#include <string>
#include <vector>
#include <stdexcept>
#include <fstream>
#include <limits>
#include <cmath>
#include "igs_ifx_common.h" /* igs::image::rgba */
#include "igs_gaussian_blur.h"
#include "igs_gauss_distribution.cpp"
namespace {
const int diameter_from_radius_(const int radius) {
/* テーブルの半径サイズ(=中心位置)からテーブルの大きさを決める */
return radius * 2 + 1;
}
#if 0
template <class RT>
void blur_1st_hori_(
const double **in_plane_with_margin // &(std::vector<double *>).at(0)
,
const int height_with_margin, const int width_with_margin,
double *brush_sequence // &(std::vector<double *>).at(0)
,
const int int_radius,
double **out_plane_with_margin // &(std::vector<double *>).at(0)
/* 参照画像用情報(no margin) */
,
const RT *ref /* 求める画像(out)と同じ高さ、幅、チャンネル数 */
,
const int ref_mode /* 0=R,1=G,2=B,3=A,4=Luminance,5=Nothing */
,
const int ref_channels, const double real_radius, const double sigma) {
const int brush_diameter = diameter_from_radius_(int_radius);
const int width_no_margin = width_with_margin - int_radius * 2;
const int r_max = std::numeric_limits<RT>::max();
const RT *ref_vert = ref;
const RT *ref_hori = ref;
double before_real_radius = -1.0;
/* 縦方向 */
for (int yo = 0; yo < height_with_margin; ++yo) {
if (ref != 0) {
if (int_radius < yo && yo < (height_with_margin - int_radius)) {
ref_vert += width_no_margin * ref_channels;
}
ref_hori = ref_vert;
}
/* 横方向 */
for (int xx = 0, xo = int_radius; xx < width_no_margin; ++xx, ++xo) {
if (ref != 0) {
const double read_r =
real_radius *
igs::color::ref_value(ref_hori, ref_channels, r_max, ref_mode);
ref_hori += ref_channels;
if (read_r != before_real_radius) {
gauss_distribution_1d_(brush_sequence, brush_diameter,
igs::gaussian_blur_hv::int_radius(read_r),
read_r, sigma);
before_real_radius = read_r;
}
}
/* ガウス分布で横blur */
double accum = 0;
/*
for (int xb=0, xi=xx; xb<brush_diameter; ++xb,++xi) {
accum += in_plane_with_margin[yo][xi] * brush_sequence[xb];
}
*/
const double *bru_seq = brush_sequence;
int bru_dia = brush_diameter;
const double *inn_pla = &in_plane_with_margin[yo][xx];
while (0 < bru_dia--) {
accum += (*inn_pla++) * (*bru_seq++);
}
out_plane_with_margin[yo][xo] = accum;
}
}
}
#endif
void blur_1st_hori_(
const double** in_plane_with_margin // &(std::vector<double *>).at(0)
,
const int height_with_margin, const int width_with_margin,
double* brush_sequence // &(std::vector<double *>).at(0)
,
const int int_radius,
double** out_plane_with_margin // &(std::vector<double *>).at(0)
/* 参照画像用情報(no margin) */
,
const float* ref /* 求める画像(out)と同じ高さ、幅、チャンネル数 */
,
const double real_radius, const double sigma) {
const int brush_diameter = diameter_from_radius_(int_radius);
const int width_no_margin = width_with_margin - int_radius * 2;
// const int r_max = std::numeric_limits<RT>::max();
const float* ref_vert = ref;
const float* ref_hori = ref;
double before_real_radius = -1.0;
/* 縦方向 */
for (int yo = 0; yo < height_with_margin; ++yo) {
if (ref != nullptr) {
if (int_radius < yo && yo < (height_with_margin - int_radius)) {
ref_vert += width_no_margin;
}
ref_hori = ref_vert;
}
/* 横方向 */
for (int xx = 0, xo = int_radius; xx < width_no_margin; ++xx, ++xo) {
if (ref != 0) {
const double read_r = real_radius * (*ref_hori);
ref_hori++;
if (read_r != before_real_radius) {
gauss_distribution_1d_(brush_sequence, brush_diameter,
igs::gaussian_blur_hv::int_radius(read_r),
read_r, sigma);
before_real_radius = read_r;
}
}
/* ガウス分布で横blur */
double accum = 0;
const double* bru_seq = brush_sequence;
int bru_dia = brush_diameter;
const double* inn_pla = &in_plane_with_margin[yo][xx];
while (0 < bru_dia--) {
accum += (*inn_pla++) * (*bru_seq++);
}
out_plane_with_margin[yo][xo] = accum;
}
}
}
#if 0
template <class RT>
void blur_2nd_vert_(
const double **in_plane_with_margin // &(std::vector<double *>).at(0)
,
const int height_with_margin, const int width_with_margin,
double *brush_sequence // &(std::vector<double *>).at(0)
,
const int int_radius,
double **out_plane_with_margin // &(std::vector<double *>).at(0)
/* 参照画像用情報(no margin) */
,
const RT *ref /* 求める画像(out)と同じ高さ、幅、チャンネル数 */
,
const int ref_mode /* 0=R,1=G,2=B,3=A,4=Luminance,5=Nothing */
,
const int ref_channels, const double real_radius, const double sigma) {
const int brush_diameter = diameter_from_radius_(int_radius);
const int height_no_margin = height_with_margin - int_radius * 2;
const int width_no_margin = width_with_margin - int_radius * 2;
const int r_max = std::numeric_limits<RT>::max();
const RT *ref_vert = ref;
const RT *ref_hori = ref;
double before_real_radius = -1.0;
/* 左右マージン部分はもう処理しなくていい */
/* 横方向 */
for (int xx = 0, xo = int_radius; xx < width_no_margin; ++xx, ++xo) {
if (ref != 0) {
ref_hori += ref_channels;
ref_vert = ref_hori;
}
/* 縦方向 */
for (int yy = 0, yo = int_radius; yy < height_no_margin; ++yy, ++yo) {
if (ref != 0) {
const double read_r =
real_radius *
igs::color::ref_value(ref_vert, ref_channels, r_max, ref_mode);
ref_vert += width_no_margin * ref_channels;
if (read_r != before_real_radius) {
gauss_distribution_1d_(brush_sequence, brush_diameter,
igs::gaussian_blur_hv::int_radius(read_r),
read_r, sigma);
before_real_radius = read_r;
}
}
/* ガウス分布で横blur */
double accum = 0;
/*
for (int yb=0,yi=yy; yb<brush_diameter; ++yb,++yi) {
accum += in_plane_with_margin[yi][xo] * brush_sequence[yb];
}
*/
const double *bru_seq = brush_sequence;
int bru_dia = brush_diameter;
const double *inn_pla = &in_plane_with_margin[yy][xo];
while (0 < bru_dia--) {
accum += (*inn_pla) * (*bru_seq++);
inn_pla += width_with_margin;
}
out_plane_with_margin[yo][xo] = accum;
}
}
}
#endif
void blur_2nd_vert_(
const double** in_plane_with_margin // &(std::vector<double *>).at(0)
,
const int height_with_margin, const int width_with_margin,
double* brush_sequence // &(std::vector<double *>).at(0)
,
const int int_radius,
double** out_plane_with_margin // &(std::vector<double *>).at(0)
/* 参照画像用情報(no margin) */
,
const float* ref /* 求める画像(out)と同じ高さ、幅、チャンネル数 */
,
const double real_radius, const double sigma) {
const int brush_diameter = diameter_from_radius_(int_radius);
const int height_no_margin = height_with_margin - int_radius * 2;
const int width_no_margin = width_with_margin - int_radius * 2;
// const int r_max = std::numeric_limits<RT>::max();
const float* ref_vert = ref;
const float* ref_hori = ref;
double before_real_radius = -1.0;
/* 左右マージン部分はもう処理しなくていい */
/* 横方向 */
for (int xx = 0, xo = int_radius; xx < width_no_margin; ++xx, ++xo) {
if (ref != nullptr) {
ref_hori++;
ref_vert = ref_hori;
}
/* 縦方向 */
for (int yy = 0, yo = int_radius; yy < height_no_margin; ++yy, ++yo) {
if (ref != 0) {
const double read_r = real_radius * (*ref_vert);
ref_vert += width_no_margin;
if (read_r != before_real_radius) {
gauss_distribution_1d_(brush_sequence, brush_diameter,
igs::gaussian_blur_hv::int_radius(read_r),
read_r, sigma);
before_real_radius = read_r;
}
}
/* ガウス分布で横blur */
double accum = 0;
const double* bru_seq = brush_sequence;
int bru_dia = brush_diameter;
const double* inn_pla = &in_plane_with_margin[yy][xo];
while (0 < bru_dia--) {
accum += (*inn_pla) * (*bru_seq++);
inn_pla += width_with_margin;
}
out_plane_with_margin[yo][xo] = accum;
}
}
}
#if 0
template <class T>
void get_(const T *in, const int height, const int width, const int channels,
const int current_ch, double **out // &(std::vector<double *>).at(0)
) {
in += current_ch;
const double maxi = static_cast<double>(std::numeric_limits<T>::max());
for (int yy = 0; yy < height; ++yy) {
for (int xx = 0; xx < width; ++xx) {
out[yy][xx] = static_cast<double>(*in) / maxi;
in += channels;
}
}
}
#endif
void get_(const float* in, const int height, const int width,
const int channels, const int current_ch,
double** out // &(std::vector<double *>).at(0)
) {
in += current_ch;
for (int yy = 0; yy < height; ++yy) {
for (int xx = 0; xx < width; ++xx) {
out[yy][xx] = static_cast<double>(*in);
in += channels;
}
}
}
#if 0
template <class T>
void put_margin_(
const double **in_with_margin // &(std::vector<double *>).at(0)
,
const int height_with_margin, const int width_with_margin,
const int channels, const int current_ch, const int margin,
T *out_no_margin) {
out_no_margin += current_ch;
const double maxi =
static_cast<double>(std::numeric_limits<T>::max()) + 0.999999;
for (int yy = margin; yy < (height_with_margin - margin); ++yy) {
for (int xx = margin; xx < (width_with_margin - margin); ++xx) {
*out_no_margin = static_cast<T>(in_with_margin[yy][xx] * maxi);
out_no_margin += channels;
}
}
}
#endif
void put_margin_(
const double** in_with_margin, // &(std::vector<double *>).at(0)
const int height_with_margin, const int width_with_margin,
const int channels, const int current_ch, const int margin,
float* out_no_margin) {
out_no_margin += current_ch;
for (int yy = margin; yy < (height_with_margin - margin); ++yy) {
for (int xx = margin; xx < (width_with_margin - margin); ++xx) {
*out_no_margin = in_with_margin[yy][xx];
out_no_margin += channels;
}
}
}
#if 0
template <class T>
bool diff_between_channel_(const T *in, const int height, const int width,
const int channels, const int ch1, const int ch2) {
// if (ch1 == ch2) { return false; }
// if (channels <= ch1) { return false; }
// if (channels <= ch2) { return false; }
for (int yy = 0; yy < height; ++yy) {
for (int xx = 0; xx < width; ++xx) {
if (in[ch1] != in[ch2]) {
return true;
}
in += channels;
}
}
return false;
}
#endif
bool diff_between_channel_(const float* in, const int height, const int width,
const int channels, const int ch1, const int ch2) {
for (int yy = 0; yy < height; ++yy) {
for (int xx = 0; xx < width; ++xx) {
if (in[ch1] != in[ch2]) {
return true;
}
in += channels;
}
}
return false;
}
#if 0
template <class IT, class RT>
void convert_hv_(const IT *in_with_margin, IT *out_no_margin,
const int height_with_margin, const int width_with_margin,
const int channels
,
double *filter // (double *)(&filter_buf.at(0))
,
const int int_radius,
double **buffer_inn // &(std::vector<double *>).at(0)
,
double **buffer_out // &(std::vector<double *>).at(0)
/* 参照画像用情報(no margin) */
,
const RT *ref /* 求める画像(out)と同じ高さ、幅、チャンネル数 */
,
const int ref_mode /* 0=R,1=G,2=B,3=A,4=Luminance,5=Nothing */
,
const double real_radius, const double sigma) {
bool diff_sw = true; /* 1番目の画像は処理する */
for (int cc = 0; cc < channels; ++cc) {
if (0 < cc) { /* 2番目のチャンネル以後 */
/* 1つ前のチャンネルと違いを調べる */
diff_sw = diff_between_channel_(in_with_margin, height_with_margin,
width_with_margin, channels, cc - 1, cc);
}
/* 一つ前と同じ画像なら処理せず使い回して高速化する */
if (diff_sw) {
get_(in_with_margin, height_with_margin, width_with_margin, channels, cc,
buffer_inn);
blur_1st_hori_((const double **)(buffer_inn), height_with_margin,
width_with_margin, filter, int_radius, buffer_out
,
ref, ref_mode, channels, real_radius, sigma);
blur_2nd_vert_((const double **)(buffer_out), height_with_margin,
width_with_margin, filter, int_radius, buffer_inn
,
ref, ref_mode, channels, real_radius, sigma);
}
put_margin_((const double **)(buffer_inn), height_with_margin,
width_with_margin, channels, cc, int_radius, out_no_margin);
}
}
#endif
void convert_hv_(
const float* in_with_margin, float* out_no_margin,
const int height_with_margin, const int width_with_margin,
const int channels,
double* filter, // (double *)(&filter_buf.at(0))
const int int_radius,
double** buffer_inn, // &(std::vector<double *>).at(0)
double** buffer_out, // &(std::vector<double *>).at(0)
/* 参照画像用情報(no margin) */
const float* ref, /* 求める画像(out)と同じ高さ、幅、チャンネル数 */
const double real_radius, const double sigma) {
bool diff_sw = true; /* 1番目の画像は処理する */
for (int cc = 0; cc < channels; ++cc) {
if (0 < cc) { /* 2番目のチャンネル以後 */
/* 1つ前のチャンネルと違いを調べる */
diff_sw = diff_between_channel_(in_with_margin, height_with_margin,
width_with_margin, channels, cc - 1, cc);
}
/* 一つ前と同じ画像なら処理せず使い回して高速化する */
if (diff_sw) {
get_(in_with_margin, height_with_margin, width_with_margin, channels, cc,
buffer_inn);
blur_1st_hori_((const double**)(buffer_inn), height_with_margin,
width_with_margin, filter, int_radius, buffer_out, ref,
real_radius, sigma);
blur_2nd_vert_((const double**)(buffer_out), height_with_margin,
width_with_margin, filter, int_radius, buffer_inn, ref,
real_radius, sigma);
}
put_margin_((const double**)(buffer_inn), height_with_margin,
width_with_margin, channels, cc, int_radius, out_no_margin);
}
}
} // namespace
const int igs::gaussian_blur_hv::int_radius(const double real_radius) {
/* ぼかしの半径から、pixelサイズ半径(=中心位置=margin)を決める */
return static_cast<int>(ceil(real_radius));
}
const int igs::gaussian_blur_hv::buffer_bytes(const int height_with_margin,
const int width_with_margin,
const int int_radius) {
const int int_diameter = diameter_from_radius_(int_radius);
return int_diameter * int_diameter * sizeof(double) +
height_with_margin * width_with_margin * sizeof(double) +
height_with_margin * width_with_margin * sizeof(double);
}
void igs::gaussian_blur_hv::convert(
/* 入出力画像 */
const float* in_with_margin, float* out_no_margin,
const int height_with_margin, const int width_with_margin,
const int channels,
/* Pixel毎に効果の強弱 */
const float* ref, /* 求める画像(out)と同じ高、幅、ch数 */
/* 計算バッファ */
void* buffer,
int buffer_bytes, // Must be igs::gaussian_blur_hv::buffer_bytes(-)
/* Action Geometry */
const int int_radius, // =margin
const double real_radius, const double sigma //= 0.25
) {
/* 引数チェック */
if (real_radius <= 0.0) {
return;
}
if ((igs::image::rgba::siz != channels) &&
(igs::image::rgb::siz != channels) && (1 != channels) /* grayscale */
) {
throw std::domain_error("Bad channels,Not rgba/rgb/grayscale");
}
/* 変数の設定 */
const int int_diameter = diameter_from_radius_(int_radius);
double* double_buffer = static_cast<double*>(buffer);
/* メモリバッファの設定 */
std::vector<double> filter_buf(int_diameter);
std::vector<double*> in_plane_with_margin_dp(height_with_margin);
for (int yy = 0; yy < height_with_margin; ++yy) {
in_plane_with_margin_dp.at(yy) = double_buffer;
double_buffer += width_with_margin;
buffer_bytes -= width_with_margin * sizeof(double);
if (buffer_bytes <= 0) {
std::string msg("buffer_inn is empty");
throw std::domain_error(msg);
}
}
std::vector<double*> out_plane_with_margin_dp(height_with_margin);
for (int yy = 0; yy < height_with_margin; ++yy) {
out_plane_with_margin_dp.at(yy) = double_buffer;
double_buffer += width_with_margin;
buffer_bytes -= width_with_margin * sizeof(double);
if (buffer_bytes <= 0) {
std::string msg("buffer_out is empty");
throw std::domain_error(msg);
}
}
/* filter生成 */
gauss_distribution_1d_(&filter_buf.at(0), int_diameter, int_radius,
real_radius, sigma);
convert_hv_(in_with_margin, out_no_margin, height_with_margin,
width_with_margin, channels, &filter_buf.at(0), int_radius,
&in_plane_with_margin_dp.at(0), &out_plane_with_margin_dp.at(0),
ref, real_radius, sigma);
/*
if ((std::numeric_limits<unsigned char>::digits == bits) &&
((std::numeric_limits<unsigned char>::digits == ref_bits) ||
(0 == ref_bits))) {
convert_hv_(static_cast<const unsigned char *>(in_with_margin),
static_cast<unsigned char *>(out_no_margin), height_with_margin,
width_with_margin, channels, &filter_buf.at(0), int_radius,
&in_plane_with_margin_dp.at(0), &out_plane_with_margin_dp.at(0)
,
ref, ref_mode, real_radius, sigma);
} else if ((std::numeric_limits<unsigned short>::digits == bits) &&
((std::numeric_limits<unsigned char>::digits == ref_bits) ||
(0 == ref_bits))) {
convert_hv_(static_cast<const unsigned short *>(in_with_margin),
static_cast<unsigned short *>(out_no_margin),
height_with_margin, width_with_margin, channels,
&filter_buf.at(0), int_radius, &in_plane_with_margin_dp.at(0),
&out_plane_with_margin_dp.at(0)
,
ref, ref_mode, real_radius, sigma);
} else if ((std::numeric_limits<unsigned short>::digits == bits) &&
(std::numeric_limits<unsigned short>::digits == ref_bits)) {
convert_hv_(static_cast<const unsigned short *>(in_with_margin),
static_cast<unsigned short *>(out_no_margin),
height_with_margin, width_with_margin, channels,
&filter_buf.at(0), int_radius, &in_plane_with_margin_dp.at(0),
&out_plane_with_margin_dp.at(0)
,
reinterpret_cast<const unsigned short *>(ref), ref_mode,
real_radius, sigma);
} else if ((std::numeric_limits<unsigned char>::digits == bits) &&
(std::numeric_limits<unsigned short>::digits == ref_bits)) {
convert_hv_(static_cast<const unsigned short *>(in_with_margin),
static_cast<unsigned short *>(out_no_margin),
height_with_margin, width_with_margin, channels,
&filter_buf.at(0), int_radius, &in_plane_with_margin_dp.at(0),
&out_plane_with_margin_dp.at(0)
,
reinterpret_cast<const unsigned char *>(ref), ref_mode,
real_radius, sigma);
} else {
throw std::domain_error("Bad bits,Not uchar/ushort");
}
*/
}