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qpdf/libqpdf/QPDFAnnotationObjectHelper.cc
Jay Berkenbilt d71f05ca07 Fix sign and conversion warnings (major)
This makes all integer type conversions that have potential data loss
explicit with calls that do range checks and raise an exception. After
this commit, qpdf builds with no warnings when -Wsign-conversion
-Wconversion is used with gcc or clang or when -W3 -Wd4800 is used
with MSVC. This significantly reduces the likelihood of potential
crashes from bogus integer values.

There are some parts of the code that take int when they should take
size_t or an offset. Such places would make qpdf not support files
with more than 2^31 of something that usually wouldn't be so large. In
the event that such a file shows up and is valid, at least qpdf would
raise an error in the right spot so the issue could be legitimately
addressed rather than failing in some weird way because of a silent
overflow condition.
2019-06-21 13:17:21 -04:00

284 lines
9.6 KiB
C++

#include <qpdf/QPDFAnnotationObjectHelper.hh>
#include <qpdf/QTC.hh>
#include <qpdf/QPDFMatrix.hh>
#include <qpdf/QUtil.hh>
#include <qpdf/QPDF.hh>
#include <qpdf/QPDFNameTreeObjectHelper.hh>
QPDFAnnotationObjectHelper::Members::~Members()
{
}
QPDFAnnotationObjectHelper::Members::Members()
{
}
QPDFAnnotationObjectHelper::QPDFAnnotationObjectHelper(QPDFObjectHandle oh) :
QPDFObjectHelper(oh)
{
}
std::string
QPDFAnnotationObjectHelper::getSubtype()
{
return this->oh.getKey("/Subtype").getName();
}
QPDFObjectHandle::Rectangle
QPDFAnnotationObjectHelper::getRect()
{
return this->oh.getKey("/Rect").getArrayAsRectangle();
}
QPDFObjectHandle
QPDFAnnotationObjectHelper::getAppearanceDictionary()
{
return this->oh.getKey("/AP");
}
std::string
QPDFAnnotationObjectHelper::getAppearanceState()
{
if (this->oh.getKey("/AS").isName())
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper AS present");
return this->oh.getKey("/AS").getName();
}
QTC::TC("qpdf", "QPDFAnnotationObjectHelper AS absent");
return "";
}
int
QPDFAnnotationObjectHelper::getFlags()
{
QPDFObjectHandle flags_obj = this->oh.getKey("/F");
return flags_obj.isInteger() ? flags_obj.getIntValueAsInt() : 0;
}
QPDFObjectHandle
QPDFAnnotationObjectHelper::getAppearanceStream(
std::string const& which,
std::string const& state)
{
QPDFObjectHandle ap = getAppearanceDictionary();
std::string desired_state = state.empty() ? getAppearanceState() : state;
if (ap.isDictionary())
{
QPDFObjectHandle ap_sub = ap.getKey(which);
if (ap_sub.isStream() && desired_state.empty())
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper AP stream");
return ap_sub;
}
if (ap_sub.isDictionary() && (! desired_state.empty()))
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper AP dictionary");
QPDFObjectHandle ap_sub_val = ap_sub.getKey(desired_state);
if (ap_sub_val.isStream())
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper AN sub stream");
return ap_sub_val;
}
}
}
QTC::TC("qpdf", "QPDFAnnotationObjectHelper AN null");
return QPDFObjectHandle::newNull();
}
std::string
QPDFAnnotationObjectHelper::getPageContentForAppearance(
std::string const& name, int rotate,
int required_flags, int forbidden_flags)
{
if (! getAppearanceStream("/N").isStream())
{
return "";
}
// The appearance matrix computed by this method is the
// transformation matrix that needs to be in effect when drawing
// this annotation's appearance stream on the page. The algorithm
// for computing the appearance matrix described in section 12.5.5
// of the ISO-32000 PDF spec is similar but not identical to what
// we are doing here.
// When rendering an appearance stream associated with an
// annotation, there are four relevant components:
//
// * The appearance stream's bounding box (/BBox)
// * The appearance stream's matrix (/Matrix)
// * The annotation's rectangle (/Rect)
// * In the case of form fields with the NoRotate flag, the
// page's rotation
// When rendering a form xobject in isolation, just drawn with a
// /Do operator, the is no form field, so page rotation is not
// relevant, and there is no annotation, so /Rect is not relevant,
// so only /BBox and /Matrix are relevant. The effect of these are
// as follows:
// * /BBox is treated as a clipping region
// * /Matrix is applied as a transformation prior to rendering the
// appearance stream.
// There is no relationship between /BBox and /Matrix in this
// case.
// When rendering a form xobject in the context of an annotation,
// things are a little different. In particular, a matrix is
// established such that /BBox, when transformed by /Matrix, would
// fit completely inside of /Rect. /BBox is no longer a clipping
// region. To illustrate the difference, consider a /Matrix of
// [2 0 0 2 0 0], which is scaling by a factor of two along both
// axes. If the appearance stream drew a rectangle equal to /BBox,
// in the case of the form xobject in isolation, this matrix would
// cause only the lower-left quadrant of the rectangle to be
// visible since the scaling would cause the rest of it to fall
// outside of the clipping region. In the case of the form xobject
// displayed in the context of an annotation, such a matrix would
// have no effect at all because it would be applied to the
// bounding box first, and then when the resulting enclosing
// quadrilateral was transformed to fit into /Rect, the effect of
// the scaling would be undone.
// Our job is to create a transformation matrix that compensates
// for these differences so that the appearance stream of an
// annotation can be drawn as a regular form xobject.
// To do this, we perform the following steps, which overlap
// significantly with the algorithm in 12.5.5:
// 1. Transform the four corners of /BBox by applying /Matrix to
// them, creating an arbitrarily transformed quadrilateral.
// 2. Find the minimum upright rectangle that encompasses the
// resulting quadrilateral. This is the "transformed appearance
// box", T.
// 3. Compute matrix A that maps the lower left and upper right
// corners of T to the annotation's /Rect. This can be done by
// scaling so that the sizes match and translating so that the
// scaled T exactly overlaps /Rect.
// If the annotation's /F flag has bit 4 set, this means that
// annotation is to be rotated about its upper left corner to
// counteract any rotation of the page so it remains upright. To
// achieve this effect, we do the following extra steps:
// 1. Perform the rotation on /BBox box prior to transforming it
// with /Matrix (by replacing matrix with concatenation of
// matrix onto the rotation)
// 2. Rotate the destination rectangle by the specified amount
// 3. Apply the rotation to A as computed above to get the final
// appearance matrix.
QPDFObjectHandle rect_obj = this->oh.getKey("/Rect");
QPDFObjectHandle as = getAppearanceStream("/N").getDict();
QPDFObjectHandle bbox_obj = as.getKey("/BBox");
QPDFObjectHandle matrix_obj = as.getKey("/Matrix");
int flags = getFlags();
if (flags & forbidden_flags)
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper forbidden flags");
return "";
}
if ((flags & required_flags) != required_flags)
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper missing required flags");
return "";
}
if (! (bbox_obj.isRectangle() && rect_obj.isRectangle()))
{
return "";
}
QPDFMatrix matrix;
if (matrix_obj.isMatrix())
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper explicit matrix");
matrix = QPDFMatrix(matrix_obj.getArrayAsMatrix());
}
else
{
QTC::TC("qpdf", "QPDFAnnotationObjectHelper default matrix");
}
QPDFObjectHandle::Rectangle rect = rect_obj.getArrayAsRectangle();
bool do_rotate = (rotate && (flags & an_no_rotate));
if (do_rotate)
{
// If the the annotation flags include the NoRotate bit and
// the page is rotated, we have to rotate the annotation about
// its upper left corner by the same amount in the opposite
// direction so that it will remain upright in absolute
// coordinates. Since the semantics of /Rotate for a page are
// to rotate the page, while the effect of rotating using a
// transformation matrix is to rotate the coordinate system,
// the opposite directionality is explicit in the code.
QPDFMatrix mr;
mr.rotatex90(rotate);
mr.concat(matrix);
matrix = mr;
double rect_w = rect.urx - rect.llx;
double rect_h = rect.ury - rect.lly;
switch (rotate)
{
case 90:
QTC::TC("qpdf", "QPDFAnnotationObjectHelper rotate 90");
rect = QPDFObjectHandle::Rectangle(
rect.llx,
rect.ury,
rect.llx + rect_h,
rect.ury + rect_w);
break;
case 180:
QTC::TC("qpdf", "QPDFAnnotationObjectHelper rotate 180");
rect = QPDFObjectHandle::Rectangle(
rect.llx - rect_w,
rect.ury,
rect.llx,
rect.ury + rect_h);
break;
case 270:
QTC::TC("qpdf", "QPDFAnnotationObjectHelper rotate 270");
rect = QPDFObjectHandle::Rectangle(
rect.llx - rect_h,
rect.ury - rect_w,
rect.llx,
rect.ury);
break;
default:
// ignore
break;
}
}
// Transform bounding box by matrix to get T
QPDFObjectHandle::Rectangle bbox = bbox_obj.getArrayAsRectangle();
QPDFObjectHandle::Rectangle T = matrix.transformRectangle(bbox);
if ((T.urx == T.llx) || (T.ury == T.lly))
{
// avoid division by zero
return "";
}
// Compute a matrix to transform the appearance box to the rectangle
QPDFMatrix AA;
AA.translate(rect.llx, rect.lly);
AA.scale((rect.urx - rect.llx) / (T.urx - T.llx),
(rect.ury - rect.lly) / (T.ury - T.lly));
AA.translate(-T.llx, -T.lly);
if (do_rotate)
{
AA.rotatex90(rotate);
}
as.replaceKey("/Subtype", QPDFObjectHandle::newName("/Form"));
return (
"q\n" +
AA.unparse() + " cm\n" +
name + " Do\n" +
"Q\n");
}