
RENDERER_HANDLER(path_line)
{
VERIFY(!m_current_path.segments().is_empty());
m_current_path.line_to(map(args[0].to_float(), args[1].to_float()));
return {};
}
RENDERER_HANDLER(path_cubic_bezier_curve)
{
VERIFY(args.size() == 6);
m_current_path.cubic_bezier_curve_to(
map(args[0].to_float(), args[1].to_float()),
map(args[2].to_float(), args[3].to_float()),
map(args[4].to_float(), args[5].to_float()));
return {};
}
RENDERER_HANDLER(path_cubic_bezier_curve_no_first_control)
{
VERIFY(args.size() == 4);
VERIFY(!m_current_path.segments().is_empty());
auto current_point = (*m_current_path.segments().rbegin())->point();
m_current_path.cubic_bezier_curve_to(
current_point,
map(args[0].to_float(), args[1].to_float()),
map(args[2].to_float(), args[3].to_float()));
return {};
}
RENDERER_HANDLER(path_cubic_bezier_curve_no_second_control)
{
VERIFY(args.size() == 4);
VERIFY(!m_current_path.segments().is_empty());
auto first_control_point = map(args[0].to_float(), args[1].to_float());
auto second_control_point = map(args[2].to_float(), args[3].to_float());
m_current_path.cubic_bezier_curve_to(
first_control_point,
second_control_point,
second_control_point);
return {};
}
RENDERER_HANDLER(path_close)
{
m_current_path.close();
return {};
}
RENDERER_HANDLER(path_append_rect)
{
auto rect = Gfx::FloatRect(args[0].to_float(), args[1].to_float(), args[2].to_float(), args[3].to_float());
rect_path(m_current_path, map(rect));
return {};
}
///
// Path painting operations
///
void Renderer::begin_path_paint()
{
auto bounding_box = state().clipping_paths.current.bounding_box();
m_painter.clear_clip_rect();
if (m_rendering_preferences.show_clipping_paths) {
m_painter.stroke_path(rect_path(bounding_box), Color::Black, 1);
}
m_painter.add_clip_rect(bounding_box.to_type<int>());
}
void Renderer::end_path_paint()
{
m_current_path.clear();
m_painter.clear_clip_rect();
state().clipping_paths.current = state().clipping_paths.next;
}
RENDERER_HANDLER(path_stroke)
{
begin_path_paint();
m_anti_aliasing_painter.stroke_path(m_current_path, state().stroke_color, state().ctm.x_scale() * state().line_width);
end_path_paint();
return {};
}
RENDERER_HANDLER(path_close_and_stroke)
{
m_current_path.close();
TRY(handle_path_stroke(args));
return {};
}
RENDERER_HANDLER(path_fill_nonzero)
{
begin_path_paint();
m_current_path.close_all_subpaths();
m_anti_aliasing_painter.fill_path(m_current_path, state().paint_color, Gfx::Painter::WindingRule::Nonzero);
end_path_paint();
return {};
}
RENDERER_HANDLER(path_fill_nonzero_deprecated)
{
return handle_path_fill_nonzero(args);
}
RENDERER_HANDLER(path_fill_evenodd)
{
begin_path_paint();
m_current_path.close_all_subpaths();
m_anti_aliasing_painter.fill_path(m_current_path, state().paint_color, Gfx::Painter::WindingRule::EvenOdd);
end_path_paint();
return {};
}
RENDERER_HANDLER(path_fill_stroke_nonzero)
{
m_anti_aliasing_painter.stroke_path(m_current_path, state().stroke_color, state().ctm.x_scale() * state().line_width);
return handle_path_fill_nonzero(args);
}
RENDERER_HANDLER(path_fill_stroke_evenodd)
{
m_anti_aliasing_painter.stroke_path(m_current_path, state().stroke_color, state().ctm.x_scale() * state().line_width);
return handle_path_fill_evenodd(args);
}
RENDERER_HANDLER(path_close_fill_stroke_nonzero)
{
m_current_path.close();
return handle_path_fill_stroke_nonzero(args);
}
RENDERER_HANDLER(path_close_fill_stroke_evenodd)
{
m_current_path.close();
return handle_path_fill_stroke_evenodd(args);
}
RENDERER_HANDLER(path_end)
{
begin_path_paint();
end_path_paint();
return {};
}
RENDERER_HANDLER(path_intersect_clip_nonzero)
{
// FIXME: Support arbitrary path clipping in Path and utilize that here
auto next_clipping_bbox = state().clipping_paths.next.bounding_box();
next_clipping_bbox.intersect(m_current_path.bounding_box());
state().clipping_paths.next = rect_path(next_clipping_bbox);
return {};
}
RENDERER_HANDLER(path_intersect_clip_evenodd)
{
// FIXME: Should have different behavior than path_intersect_clip_nonzero
return handle_path_intersect_clip_nonzero(args);
}
RENDERER_HANDLER(text_begin)
{
m_text_matrix = Gfx::AffineTransform();
m_text_line_matrix = Gfx::AffineTransform();
return {};
}
RENDERER_HANDLER(text_end)
{
// FIXME: Do we need to do anything here?
return {};
}
RENDERER_HANDLER(text_set_char_space)
{
text_state().character_spacing = args[0].to_float();
return {};
}
RENDERER_HANDLER(text_set_word_space)
{
text_state().word_spacing = args[0].to_float();
return {};
}
RENDERER_HANDLER(text_set_horizontal_scale)
{
m_text_rendering_matrix_is_dirty = true;
text_state().horizontal_scaling = args[0].to_float() / 100.0f;
return {};
}
RENDERER_HANDLER(text_set_leading)
{
text_state().leading = args[0].to_float();
return {};
}
PDFErrorOr<NonnullRefPtr<PDFFont>> Renderer::get_font(FontCacheKey const& key, Optional<NonnullRefPtr<DictObject>> extra_resources)
{
auto it = m_font_cache.find(key);
if (it != m_font_cache.end())
return it->value;
auto resources = extra_resources.value_or(m_page.resources);
auto fonts_dictionary = MUST(resources->get_dict(m_document, CommonNames::Font));
auto font_dictionary = MUST(fonts_dictionary->get_dict(m_document, key.font_dictionary_key));
auto font = TRY(PDFFont::create(m_document, font_dictionary, key.font_size));
m_font_cache.set(key, font);
return font;
}
RENDERER_HANDLER(text_set_font)
{
auto target_font_name = MUST(m_document->resolve_to<NameObject>(args[0]))->name();
text_state().font_size = args[1].to_float();
auto& text_rendering_matrix = calculate_text_rendering_matrix();
auto font_size = text_rendering_matrix.x_scale() * text_state().font_size;
FontCacheKey cache_key { target_font_name, font_size };
text_state().font = TRY(get_font(cache_key, extra_resources));
m_text_rendering_matrix_is_dirty = true;
return {};
}
RENDERER_HANDLER(text_set_rendering_mode)
{
text_state().rendering_mode = static_cast<TextRenderingMode>(args[0].get<int>());
return {};
}
RENDERER_HANDLER(text_set_rise)
{
m_text_rendering_matrix_is_dirty = true;
text_state().rise = args[0].to_float();
return {};
}
RENDERER_HANDLER(text_next_line_offset)
{
Gfx::AffineTransform transform(1.0f, 0.0f, 0.0f, 1.0f, args[0].to_float(), args[1].to_float());
m_text_line_matrix.multiply(transform);
m_text_matrix = m_text_line_matrix;
return {};
}
RENDERER_HANDLER(text_next_line_and_set_leading)
{
text_state().leading = -args[1].to_float();
TRY(handle_text_next_line_offset(args));
return {};
}
RENDERER_HANDLER(text_set_matrix_and_line_matrix)
{
Gfx::AffineTransform new_transform(
args[0].to_float(),
args[1].to_float(),
args[2].to_float(),
args[3].to_float(),
args[4].to_float(),
args[5].to_float());
m_text_line_matrix = new_transform;
m_text_matrix = new_transform;
m_text_rendering_matrix_is_dirty = true;
// Settings the text/line matrix retroactively affects fonts
if (text_state().font) {
auto new_text_rendering_matrix = calculate_text_rendering_matrix();
text_state().font->set_font_size(text_state().font_size * new_text_rendering_matrix.x_scale());
}
return {};
}
RENDERER_HANDLER(text_next_line)
{
TRY(handle_text_next_line_offset({ 0.0f, -text_state().leading }));
return {};
}
RENDERER_HANDLER(text_show_string)
{
auto text = MUST(m_document->resolve_to<StringObject>(args[0]))->string();
TRY(show_text(text));
return {};
}
RENDERER_HANDLER(text_next_line_show_string)
{
TRY(handle_text_next_line(args));
TRY(handle_text_show_string(args));
return {};
}
RENDERER_TODO(text_next_line_show_string_set_spacing)
RENDERER_HANDLER(text_show_string_array)
{
auto elements = MUST(m_document->resolve_to<ArrayObject>(args[0]))->elements();
float next_shift = 0.0f;
for (auto& element : elements) {
if (element.has<int>()) {
next_shift = element.get<int>();
} else if (element.has<float>()) {
next_shift = element.get<float>();
} else {
auto shift = next_shift / 1000.0f;
m_text_matrix.translate(-shift * text_state().font_size * text_state().horizontal_scaling, 0.0f);
auto str = element.get<NonnullRefPtr<Object>>()->cast<StringObject>()->string();
TRY(show_text(str));
}
}
return {};
}
RENDERER_TODO(type3_font_set_glyph_width)
RENDERER_TODO(type3_font_set_glyph_width_and_bbox)
RENDERER_HANDLER(set_stroking_space)
{
state().stroke_color_space = TRY(get_color_space_from_resources(args[0], extra_resources.value_or(m_page.resources)));
VERIFY(state().stroke_color_space);
return {};
}
RENDERER_HANDLER(set_painting_space)
{
state().paint_color_space = TRY(get_color_space_from_resources(args[0], extra_resources.value_or(m_page.resources)));
VERIFY(state().paint_color_space);
return {};
}
RENDERER_HANDLER(set_stroking_color)
{
state().stroke_color = TRY(state().stroke_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_stroking_color_extended)
{
// FIXME: Handle Pattern color spaces
auto last_arg = args.last();
if (last_arg.has<NonnullRefPtr<Object>>() && last_arg.get<NonnullRefPtr<Object>>()->is<NameObject>())
TODO();
state().stroke_color = TRY(state().stroke_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_painting_color)
{
state().paint_color = TRY(state().paint_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_painting_color_extended)
{
// FIXME: Handle Pattern color spaces
auto last_arg = args.last();
if (last_arg.has<NonnullRefPtr<Object>>() && last_arg.get<NonnullRefPtr<Object>>()->is<NameObject>()) {
dbgln("pattern space {}", last_arg.get<NonnullRefPtr<Object>>()->cast<NameObject>()->name());
return Error::rendering_unsupported_error("Pattern color spaces not yet implemented");
}
state().paint_color = TRY(state().paint_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_stroking_color_and_space_to_gray)
{
state().stroke_color_space = DeviceGrayColorSpace::the();
state().stroke_color = TRY(state().stroke_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_painting_color_and_space_to_gray)
{
state().paint_color_space = DeviceGrayColorSpace::the();
state().paint_color = TRY(state().paint_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_stroking_color_and_space_to_rgb)
{
state().stroke_color_space = DeviceRGBColorSpace::the();
state().stroke_color = TRY(state().stroke_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_painting_color_and_space_to_rgb)
{
state().paint_color_space = DeviceRGBColorSpace::the();
state().paint_color = TRY(state().paint_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_stroking_color_and_space_to_cmyk)
{
state().stroke_color_space = DeviceCMYKColorSpace::the();
state().stroke_color = TRY(state().stroke_color_space->color(args));
return {};
}
RENDERER_HANDLER(set_painting_color_and_space_to_cmyk)
{
state().paint_color_space = DeviceCMYKColorSpace::the();
state().paint_color = TRY(state().paint_color_space->color(args));
return {};
}
RENDERER_TODO(shade)
RENDERER_TODO(inline_image_begin)
RENDERER_TODO(inline_image_begin_data)
RENDERER_TODO(inline_image_end)
RENDERER_HANDLER(paint_xobject)
{
VERIFY(args.size() > 0);
auto resources = extra_resources.value_or(m_page.resources);
auto xobject_name = args[0].get<NonnullRefPtr<Object>>()->cast<NameObject>()->name();
auto xobjects_dict = TRY(resources->get_dict(m_document, CommonNames::XObject));
auto xobject = TRY(xobjects_dict->get_stream(m_document, xobject_name));
Optional<NonnullRefPtr<DictObject>> xobject_resources {};
if (xobject->dict()->contains(CommonNames::Resources)) {
xobject_resources = xobject->dict()->get_dict(m_document, CommonNames::Resources).value();
}
auto subtype = MUST(xobject->dict()->get_name(m_document, CommonNames::Subtype))->name();
if (subtype == CommonNames::Image) {
TRY(show_image(xobject));
return {};
}
// Use a RAII object to restore the graphics state, to make sure it gets restored even if
// a TRY(handle_operator()) causes us to exit the operators loop early.
class ScopedState {
public:
ScopedState(Renderer& renderer)
: m_renderer(renderer)
{
MUST(m_renderer.handle_save_state({}));
}
~ScopedState()
{
MUST(m_renderer.handle_restore_state({}));
}
private:
Renderer& m_renderer;
};
ScopedState scoped_state { *this };
Vector<Value> matrix;
if (xobject->dict()->contains(CommonNames::Matrix)) {
matrix = xobject->dict()->get_array(m_document, CommonNames::Matrix).value()->elements();
} else {
matrix = Vector { Value { 1 }, Value { 0 }, Value { 0 }, Value { 1 }, Value { 0 }, Value { 0 } };
}
MUST(handle_concatenate_matrix(matrix));
auto operators = TRY(Parser::parse_operators(m_document, xobject->bytes()));
for (auto& op : operators)
TRY(handle_operator(op, xobject_resources));
return {};
}
RENDERER_HANDLER(marked_content_point)
{
// nop
return {};
}
RENDERER_HANDLER(marked_content_designate)
{
// nop
return {};
}
RENDERER_HANDLER(marked_content_begin)
{
// nop
return {};
}
RENDERER_HANDLER(marked_content_begin_with_property_list)
{
// nop
return {};
}
RENDERER_HANDLER(marked_content_end)
{
// nop
return {};
}
RENDERER_TODO(compatibility_begin)
RENDERER_TODO(compatibility_end)
template<typename T>
Gfx::Point<T> Renderer::map(T x, T y) const
{
return state().ctm.map(Gfx::Point<T> { x, y });
}
template<typename T>
Gfx::Size<T> Renderer::map(Gfx::Size<T> size) const
{
return state().ctm.map(size);
}
template<typename T>
Gfx::Rect<T> Renderer::map(Gfx::Rect<T> rect) const
{
return state().ctm.map(rect);
}
PDFErrorOr<void> Renderer::set_graphics_state_from_dict(NonnullRefPtr<DictObject> dict)
{
// ISO 32000 (PDF 2.0), 8.4.5 Graphics state parameter dictionaries
if (dict->contains(CommonNames::LW))
TRY(handle_set_line_width({ dict->get_value(CommonNames::LW) }));
if (dict->contains(CommonNames::LC))
TRY(handle_set_line_cap({ dict->get_value(CommonNames::LC) }));
if (dict->contains(CommonNames::LJ))
TRY(handle_set_line_join({ dict->get_value(CommonNames::LJ) }));
if (dict->contains(CommonNames::ML))
TRY(handle_set_miter_limit({ dict->get_value(CommonNames::ML) }));
if (dict->contains(CommonNames::D)) {
auto array = MUST(dict->get_array(m_document, CommonNames::D));
TRY(handle_set_dash_pattern(array->elements()));
}
// FIXME: RI
// FIXME: OP
// FIXME: op
// FIXME: OPM
// FIXME: Font
// FIXME: BG
// FIXME: BG2
// FIXME: UCR
// FIXME: UCR2
// FIXME: TR
// FIXME: TR2
// FIXME: HT
if (dict->contains(CommonNames::FL))
TRY(handle_set_flatness_tolerance({ dict->get_value(CommonNames::FL) }));
// FIXME: SM
// FIXME: SA
// FIXME: BM
// FIXME: SMask
// FIXME: CA
// FIXME: ca
// FIXME: AIS
// FIXME: TK
// FIXME: UseBlackPtComp
// FIXME: HTO
return {};
}
PDFErrorOr<void> Renderer::show_text(DeprecatedString const& string)
{
if (!text_state().font)
return Error::rendering_unsupported_error("Can't draw text because an invalid font was in use");
auto& text_rendering_matrix = calculate_text_rendering_matrix();
auto font_size = text_rendering_matrix.x_scale() * text_state().font_size;
auto start_position = text_rendering_matrix.map(Gfx::FloatPoint { 0.0f, 0.0f });
auto end_position = TRY(text_state().font->draw_string(m_painter, start_position, string, state().paint_color, font_size, text_state().character_spacing * text_rendering_matrix.x_scale(), text_state().word_spacing * text_rendering_matrix.x_scale(), text_state().horizontal_scaling));
// Update text matrix
auto delta_x = end_position.x() - start_position.x();
m_text_rendering_matrix_is_dirty = true;
m_text_matrix.translate(delta_x / text_rendering_matrix.x_scale(), 0.0f);
return {};
}
PDFErrorOr<NonnullRefPtr<Gfx::Bitmap>> Renderer::load_image(NonnullRefPtr<StreamObject> image)
{
auto image_dict = image->dict();
auto width = image_dict->get_value(CommonNames::Width).get<int>();
auto height = image_dict->get_value(CommonNames::Height).get<int>();
auto is_filter = [&](DeprecatedFlyString const& name) -> PDFErrorOr<bool> {
if (!image_dict->contains(CommonNames::Filter))
return false;
auto filter_object = TRY(image_dict->get_object(m_document, CommonNames::Filter));
if (filter_object->is<NameObject>())
return filter_object->cast<NameObject>()->name() == name;
auto filters = filter_object->cast<ArrayObject>();
return MUST(filters->get_name_at(m_document, 0))->name() == name;
};
if (TRY(is_filter(CommonNames::JPXDecode))) {
return Error(Error::Type::RenderingUnsupported, "JPXDecode filter");
}
if (image_dict->contains(CommonNames::ImageMask)) {
auto is_mask = image_dict->get_value(CommonNames::ImageMask).get<bool>();
if (is_mask) {
return Error(Error::Type::RenderingUnsupported, "Image masks");
}
}
auto color_space_object = MUST(image_dict->get_object(m_document, CommonNames::ColorSpace));
auto color_space = TRY(get_color_space_from_document(color_space_object));
auto bits_per_component = image_dict->get_value(CommonNames::BitsPerComponent).get<int>();
if (bits_per_component != 8) {
return Error(Error::Type::RenderingUnsupported, "Image's bit per component != 8");
}
Vector<float> decode_array;
if (image_dict->contains(CommonNames::Decode)) {
decode_array = MUST(image_dict->get_array(m_document, CommonNames::Decode))->float_elements();
} else {
decode_array = color_space->default_decode();
}
Vector<LinearInterpolation1D> component_value_decoders;
component_value_decoders.ensure_capacity(decode_array.size());
for (size_t i = 0; i < decode_array.size(); i += 2) {
auto dmin = decode_array[i];
auto dmax = decode_array[i + 1];
component_value_decoders.empend(0.0f, 255.0f, dmin, dmax);
}
if (TRY(is_filter(CommonNames::DCTDecode))) {
// TODO: stream objects could store Variant<bytes/Bitmap> to avoid seialisation/deserialisation here
return TRY(Gfx::Bitmap::create_from_serialized_bytes(image->bytes()));
}
auto bitmap = MUST(Gfx::Bitmap::create(Gfx::BitmapFormat::BGRA8888, { width, height }));
int x = 0;
int y = 0;
int const n_components = color_space->number_of_components();
auto const bytes_per_component = bits_per_component / 8;
Vector<Value> component_values;
component_values.resize(n_components);
auto content = image->bytes();
while (!content.is_empty() && y < height) {
auto sample = content.slice(0, bytes_per_component * n_components);
content = content.slice(bytes_per_component * n_components);
for (int i = 0; i < n_components; ++i) {
auto component = sample.slice(0, bytes_per_component);
sample = sample.slice(bytes_per_component);
component_values[i] = Value { component_value_decoders[i].interpolate(component[0]) };
}
auto color = TRY(color_space->color(component_values));
bitmap->set_pixel(x, y, color);
++x;
if (x == width) {
x = 0;
++y;
}
}
return bitmap;
}
Gfx::AffineTransform Renderer::calculate_image_space_transformation(int width, int height)
{
// Image space maps to a 1x1 unit of user space and starts at the top-left
auto image_space = state().ctm;
image_space.multiply(Gfx::AffineTransform(
1.0f / width,
0.0f,
0.0f,
-1.0f / height,
0.0f,
1.0f));
return image_space;
}
void Renderer::show_empty_image(int width, int height)
{
auto image_space_transofmation = calculate_image_space_transformation(width, height);
auto image_border = image_space_transofmation.map(Gfx::IntRect { 0, 0, width, height });
m_painter.stroke_path(rect_path(image_border), Color::Black, 1);
}
PDFErrorOr<void> Renderer::show_image(NonnullRefPtr<StreamObject> image)
{
auto image_dict = image->dict();
auto width = image_dict->get_value(CommonNames::Width).get<int>();
auto height = image_dict->get_value(CommonNames::Height).get<int>();
if (!m_rendering_preferences.show_images) {
show_empty_image(width, height);
return {};
}
auto image_bitmap = TRY(load_image(image));
if (image_dict->contains(CommonNames::SMask)) {
auto smask_bitmap = TRY(load_image(TRY(image_dict->get_stream(m_document, CommonNames::SMask))));
// Make softmask same size as image.
// FIXME: The smask code here is fairly ad-hoc and incomplete.
if (smask_bitmap->size() != image_bitmap->size())
smask_bitmap = TRY(smask_bitmap->scaled_to_size(image_bitmap->size()));
for (int j = 0; j < image_bitmap->height(); ++j) {
for (int i = 0; i < image_bitmap->width(); ++i) {
auto image_color = image_bitmap->get_pixel(i, j);
auto smask_color = smask_bitmap->get_pixel(i, j);
image_color = image_color.with_alpha(smask_color.luminosity());
image_bitmap->set_pixel(i, j, image_color);
}
}
}
auto image_space = calculate_image_space_transformation(width, height);
auto image_rect = Gfx::FloatRect { 0, 0, width, height };
m_painter.draw_scaled_bitmap_with_transform(image_bitmap->rect(), image_bitmap, image_rect, image_space);
return {};
}
PDFErrorOr<NonnullRefPtr<ColorSpace>> Renderer::get_color_space_from_resources(Value const& value, NonnullRefPtr<DictObject> resources)
{
auto color_space_name = value.get<NonnullRefPtr<Object>>()->cast<NameObject>()->name();
auto maybe_color_space_family = ColorSpaceFamily::get(color_space_name);
if (!maybe_color_space_family.is_error()) {
auto color_space_family = maybe_color_space_family.release_value();
if (color_space_family.never_needs_parameters()) {
return ColorSpace::create(color_space_name);
}
}
auto color_space_resource_dict = TRY(resources->get_dict(m_document, CommonNames::ColorSpace));
if (!color_space_resource_dict->contains(color_space_name)) {
dbgln("missing key {}", color_space_name);
return Error::rendering_unsupported_error("Missing entry for color space name");
}
auto color_space_array = TRY(color_space_resource_dict->get_array(m_document, color_space_name));
return ColorSpace::create(m_document, color_space_array);
}
PDFErrorOr<NonnullRefPtr<ColorSpace>> Renderer::get_color_space_from_document(NonnullRefPtr<Object> color_space_object)
{
// Pattern cannot be a name in these cases
if (color_space_object->is<NameObject>()) {
return ColorSpace::create(color_space_object->cast<NameObject>()->name());
}
return ColorSpace::create(m_document, color_space_object->cast<ArrayObject>());
}
Gfx::AffineTransform const& Renderer::calculate_text_rendering_matrix()
{
if (m_text_rendering_matrix_is_dirty) {
m_text_rendering_matrix = Gfx::AffineTransform(
text_state().horizontal_scaling,
0.0f,
0.0f,
1.0f,
0.0f,
text_state().rise);
m_text_rendering_matrix.multiply(state().ctm);
m_text_rendering_matrix.multiply(m_text_matrix);
m_text_rendering_matrix_is_dirty = false;
}
return m_text_rendering_matrix;
}
}