#include <iostream> // std::cout
#include <vector> // std::vector
#include <cmath> // cos(),sin(),sqrt()
#include <limits> // std::numeric_limits<T>
#include <stdexcept> // std::domain_error()
#include "igs_ifx_common.h"
#include "igs_rotate_blur.h"
#include <QVector2D>
#include <QTransform>
namespace {
enum Type { Accelerator = 0, Uniform_Angle, Uniform_Length };
//------------------------------------------------------------------
class Rotator {
const float* in_top_;
const int hh_;
const int ww_;
const int cc_;
const TPointD center_;
const bool antialias_sw_;
const bool alpha_rendering_sw_;
const double radian_;
const double blur_radius_;
const double spin_radius_;
const int type_;
const double ellipse_aspect_ratio_;
const double ellipse_angle_;
QTransform tr_, tr_inv_;
public:
Rotator(const float* in_top, const int height, const int width,
const int channels, const TPointD center, const bool antialias_sw,
const bool alpha_rendering_sw, const double radian,
const double blur_radius, const double spin_radius, const int type,
const double ellipse_aspect_ratio, const double ellipse_angle)
: in_top_(in_top)
, hh_(height)
, ww_(width)
, cc_(channels)
, center_(center)
, antialias_sw_(antialias_sw)
, alpha_rendering_sw_(alpha_rendering_sw)
, radian_(radian)
, blur_radius_(blur_radius)
, spin_radius_(spin_radius)
, type_(type)
, ellipse_aspect_ratio_(ellipse_aspect_ratio)
, ellipse_angle_(ellipse_angle) {
if (ellipse_aspect_ratio_ != 1.0) {
double axis_x =
2.0 * ellipse_aspect_ratio_ / (ellipse_aspect_ratio_ + 1.0);
double axis_y = axis_x / ellipse_aspect_ratio_;
tr_ = QTransform()
.rotateRadians(this->ellipse_angle_)
.scale(axis_x, axis_y);
tr_inv_ = QTransform(tr_).inverted();
}
}
void pixel_value(const float* in_current_pixel, const int xx, const int yy,
const bool isRGB, const double refVal, float* result_pixel) {
auto in_pixel = [&](int x, int y) {
/* clamp */
x = (x < 0) ? 0 : ((this->ww_ <= x) ? this->ww_ - 1 : x);
y = (y < 0) ? 0 : ((this->hh_ <= y) ? this->hh_ - 1 : y);
return this->in_top_ + this->cc_ * y * this->ww_ + this->cc_ * x;
};
auto interp = [&](float v1, float v2, float r) {
return v1 * (1.f - r) + v2 * r;
};
auto accum_interp_in_values = [&](QPointF pos, std::vector<float>& accumP,
int z1, int z2, float weight) {
int xId = (int)std::floor(pos.x());
float rx = pos.x() - (float)xId;
int yId = (int)std::floor(pos.y());
float ry = pos.y() - (float)yId;
const float* p00 = in_pixel(xId, yId);
const float* p01 = in_pixel(xId + 1, yId);
const float* p10 = in_pixel(xId, yId + 1);
const float* p11 = in_pixel(xId + 1, yId + 1);
for (int zz = z1; zz <= z2; zz++) {
accumP[zz] += weight * interp(interp(p00[zz], p01[zz], rx),
interp(p10[zz], p11[zz], rx), ry);
}
};
auto accum_in_values = [&](QPointF pos, std::vector<float>& accumP, int z1,
int z2, float weight) {
int xId = (int)std::round(pos.x());
int yId = (int)std::round(pos.y());
const float* p = in_pixel(xId, yId);
for (int zz = z1; zz <= z2; zz++) {
accumP[zz] += weight * p[zz];
}
};
int c1, c2;
if (isRGB) {
#if defined RGBA_ORDER_OF_TOONZ6
c1 = igs::image::rgba::blu;
c2 = igs::image::rgba::red;
#elif defined RGBA_ORDER_OF_OPENGL
c1 = igs::image::rgba::red;
c2 = igs::image::rgba::blu;
#else
Must be define / DRGBA_ORDER_OF_TOONZ6 or / DRGBA_ORDER_OF_OPENGL
#endif
} else {
c1 = igs::image::rgba::alp;
c2 = igs::image::rgba::alp;
}
const QPointF center(this->center_.x, this->center_.y);
/* Pixel位置 */
const QPointF p(static_cast<float>(xx), static_cast<float>(yy));
/* 中心からPixel位置へのベクトルと長さ */
const QVector2D v(p - center);
const float dist = v.length();
/* 指定半径の範囲内なら何もしない */
bool is_in_blur_radius = false;
if (this->ellipse_aspect_ratio_ == 1.f) {
is_in_blur_radius = (dist <= this->blur_radius_);
} else {
is_in_blur_radius =
QVector2D(this->tr_inv_.map(v.toPointF())).lengthSquared() <=
(this->blur_radius_ * this->blur_radius_);
}
if (is_in_blur_radius) {
for (int c = c1; c <= c2; ++c) {
result_pixel[c] = in_current_pixel[c];
}
return;
}
/* 積算値と積算回数 */
std::vector<float> accum_val(this->cc_);
float accum_counter = 0.f; // TODO 重みづけを均一以外も選べるようにしたい
/* 参照画像による強弱付加 */
float radian = this->radian_ * refVal; // TODO: it can be bidirectional..
if (type_ == Accelerator) { /* 外への強調 */
radian *= (dist - this->blur_radius_) / this->spin_radius_;
} else if (type_ == Uniform_Length &&
dist > 0.) { // decrease radian so that the blur length becomes
// the same along radius
radian *= (this->spin_radius_ + this->blur_radius_) / dist;
radian = std::min(radian, 2.f * (float)M_PI);
}
// blur pixel length at the current pos
float spin_length_half = dist * radian * 0.5f;
// sampling in both directions
float sample_length = 0.f;
while (sample_length < spin_length_half) {
// compute weight
float weight = 1.f;
if (sample_length >= spin_length_half - 1.f) {
if (antialias_sw_)
weight = spin_length_half - sample_length;
else
break;
}
// advance to the next sample
sample_length += weight;
// compute for both side
float sample_radian = sample_length / dist;
QPointF vrot1, vrot2;
if (this->ellipse_aspect_ratio_ == 1.f) {
float cos = std::cos(sample_radian);
float sin = std::sin(sample_radian);
vrot1 = QPointF(cos * v.x() - sin * v.y(), sin * v.x() + cos * v.y());
vrot2 = QPointF(cos * v.x() + sin * v.y(), -sin * v.x() + cos * v.y());
} else {
vrot1 =
(this->tr_inv_ * QTransform(this->tr_).rotateRadians(sample_radian))
.map(v.toPointF());
vrot2 = (this->tr_inv_ *
QTransform(this->tr_).rotateRadians(-sample_radian))
.map(v.toPointF());
}
if (antialias_sw_) {
accum_interp_in_values(vrot1 + center, accum_val, c1, c2, weight);
accum_interp_in_values(vrot2 + center, accum_val, c1, c2, weight);
} else {
accum_in_values(vrot1 + center, accum_val, c1, c2, weight);
accum_in_values(vrot2 + center, accum_val, c1, c2, weight);
}
accum_counter += weight * 2.f;
}
// sample the original pos
if (antialias_sw_)
accum_interp_in_values(p, accum_val, c1, c2, 1.f);
else
accum_in_values(p, accum_val, c1, c2, 1.f);
accum_counter += 1.f;
//}
/* 積算しなかったとき(念のためのCheck) */
if (accum_counter <= 0.f) {
for (int c = c1; c <= c2; ++c) {
result_pixel[c] = in_current_pixel[c];
}
return;
}
/* ここで画像Pixelに保存 */
for (int c = c1; c <= c2; ++c) {
accum_val[c] /= accum_counter;
if (isRGB && !this->alpha_rendering_sw_ &&
(in_current_pixel[c] < accum_val[c]) &&
result_pixel[igs::image::rgba::alp] < 1.f) {
/* 増分のみMask! */
result_pixel[c] =
in_current_pixel[c] + (accum_val[c] - in_current_pixel[c]) *
result_pixel[igs::image::rgba::alp];
} else {
result_pixel[c] = accum_val[c];
}
}
}
private:
// disable
Rotator();
Rotator(const Rotator&);
Rotator& operator=(const Rotator&) {}
};
//------------------------------------------------------------------
void rotate_convert(
const float* in, float* out, const int margin, /* 参照画像(in)がもつ余白 */
const TDimension out_dim, /* 求める画像(out)のサイズ */
const int channels, const float* ref, /* 求める画像(out)と同じ高さ、幅 */
const TPointD center, const double degree,
const double blur_radius, /* ぼかしの始まる半径 */
const double spin_radius, /* ゼロ以上でspin指定となり、
かつぼかし強弱の一定になる半径となる */
const int type, // 0: Accelerator, 1: Uniform Angle, 2: Uniform Length
const bool antialias_sw, /* when true, sampled pixel will be
bilinear-interpolated */
const bool alpha_rendering_sw, const double ellipse_aspect_ratio,
const double ellipse_angle) {
assert(degree > 0.0);
Rotator rotator(in, out_dim.ly + margin * 2, out_dim.lx + margin * 2,
channels, center, antialias_sw, alpha_rendering_sw,
degree * M_PI_180, blur_radius, spin_radius, type,
ellipse_aspect_ratio, ellipse_angle * M_PI_180);
const float* p_in =
in + margin * (out_dim.lx + margin * 2) * channels + margin * channels;
float* p_out = out;
const float* p_ref = ref; // may be nullptr
for (int yy = margin; yy < out_dim.ly + margin;
++yy, p_in += 2 * margin * channels) {
for (int xx = margin; xx < out_dim.lx + margin;
++xx, p_in += channels, p_out += channels) {
using namespace igs::image::rgba;
float refVal = (ref) ? *p_ref : 1.f;
// if the reference value is zero
if (refVal == 0.f) {
for (int c = 0; c < channels; ++c) p_out[c] = p_in[c];
p_ref++;
continue;
}
if (alpha_rendering_sw) { // blur alpha
rotator.pixel_value(p_in, xx, yy, false, refVal, p_out);
} else { // use the src alpha as-is
p_out[alp] = p_in[alp];
}
if (p_out[alp] == 0.f) {
p_out[red] = p_in[red];
p_out[gre] = p_in[gre];
p_out[blu] = p_in[blu];
if (ref) p_ref++;
continue;
}
// blur RGB channels
rotator.pixel_value(p_in, xx, yy, true, refVal, p_out);
if (ref) p_ref++;
}
}
}
//------------------------------------------------------------------
} // namespace
void igs::rotate_blur::convert(
const float* in, float* out, const int margin,
const TDimension out_dim, /* 求める画像(out)の大きさ */
const int channels, const float* ref, /* outと同じ高さ、幅 */
const TPointD center, const double degree, /* ぼかしの回転角度 */
const double blur_radius, /* ぼかしの始まる半径 */
const double spin_radius, /* ゼロ以上でspin指定となり、
かつぼかし強弱の一定になる半径となる */
const int type, // 0: Accelerator, 1: Uniform Angle, 2: Uniform Length
const bool antialias_sw, /* when true, sampled pixel will be
bilinear-interpolated */
const bool alpha_rendering_sw, const double ellipse_aspect_ratio,
const double ellipse_angle) {
/* 強度のないとき */
if (degree <= 0.0) {
igs::image::copy_except_margin(in, margin, out, out_dim.ly, out_dim.lx,
channels);
return;
}
rotate_convert(in, out, margin, out_dim, channels, ref, center, degree,
blur_radius, spin_radius, type, antialias_sw,
alpha_rendering_sw, ellipse_aspect_ratio, ellipse_angle);
}
//--------------------------------------------------------------------
namespace {
double reference_margin_length_(const TPointD center, const double xp,
const double yp, double radian,
const double blur_radius,
const double spin_radius, const int type) {
const QPointF c(center.x, center.y);
const QPointF p(xp, yp);
const QVector2D v(p - c);
const float dist = v.length();
if (type == Accelerator) { /* 外への強調 */
radian *= (dist - blur_radius) / spin_radius;
} else if (type == Uniform_Length &&
dist > 0.) { // decrease radian so that the blur length becomes
// the same along radius
radian *= (spin_radius + blur_radius) / dist;
radian = std::min(radian, 2. * M_PI);
}
double cosval = cos(radian / 2.0);
double sinval = sin(radian / 2.0);
QPointF vrot1(v.x() * cosval - v.y() * sinval,
v.x() * sinval + v.y() * cosval);
QPointF vrot2(v.x() * cosval + v.y() * sinval,
-v.x() * sinval + v.y() * cosval);
float dist1 = QVector2D(vrot1 + c - p).length();
float dist2 = QVector2D(vrot2 + c - p).length();
return (dist1 < dist2) ? dist2 : dist1;
}
} // namespace
int igs::rotate_blur::reference_margin(
const int height, /* 求める画像(out)の高さ */
const int width, /* 求める画像(out)の幅 */
const TPointD center, const double degree, /* ぼかしの回転角度 */
const double blur_radius, /* ぼかしの始まる半径 */
const double spin_radius, /* ゼロ以上でspin指定となり、
かつぼかし強弱の一定になる半径となる */
const int type, // 0: Accelerator, 1: Uniform Angle, 2: Uniform Length
const double ellipse_aspect_ratio) {
/* 強度のないとき、なにもしない */
if (degree <= 0.0) {
return 0;
}
double margin1 = 0;
double margin2 = 0;
double deg = degree;
if (180.0 < deg) {
deg = 180.0;
}
margin1 =
reference_margin_length_(center, -width / 2.0, -height / 2.0,
deg * M_PI_180, blur_radius, spin_radius, type);
margin2 =
reference_margin_length_(center, -width / 2.0, height / 2.0,
deg * M_PI_180, blur_radius, spin_radius, type);
if (margin1 < margin2) {
margin1 = margin2;
}
margin2 =
reference_margin_length_(center, width / 2.0, -height / 2.0,
deg * M_PI_180, blur_radius, spin_radius, type);
if (margin1 < margin2) {
margin1 = margin2;
}
margin2 =
reference_margin_length_(center, width / 2.0, height / 2.0,
deg * M_PI_180, blur_radius, spin_radius, type);
if (margin1 < margin2) {
margin1 = margin2;
}
// Consider ellipse deformation.
// Instead of precise computing, return the maximum possible value.
if (ellipse_aspect_ratio != 1.0) {
double axis_x = 2.0 * ellipse_aspect_ratio / (ellipse_aspect_ratio + 1.0);
double axis_y = axis_x / ellipse_aspect_ratio;
margin1 *= std::max(axis_x, axis_y);
}
return static_cast<int>(ceil(margin1));
}