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ladybird/Userland/Libraries/LibPDF/Renderer.cpp
Rodrigo Tobar 82bac7e665 LibPDF: Fix clipping of painting operations 
While the clipping logic was correct (current v/s new clipping path),
the clipping path contents weren't. This commit fixed that.

We calculate the clipping path in two places: when we set it to be the
whole page at graphics state creation time, and when we perform clipping
path intersection to calculate a new clipping path. The clipping path is
then used to limit painting by passing it to the painter (more
precisely, but passing its bounding box to the painter, as the latter
doesn't support arbitrary path clipping). For this last point the
clipping path must be in device coordinates.

There was however a mix of coordinate systems involved in the creation,
update and usage of the clipping path:

 * The initial values of the path (i.e., the whole page) were in user
   coordinates.
 * Clipping path intersection was performed against m_current_path,
   which is in device coordinates.
 * To perform the clipping operation, the current clipping path was
   assumed to be in user coordinates.

This mix resulted in the clipping not working correctly depending on the
zoom level at which one visualised a page.

This commit fixes the issue by always keeping track of the clipping path
in device coordinates. This means that the initial full-page contents
are now converted to device coordinates before putting them in the
graphics state, and that no mapping is performed when applied the
clipping to the painter.
2023-02-04 12:29:57 +01:00

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/*
* 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()
{
// Use our own vector, as the /Content can be an array with multiple
// streams which gets concatenated
// FIXME: Text operators are supposed to only have effects on the current
// stream object. Do the text operators treat this concatenated stream
// as one stream or multiple?
ByteBuffer byte_buffer;
if (m_page.contents->is<ArrayObject>()) {
auto contents = m_page.contents->cast<ArrayObject>();
for (auto& ref : *contents) {
auto bytes = TRY(m_document->resolve_to<StreamObject>(ref))->bytes();
byte_buffer.append(bytes.data(), bytes.size());
}
} else {
auto bytes = m_page.contents->cast<StreamObject>()->bytes();
byte_buffer.append(bytes.data(), bytes.size());
}
auto operators = TRY(Parser::parse_operators(m_document, byte_buffer));
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].get<int>() };
return {};
}
RENDERER_TODO(set_color_rendering_intent)
RENDERER_TODO(set_flatness_tolerance)
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().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_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_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().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().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 {};
}
RENDERER_HANDLER(text_set_font)
{
auto resources = extra_resources.value_or(m_page.resources);
auto target_font_name = MUST(m_document->resolve_to<NameObject>(args[0]))->name();
auto fonts_dictionary = MUST(resources->get_dict(m_document, CommonNames::Font));
auto font_dictionary = MUST(fonts_dictionary->get_dict(m_document, target_font_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;
auto font = TRY(PDFFont::create(m_document, font_dictionary, font_size));
text_state().font = font;
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;
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();
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();
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 = 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 = state().stroke_color_space->color(args);
return {};
}
RENDERER_HANDLER(set_painting_color)
{
state().paint_color = 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>())
TODO();
state().paint_color = 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 = 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 = 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 = 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 = 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 = 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 = 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 = MUST(resources->get_dict(m_document, CommonNames::XObject));
auto xobject = MUST(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 {};
}
MUST(handle_save_state({}));
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));
MUST(handle_restore_state({}));
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)
{
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()));
}
if (dict->contains(CommonNames::FL))
TRY(handle_set_flatness_tolerance({ dict->get_value(CommonNames::FL) }));
return {};
}
void Renderer::show_text(DeprecatedString const& string)
{
auto& text_rendering_matrix = calculate_text_rendering_matrix();
auto font_size = text_rendering_matrix.x_scale() * text_state().font_size;
auto glyph_position = text_rendering_matrix.map(Gfx::FloatPoint { 0.0f, 0.0f });
auto original_position = glyph_position;
for (auto char_code : string.bytes()) {
auto char_width = text_state().font->get_char_width(char_code);
auto glyph_width = char_width * font_size;
text_state().font->draw_glyph(m_painter, glyph_position, glyph_width, char_code, state().paint_color);
auto tx = glyph_width;
tx += text_state().character_spacing;
tx *= text_state().horizontal_scaling;
glyph_position += { tx, 0.0f };
}
// Update text matrix
auto delta_x = glyph_position.x() - original_position.x();
m_text_rendering_matrix_is_dirty = true;
m_text_matrix.translate(delta_x / text_rendering_matrix.x_scale(), 0.0f);
}
PDFErrorOr<NonnullRefPtr<Gfx::Bitmap>> Renderer::load_image(NonnullRefPtr<StreamObject> image)
{
auto image_dict = image->dict();
auto filter_object = TRY(image_dict->get_object(m_document, CommonNames::Filter));
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) {
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 (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 (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 = 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))));
VERIFY(smask_bitmap->rect() == image_bitmap->rect());
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));
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;
}
}
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