pdf/pdfium/pdfium_engine_exports.cc - chromium/src - Git at Google

 // Copyright 2018 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "pdf/pdfium/pdfium_engine_exports.h"

 #include <algorithm>
 #include <utility>

 #include "base/no_destructor.h"
 #include "base/numerics/safe_conversions.h"
 #include "pdf/pdfium/pdfium_mem_buffer_file_write.h"
 #include "pdf/pdfium/pdfium_print.h"
 #include "printing/nup_parameters.h"
 #include "printing/units.h"
 #include "third_party/pdfium/public/cpp/fpdf_scopers.h"
 #include "third_party/pdfium/public/fpdf_ppo.h"
 #include "third_party/pdfium/public/fpdfview.h"
 #include "ui/gfx/geometry/rect.h"
 #include "ui/gfx/geometry/size.h"

 using printing::ConvertUnitDouble;
 using printing::kPointsPerInch;

 namespace chrome_pdf {

 namespace {

 int CalculatePosition(FPDF_PAGE page,
                       const PDFiumEngineExports::RenderingSettings& settings,
                       pp::Rect* dest) {
   // settings.bounds is in terms of the max DPI. Convert page sizes to match.
   int dpi = std::max(settings.dpi_x, settings.dpi_y);
   int page_width = static_cast<int>(
       ConvertUnitDouble(FPDF_GetPageWidth(page), kPointsPerInch, dpi));
   int page_height = static_cast<int>(
       ConvertUnitDouble(FPDF_GetPageHeight(page), kPointsPerInch, dpi));

   // Start by assuming that we will draw exactly to the bounds rect
   // specified.
   *dest = settings.bounds;

   int rotate = 0;  // normal orientation.

   // Auto-rotate landscape pages to print correctly.
   if (settings.autorotate &&
       (dest->width() > dest->height()) != (page_width > page_height)) {
     rotate = 3;  // 90 degrees counter-clockwise.
     std::swap(page_width, page_height);
   }

   // See if we need to scale the output
   bool scale_to_bounds = false;
   if (settings.fit_to_bounds &&
       ((page_width > dest->width()) || (page_height > dest->height()))) {
     scale_to_bounds = true;
   } else if (settings.stretch_to_bounds &&
              ((page_width < dest->width()) || (page_height < dest->height()))) {
     scale_to_bounds = true;
   }

   if (scale_to_bounds) {
     // If we need to maintain aspect ratio, calculate the actual width and
     // height.
     if (settings.keep_aspect_ratio) {
       double scale_factor_x = page_width;
       scale_factor_x /= dest->width();
       double scale_factor_y = page_height;
       scale_factor_y /= dest->height();
       if (scale_factor_x > scale_factor_y) {
         dest->set_height(page_height / scale_factor_x);
       } else {
         dest->set_width(page_width / scale_factor_y);
       }
     }
   } else {
     // We are not scaling to bounds. Draw in the actual page size. If the
     // actual page size is larger than the bounds, the output will be
     // clipped.
     dest->set_width(page_width);
     dest->set_height(page_height);
   }

   // Scale the bounds to device units if DPI is rectangular.
   if (settings.dpi_x != settings.dpi_y) {
     dest->set_width(dest->width() * settings.dpi_x / dpi);
     dest->set_height(dest->height() * settings.dpi_y / dpi);
   }

   if (settings.center_in_bounds) {
     pp::Point offset(
         (settings.bounds.width() * settings.dpi_x / dpi - dest->width()) / 2,
         (settings.bounds.height() * settings.dpi_y / dpi - dest->height()) / 2);
     dest->Offset(offset);
   }
   return rotate;
 }

 ScopedFPDFDocument LoadPdfData(base::span<const uint8_t> pdf_buffer) {
   if (!base::IsValueInRangeForNumericType<int>(pdf_buffer.size()))
     return nullptr;
   return ScopedFPDFDocument(
       FPDF_LoadMemDocument(pdf_buffer.data(), pdf_buffer.size(), nullptr));
 }

 ScopedFPDFDocument CreatePdfDoc(
     std::vector<base::span<const uint8_t>> input_buffers) {
   if (input_buffers.empty())
     return nullptr;

   ScopedFPDFDocument doc(FPDF_CreateNewDocument());
   size_t index = 0;
   for (auto input_buffer : input_buffers) {
     ScopedFPDFDocument single_page_doc = LoadPdfData(input_buffer);
     if (!FPDF_ImportPages(doc.get(), single_page_doc.get(), "1", index++)) {
       return nullptr;
     }
   }

   return doc;
 }

 bool IsValidPrintableArea(const gfx::Size& page_size,
                           const gfx::Rect& printable_area) {
   return !printable_area.IsEmpty() && printable_area.x() >= 0 &&
          printable_area.y() >= 0 &&
          printable_area.right() <= page_size.width() &&
          printable_area.bottom() <= page_size.height();
 }

 }  // namespace

 PDFEngineExports::RenderingSettings::RenderingSettings(int dpi_x,
                                                        int dpi_y,
                                                        const pp::Rect& bounds,
                                                        bool fit_to_bounds,
                                                        bool stretch_to_bounds,
                                                        bool keep_aspect_ratio,
                                                        bool center_in_bounds,
                                                        bool autorotate,
                                                        bool use_color)
     : dpi_x(dpi_x),
       dpi_y(dpi_y),
       bounds(bounds),
       fit_to_bounds(fit_to_bounds),
       stretch_to_bounds(stretch_to_bounds),
       keep_aspect_ratio(keep_aspect_ratio),
       center_in_bounds(center_in_bounds),
       autorotate(autorotate),
       use_color(use_color) {}

 PDFEngineExports::RenderingSettings::RenderingSettings(
     const RenderingSettings& that) = default;

 PDFEngineExports* PDFEngineExports::Get() {
   static base::NoDestructor<PDFiumEngineExports> exports;
   return exports.get();
 }

 PDFiumEngineExports::PDFiumEngineExports() {}

 PDFiumEngineExports::~PDFiumEngineExports() {}

 #if defined(OS_WIN)
 bool PDFiumEngineExports::RenderPDFPageToDC(
     base::span<const uint8_t> pdf_buffer,
     int page_number,
     const RenderingSettings& settings,
     HDC dc) {
   ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
   if (!doc)
     return false;
   ScopedFPDFPage page(FPDF_LoadPage(doc.get(), page_number));
   if (!page)
     return false;

   RenderingSettings new_settings = settings;
   // calculate the page size
   if (new_settings.dpi_x == -1)
     new_settings.dpi_x = GetDeviceCaps(dc, LOGPIXELSX);
   if (new_settings.dpi_y == -1)
     new_settings.dpi_y = GetDeviceCaps(dc, LOGPIXELSY);

   pp::Rect dest;
   int rotate = CalculatePosition(page.get(), new_settings, &dest);

   int save_state = SaveDC(dc);
   // The caller wanted all drawing to happen within the bounds specified.
   // Based on scale calculations, our destination rect might be larger
   // than the bounds. Set the clip rect to the bounds.
   IntersectClipRect(dc, settings.bounds.x(), settings.bounds.y(),
                     settings.bounds.x() + settings.bounds.width(),
                     settings.bounds.y() + settings.bounds.height());

   int flags = FPDF_ANNOT | FPDF_PRINTING;
   if (!settings.use_color)
     flags |= FPDF_GRAYSCALE;

   // A "temporary" hack. Some PDFs seems to render very slowly if
   // FPDF_RenderPage() is directly used on a printer DC. I suspect it is
   // because of the code to talk Postscript directly to the printer if
   // the printer supports this. Need to discuss this with PDFium. For now,
   // render to a bitmap and then blit the bitmap to the DC if we have been
   // supplied a printer DC.
   int device_type = GetDeviceCaps(dc, TECHNOLOGY);
   if (device_type == DT_RASPRINTER || device_type == DT_PLOTTER) {
     ScopedFPDFBitmap bitmap(
         FPDFBitmap_Create(dest.width(), dest.height(), FPDFBitmap_BGRx));
     // Clear the bitmap
     FPDFBitmap_FillRect(bitmap.get(), 0, 0, dest.width(), dest.height(),
                         0xFFFFFFFF);
     FPDF_RenderPageBitmap(bitmap.get(), page.get(), 0, 0, dest.width(),
                           dest.height(), rotate, flags);
     int stride = FPDFBitmap_GetStride(bitmap.get());
     BITMAPINFO bmi;
     memset(&bmi, 0, sizeof(bmi));
     bmi.bmiHeader.biSize = sizeof(BITMAPINFOHEADER);
     bmi.bmiHeader.biWidth = dest.width();
     bmi.bmiHeader.biHeight = -dest.height();  // top-down image
     bmi.bmiHeader.biPlanes = 1;
     bmi.bmiHeader.biBitCount = 32;
     bmi.bmiHeader.biCompression = BI_RGB;
     bmi.bmiHeader.biSizeImage = stride * dest.height();
     StretchDIBits(dc, dest.x(), dest.y(), dest.width(), dest.height(), 0, 0,
                   dest.width(), dest.height(),
                   FPDFBitmap_GetBuffer(bitmap.get()), &bmi, DIB_RGB_COLORS,
                   SRCCOPY);
   } else {
     FPDF_RenderPage(dc, page.get(), dest.x(), dest.y(), dest.width(),
                     dest.height(), rotate, flags);
   }
   RestoreDC(dc, save_state);
   return true;
 }

 void PDFiumEngineExports::SetPDFEnsureTypefaceCharactersAccessible(
     PDFEnsureTypefaceCharactersAccessible func) {
   FPDF_SetTypefaceAccessibleFunc(
       reinterpret_cast<PDFiumEnsureTypefaceCharactersAccessible>(func));
 }

 void PDFiumEngineExports::SetPDFUseGDIPrinting(bool enable) {
   FPDF_SetPrintTextWithGDI(enable);
 }

 void PDFiumEngineExports::SetPDFUsePrintMode(int mode) {
   FPDF_SetPrintMode(mode);
 }
 #endif  // defined(OS_WIN)

 bool PDFiumEngineExports::RenderPDFPageToBitmap(
     base::span<const uint8_t> pdf_buffer,
     int page_number,
     const RenderingSettings& settings,
     void* bitmap_buffer) {
   ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
   if (!doc)
     return false;
   ScopedFPDFPage page(FPDF_LoadPage(doc.get(), page_number));
   if (!page)
     return false;

   pp::Rect dest;
   int rotate = CalculatePosition(page.get(), settings, &dest);

   ScopedFPDFBitmap bitmap(FPDFBitmap_CreateEx(
       settings.bounds.width(), settings.bounds.height(), FPDFBitmap_BGRA,
       bitmap_buffer, settings.bounds.width() * 4));
   // Clear the bitmap
   FPDFBitmap_FillRect(bitmap.get(), 0, 0, settings.bounds.width(),
                       settings.bounds.height(), 0xFFFFFFFF);
   // Shift top-left corner of bounds to (0, 0) if it's not there.
   dest.set_point(dest.point() - settings.bounds.point());

   int flags = FPDF_ANNOT | FPDF_PRINTING;
   if (!settings.use_color)
     flags |= FPDF_GRAYSCALE;

   FPDF_RenderPageBitmap(bitmap.get(), page.get(), dest.x(), dest.y(),
                         dest.width(), dest.height(), rotate, flags);
   return true;
 }

 std::vector<uint8_t> PDFiumEngineExports::ConvertPdfPagesToNupPdf(
     std::vector<base::span<const uint8_t>> input_buffers,
     size_t pages_per_sheet,
     const gfx::Size& page_size,
     const gfx::Rect& printable_area) {
   if (!IsValidPrintableArea(page_size, printable_area))
     return std::vector<uint8_t>();

   ScopedFPDFDocument doc = CreatePdfDoc(std::move(input_buffers));
   if (!doc)
     return std::vector<uint8_t>();

   return PDFiumPrint::CreateNupPdf(std::move(doc), pages_per_sheet, page_size,
                                    printable_area);
 }

 std::vector<uint8_t> PDFiumEngineExports::ConvertPdfDocumentToNupPdf(
     base::span<const uint8_t> input_buffer,
     size_t pages_per_sheet,
     const gfx::Size& page_size,
     const gfx::Rect& printable_area) {
   if (!IsValidPrintableArea(page_size, printable_area))
     return std::vector<uint8_t>();

   ScopedFPDFDocument doc = LoadPdfData(input_buffer);
   if (!doc)
     return std::vector<uint8_t>();

   return PDFiumPrint::CreateNupPdf(std::move(doc), pages_per_sheet, page_size,
                                    printable_area);
 }

 bool PDFiumEngineExports::GetPDFDocInfo(base::span<const uint8_t> pdf_buffer,
                                         int* page_count,
                                         double* max_page_width) {
   ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
   if (!doc)
     return false;

   if (!page_count && !max_page_width)
     return true;

   int page_count_local = FPDF_GetPageCount(doc.get());
   if (page_count)
     *page_count = page_count_local;

   if (max_page_width) {
     *max_page_width = 0;
     for (int page_number = 0; page_number < page_count_local; page_number++) {
       double page_width = 0;
       double page_height = 0;
       FPDF_GetPageSizeByIndex(doc.get(), page_number, &page_width,
                               &page_height);
       if (page_width > *max_page_width) {
         *max_page_width = page_width;
       }
     }
   }
   return true;
 }

 bool PDFiumEngineExports::GetPDFPageSizeByIndex(
     base::span<const uint8_t> pdf_buffer,
     int page_number,
     double* width,
     double* height) {
   ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
   if (!doc)
     return false;
   return FPDF_GetPageSizeByIndex(doc.get(), page_number, width, height) != 0;
 }

 }  // namespace chrome_pdf
	// Copyright 2018 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "pdf/pdfium/pdfium_engine_exports.h"

	#include <algorithm>
	#include <utility>

	#include "base/no_destructor.h"
	#include "base/numerics/safe_conversions.h"
	#include "pdf/pdfium/pdfium_mem_buffer_file_write.h"
	#include "pdf/pdfium/pdfium_print.h"
	#include "printing/nup_parameters.h"
	#include "printing/units.h"
	#include "third_party/pdfium/public/cpp/fpdf_scopers.h"
	#include "third_party/pdfium/public/fpdf_ppo.h"
	#include "third_party/pdfium/public/fpdfview.h"
	#include "ui/gfx/geometry/rect.h"
	#include "ui/gfx/geometry/size.h"

	using printing::ConvertUnitDouble;
	using printing::kPointsPerInch;

	namespace chrome_pdf {

	namespace {

	int CalculatePosition(FPDF_PAGE page,
	const PDFiumEngineExports::RenderingSettings& settings,
	pp::Rect* dest) {
	// settings.bounds is in terms of the max DPI. Convert page sizes to match.
	int dpi = std::max(settings.dpi_x, settings.dpi_y);
	int page_width = static_cast<int>(
	ConvertUnitDouble(FPDF_GetPageWidth(page), kPointsPerInch, dpi));
	int page_height = static_cast<int>(
	ConvertUnitDouble(FPDF_GetPageHeight(page), kPointsPerInch, dpi));

	// Start by assuming that we will draw exactly to the bounds rect
	// specified.
	*dest = settings.bounds;

	int rotate = 0; // normal orientation.

	// Auto-rotate landscape pages to print correctly.
	if (settings.autorotate &&
	(dest->width() > dest->height()) != (page_width > page_height)) {
	rotate = 3; // 90 degrees counter-clockwise.
	std::swap(page_width, page_height);
	}

	// See if we need to scale the output
	bool scale_to_bounds = false;
	if (settings.fit_to_bounds &&
	((page_width > dest->width()) \|\| (page_height > dest->height()))) {
	scale_to_bounds = true;
	} else if (settings.stretch_to_bounds &&
	((page_width < dest->width()) \|\| (page_height < dest->height()))) {
	scale_to_bounds = true;
	}

	if (scale_to_bounds) {
	// If we need to maintain aspect ratio, calculate the actual width and
	// height.
	if (settings.keep_aspect_ratio) {
	double scale_factor_x = page_width;
	scale_factor_x /= dest->width();
	double scale_factor_y = page_height;
	scale_factor_y /= dest->height();
	if (scale_factor_x > scale_factor_y) {
	dest->set_height(page_height / scale_factor_x);
	} else {
	dest->set_width(page_width / scale_factor_y);
	}
	}
	} else {
	// We are not scaling to bounds. Draw in the actual page size. If the
	// actual page size is larger than the bounds, the output will be
	// clipped.
	dest->set_width(page_width);
	dest->set_height(page_height);
	}

	// Scale the bounds to device units if DPI is rectangular.
	if (settings.dpi_x != settings.dpi_y) {
	dest->set_width(dest->width() * settings.dpi_x / dpi);
	dest->set_height(dest->height() * settings.dpi_y / dpi);
	}

	if (settings.center_in_bounds) {
	pp::Point offset(
	(settings.bounds.width() * settings.dpi_x / dpi - dest->width()) / 2,
	(settings.bounds.height() * settings.dpi_y / dpi - dest->height()) / 2);
	dest->Offset(offset);
	}
	return rotate;
	}

	ScopedFPDFDocument LoadPdfData(base::span<const uint8_t> pdf_buffer) {
	if (!base::IsValueInRangeForNumericType<int>(pdf_buffer.size()))
	return nullptr;
	return ScopedFPDFDocument(
	FPDF_LoadMemDocument(pdf_buffer.data(), pdf_buffer.size(), nullptr));
	}

	ScopedFPDFDocument CreatePdfDoc(
	std::vector<base::span<const uint8_t>> input_buffers) {
	if (input_buffers.empty())
	return nullptr;

	ScopedFPDFDocument doc(FPDF_CreateNewDocument());
	size_t index = 0;
	for (auto input_buffer : input_buffers) {
	ScopedFPDFDocument single_page_doc = LoadPdfData(input_buffer);
	if (!FPDF_ImportPages(doc.get(), single_page_doc.get(), "1", index++)) {
	return nullptr;
	}
	}

	return doc;
	}

	bool IsValidPrintableArea(const gfx::Size& page_size,
	const gfx::Rect& printable_area) {
	return !printable_area.IsEmpty() && printable_area.x() >= 0 &&
	printable_area.y() >= 0 &&
	printable_area.right() <= page_size.width() &&
	printable_area.bottom() <= page_size.height();
	}

	} // namespace

	PDFEngineExports::RenderingSettings::RenderingSettings(int dpi_x,
	int dpi_y,
	const pp::Rect& bounds,
	bool fit_to_bounds,
	bool stretch_to_bounds,
	bool keep_aspect_ratio,
	bool center_in_bounds,
	bool autorotate,
	bool use_color)
	: dpi_x(dpi_x),
	dpi_y(dpi_y),
	bounds(bounds),
	fit_to_bounds(fit_to_bounds),
	stretch_to_bounds(stretch_to_bounds),
	keep_aspect_ratio(keep_aspect_ratio),
	center_in_bounds(center_in_bounds),
	autorotate(autorotate),
	use_color(use_color) {}

	PDFEngineExports::RenderingSettings::RenderingSettings(
	const RenderingSettings& that) = default;

	PDFEngineExports* PDFEngineExports::Get() {
	static base::NoDestructor<PDFiumEngineExports> exports;
	return exports.get();
	}

	PDFiumEngineExports::PDFiumEngineExports() {}

	PDFiumEngineExports::~PDFiumEngineExports() {}

	#if defined(OS_WIN)
	bool PDFiumEngineExports::RenderPDFPageToDC(
	base::span<const uint8_t> pdf_buffer,
	int page_number,
	const RenderingSettings& settings,
	HDC dc) {
	ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
	if (!doc)
	return false;
	ScopedFPDFPage page(FPDF_LoadPage(doc.get(), page_number));
	if (!page)
	return false;

	RenderingSettings new_settings = settings;
	// calculate the page size
	if (new_settings.dpi_x == -1)
	new_settings.dpi_x = GetDeviceCaps(dc, LOGPIXELSX);
	if (new_settings.dpi_y == -1)
	new_settings.dpi_y = GetDeviceCaps(dc, LOGPIXELSY);

	pp::Rect dest;
	int rotate = CalculatePosition(page.get(), new_settings, &dest);

	int save_state = SaveDC(dc);
	// The caller wanted all drawing to happen within the bounds specified.
	// Based on scale calculations, our destination rect might be larger
	// than the bounds. Set the clip rect to the bounds.
	IntersectClipRect(dc, settings.bounds.x(), settings.bounds.y(),
	settings.bounds.x() + settings.bounds.width(),
	settings.bounds.y() + settings.bounds.height());

	int flags = FPDF_ANNOT \| FPDF_PRINTING;
	if (!settings.use_color)
	flags \|= FPDF_GRAYSCALE;

	// A "temporary" hack. Some PDFs seems to render very slowly if
	// FPDF_RenderPage() is directly used on a printer DC. I suspect it is
	// because of the code to talk Postscript directly to the printer if
	// the printer supports this. Need to discuss this with PDFium. For now,
	// render to a bitmap and then blit the bitmap to the DC if we have been
	// supplied a printer DC.
	int device_type = GetDeviceCaps(dc, TECHNOLOGY);
	if (device_type == DT_RASPRINTER \|\| device_type == DT_PLOTTER) {
	ScopedFPDFBitmap bitmap(
	FPDFBitmap_Create(dest.width(), dest.height(), FPDFBitmap_BGRx));
	// Clear the bitmap
	FPDFBitmap_FillRect(bitmap.get(), 0, 0, dest.width(), dest.height(),
	0xFFFFFFFF);
	FPDF_RenderPageBitmap(bitmap.get(), page.get(), 0, 0, dest.width(),
	dest.height(), rotate, flags);
	int stride = FPDFBitmap_GetStride(bitmap.get());
	BITMAPINFO bmi;
	memset(&bmi, 0, sizeof(bmi));
	bmi.bmiHeader.biSize = sizeof(BITMAPINFOHEADER);
	bmi.bmiHeader.biWidth = dest.width();
	bmi.bmiHeader.biHeight = -dest.height(); // top-down image
	bmi.bmiHeader.biPlanes = 1;
	bmi.bmiHeader.biBitCount = 32;
	bmi.bmiHeader.biCompression = BI_RGB;
	bmi.bmiHeader.biSizeImage = stride * dest.height();
	StretchDIBits(dc, dest.x(), dest.y(), dest.width(), dest.height(), 0, 0,
	dest.width(), dest.height(),
	FPDFBitmap_GetBuffer(bitmap.get()), &bmi, DIB_RGB_COLORS,
	SRCCOPY);
	} else {
	FPDF_RenderPage(dc, page.get(), dest.x(), dest.y(), dest.width(),
	dest.height(), rotate, flags);
	}
	RestoreDC(dc, save_state);
	return true;
	}

	void PDFiumEngineExports::SetPDFEnsureTypefaceCharactersAccessible(
	PDFEnsureTypefaceCharactersAccessible func) {
	FPDF_SetTypefaceAccessibleFunc(
	reinterpret_cast<PDFiumEnsureTypefaceCharactersAccessible>(func));
	}

	void PDFiumEngineExports::SetPDFUseGDIPrinting(bool enable) {
	FPDF_SetPrintTextWithGDI(enable);
	}

	void PDFiumEngineExports::SetPDFUsePrintMode(int mode) {
	FPDF_SetPrintMode(mode);
	}
	#endif // defined(OS_WIN)

	bool PDFiumEngineExports::RenderPDFPageToBitmap(
	base::span<const uint8_t> pdf_buffer,
	int page_number,
	const RenderingSettings& settings,
	void* bitmap_buffer) {
	ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
	if (!doc)
	return false;
	ScopedFPDFPage page(FPDF_LoadPage(doc.get(), page_number));
	if (!page)
	return false;

	pp::Rect dest;
	int rotate = CalculatePosition(page.get(), settings, &dest);

	ScopedFPDFBitmap bitmap(FPDFBitmap_CreateEx(
	settings.bounds.width(), settings.bounds.height(), FPDFBitmap_BGRA,
	bitmap_buffer, settings.bounds.width() * 4));
	// Clear the bitmap
	FPDFBitmap_FillRect(bitmap.get(), 0, 0, settings.bounds.width(),
	settings.bounds.height(), 0xFFFFFFFF);
	// Shift top-left corner of bounds to (0, 0) if it's not there.
	dest.set_point(dest.point() - settings.bounds.point());

	int flags = FPDF_ANNOT \| FPDF_PRINTING;
	if (!settings.use_color)
	flags \|= FPDF_GRAYSCALE;

	FPDF_RenderPageBitmap(bitmap.get(), page.get(), dest.x(), dest.y(),
	dest.width(), dest.height(), rotate, flags);
	return true;
	}

	std::vector<uint8_t> PDFiumEngineExports::ConvertPdfPagesToNupPdf(
	std::vector<base::span<const uint8_t>> input_buffers,
	size_t pages_per_sheet,
	const gfx::Size& page_size,
	const gfx::Rect& printable_area) {
	if (!IsValidPrintableArea(page_size, printable_area))
	return std::vector<uint8_t>();

	ScopedFPDFDocument doc = CreatePdfDoc(std::move(input_buffers));
	if (!doc)
	return std::vector<uint8_t>();

	return PDFiumPrint::CreateNupPdf(std::move(doc), pages_per_sheet, page_size,
	printable_area);
	}

	std::vector<uint8_t> PDFiumEngineExports::ConvertPdfDocumentToNupPdf(
	base::span<const uint8_t> input_buffer,
	size_t pages_per_sheet,
	const gfx::Size& page_size,
	const gfx::Rect& printable_area) {
	if (!IsValidPrintableArea(page_size, printable_area))
	return std::vector<uint8_t>();

	ScopedFPDFDocument doc = LoadPdfData(input_buffer);
	if (!doc)
	return std::vector<uint8_t>();

	return PDFiumPrint::CreateNupPdf(std::move(doc), pages_per_sheet, page_size,
	printable_area);
	}

	bool PDFiumEngineExports::GetPDFDocInfo(base::span<const uint8_t> pdf_buffer,
	int* page_count,
	double* max_page_width) {
	ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
	if (!doc)
	return false;

	if (!page_count && !max_page_width)
	return true;

	int page_count_local = FPDF_GetPageCount(doc.get());
	if (page_count)
	*page_count = page_count_local;

	if (max_page_width) {
	*max_page_width = 0;
	for (int page_number = 0; page_number < page_count_local; page_number++) {
	double page_width = 0;
	double page_height = 0;
	FPDF_GetPageSizeByIndex(doc.get(), page_number, &page_width,
	&page_height);
	if (page_width > *max_page_width) {
	*max_page_width = page_width;
	}
	}
	}
	return true;
	}

	bool PDFiumEngineExports::GetPDFPageSizeByIndex(
	base::span<const uint8_t> pdf_buffer,
	int page_number,
	double* width,
	double* height) {
	ScopedFPDFDocument doc = LoadPdfData(pdf_buffer);
	if (!doc)
	return false;
	return FPDF_GetPageSizeByIndex(doc.get(), page_number, width, height) != 0;
	}

	} // namespace chrome_pdf