int main(int ac, char** av)
{
#if 1
{
fixed_t fu = float_to_fixed(1.2);
fixed_t bar = float_to_fixed(2.4);
fixed_t baz = fixed_add(fu, bar);
printf("%f + ", fixed_to_float(fu));
printf("%f = ", fixed_to_float(bar));
printf("%f\n", fixed_to_float(baz));
}
{
fixed_t fu = float_to_fixed(1.5);
fixed_t bar = int_to_fixed(2);
fixed_t baz = fixed_mul(fu, bar);
printf("%f * ", fixed_to_float(fu));
printf("%f = ", fixed_to_float(bar));
printf("%f\n", fixed_to_float(baz));
}
{
fixed_t fu = int_to_fixed(1);
fixed_t bar = int_to_fixed(2);
fixed_t baz = fixed_div(fu, bar);
printf("%f / ", fixed_to_float(fu));
printf("%f = ", fixed_to_float(bar));
printf("%f\n", fixed_to_float(baz));
}
{
fixed_t fu = int_to_fixed(-1);
fixed_t bar = int_to_fixed(2);
fixed_t baz = fixed_div(fu, bar);
printf("%f / ", fixed_to_float(fu));
printf("%f = ", fixed_to_float(bar));
printf("%f\n", fixed_to_float(baz));
}
#endif
#if 0
{
fixed_t alpha = float_to_fixed(0.0);
fixed_t step = float_to_fixed(0.01);
for (; alpha < FIXED_TWO_PI; alpha = fixed_add(alpha, step))
{
printf("%f ", fixed_to_float(alpha));
printf("%f\n", fabsf(sinf(fixed_to_float(alpha)) - fixed_to_float(fixed_sin(alpha))));
}
}
#endif
return 0;
}
void mat44_perspective(mat44 *m, fixed fov, fixed aspect, fixed near_z, fixed far_z) {
fixed _fov = fixed_div(fixed_mul(FIXED_PI, fov), int_to_fixed(180));
fixed _f = fixed_div(FIXED_ONE, fixed_tan(fixed_mul(_fov, double_to_fixed(0.5))));
fixed nf = fixed_div((far_z + near_z), (near_z - far_z));
fixed nfr = fixed_div(fixed_mul(fixed_mul(int_to_fixed(2), far_z), near_z), (near_z - far_z));
mat44_set(m,
fixed_div(_f, aspect), 0 , 0 , 0 ,
0 , _f, 0 , 0 ,
0 , 0 , nf , nfr,
0 , 0 , FIXED_NEGONE, 0);
}
/**
Calculates the result of plugging in @c value into the linear equation
described by the @c offset and @c coeff as a fixed point value.
Used in converting between units.
@code retval = (coeff * value) + offset @endcode
@param offset The offset of the linear equation. Often called @c b.
@param coeff The coefficient of the linear equation. Often called @c m.
@param value The value to be plugged into the linear equation. Often called @c x.
@return The fixed point result of plugging @c value into the linear equation.
*/
fixed linear_to_fixed(int offset, float coeff, int value){
int a, b, c, d, e;
a = value;
b = a - offset; //subtract the offset
c = -1 * int_to_fixed(b); //convert to fixed point
d = float_to_fixed(coeff); //convert coefficient to fixed point
e = fixed_mult(c,d); //multiply gain to get amps in fixed point
return e;
}
void draw_line_antialias_(GBitmap* img, int16_t x1, int16_t y1, int16_t x2, int16_t y2, GColor8 color)
{
uint8_t* img_pixels = gbitmap_get_data(img);
int16_t w = gbitmap_get_bounds(img).size.w;
int16_t h = gbitmap_get_bounds(img).size.h;
fixed dx = int_to_fixed(abs_(x1 - x2));
fixed dy = int_to_fixed(abs_(y1 - y2));
bool steep = dy > dx;
if(steep){
swap_(x1, y1);
swap_(x2, y2);
}
if(x1 > x2){
swap_(x1, x2);
swap_(y1, y2);
}
dx = x2 - x1;
dy = y2 - y1;
fixed intery;
int x;
for(x=x1; x <= x2; x++) {
intery = int_to_fixed(y1) + (int_to_fixed(x - x1) * dy / dx);
if(x>=0){
if(steep){
_plot(img_pixels, w, h, ipart_(intery) , x, color, rfpart_(intery));
_plot(img_pixels, w, h, ipart_(intery) + 1, x, color, fpart_(intery));
}
else {
_plot(img_pixels, w, h, x, ipart_(intery) , color, rfpart_(intery));
_plot(img_pixels, w, h, x, ipart_(intery) + 1, color, fpart_(intery));
}
}
}
}
void
image_downsize_gd_fixed_point(image *im)
{
int x, y;
fixed_t sy1, sy2, sx1, sx2;
int dstX = 0, dstY = 0, srcX = 0, srcY = 0;
fixed_t width_scale, height_scale;
int dstW = im->target_width;
int dstH = im->target_height;
int srcW = im->width;
int srcH = im->height;
if (im->height_padding) {
dstY = im->height_padding;
dstH = im->height_inner;
}
if (im->width_padding) {
dstX = im->width_padding;
dstW = im->width_inner;
}
width_scale = fixed_div(int_to_fixed(srcW), int_to_fixed(dstW));
height_scale = fixed_div(int_to_fixed(srcH), int_to_fixed(dstH));
for (y = dstY; (y < dstY + dstH); y++) {
sy1 = fixed_mul(int_to_fixed(y - dstY), height_scale);
sy2 = fixed_mul(int_to_fixed((y + 1) - dstY), height_scale);
for (x = dstX; (x < dstX + dstW); x++) {
fixed_t sx, sy;
fixed_t spixels = 0;
fixed_t red = 0, green = 0, blue = 0, alpha = 0;
if (!im->has_alpha)
alpha = FIXED_255;
sx1 = fixed_mul(int_to_fixed(x - dstX), width_scale);
sx2 = fixed_mul(int_to_fixed((x + 1) - dstX), width_scale);
sy = sy1;
/*
DEBUG_TRACE("sx1 %f, sx2 %f, sy1 %f, sy2 %f\n",
fixed_to_float(sx1), fixed_to_float(sx2), fixed_to_float(sy1), fixed_to_float(sy2));
*/
do {
fixed_t yportion;
//DEBUG_TRACE(" yportion(sy %f, sy1 %f, sy2 %f) = ", fixed_to_float(sy), fixed_to_float(sy1), fixed_to_float(sy2));
if (fixed_floor(sy) == fixed_floor(sy1)) {
yportion = FIXED_1 - (sy - fixed_floor(sy));
if (yportion > sy2 - sy1) {
yportion = sy2 - sy1;
}
sy = fixed_floor(sy);
}
else if (sy == fixed_floor(sy2)) {
yportion = sy2 - fixed_floor(sy2);
}
else {
yportion = FIXED_1;
}
//DEBUG_TRACE("%f\n", fixed_to_float(yportion));
sx = sx1;
do {
fixed_t xportion;
fixed_t pcontribution;
pix p;
//DEBUG_TRACE(" xportion(sx %f, sx1 %f, sx2 %f) = ", fixed_to_float(sx), fixed_to_float(sx1), fixed_to_float(sx2));
if (fixed_floor(sx) == fixed_floor(sx1)) {
xportion = FIXED_1 - (sx - fixed_floor(sx));
if (xportion > sx2 - sx1) {
xportion = sx2 - sx1;
}
sx = fixed_floor(sx);
}
else if (sx == fixed_floor(sx2)) {
xportion = sx2 - fixed_floor(sx2);
}
else {
xportion = FIXED_1;
}
//DEBUG_TRACE("%f\n", fixed_to_float(xportion));
pcontribution = fixed_mul(xportion, yportion);
p = get_pix(im, fixed_to_int(sx + srcX), fixed_to_int(sy + srcY));
/*
DEBUG_TRACE(" merging with pix %d, %d: src %x (%d %d %d %d), pcontribution %f\n",
fixed_to_int(sx + srcX), fixed_to_int(sy + srcY),
p, COL_RED(p), COL_GREEN(p), COL_BLUE(p), COL_ALPHA(p), fixed_to_float(pcontribution));
*/
red += fixed_mul(int_to_fixed(COL_RED(p)), pcontribution);
green += fixed_mul(int_to_fixed(COL_GREEN(p)), pcontribution);
blue += fixed_mul(int_to_fixed(COL_BLUE(p)), pcontribution);
if (im->has_alpha)
alpha += fixed_mul(int_to_fixed(COL_ALPHA(p)), pcontribution);
spixels += pcontribution;
sx += FIXED_1;
} while (sx < sx2);
sy += FIXED_1;
} while (sy < sy2);
// If rgba get too large for the fixed-point representation, fallback to the floating point routine
// This should only happen with very large images
if (red < 0 || green < 0 || blue < 0 || alpha < 0) {
warn("fixed-point overflow: %d %d %d %d\n", red, green, blue, alpha);
return image_downsize_gd(im);
}
if (spixels != 0) {
/*
DEBUG_TRACE(" rgba (%f %f %f %f) spixels %f\n",
fixed_to_float(red), fixed_to_float(green), fixed_to_float(blue), fixed_to_float(alpha), fixed_to_float(spixels));
*/
spixels = fixed_div(FIXED_1, spixels);
red = fixed_mul(red, spixels);
green = fixed_mul(green, spixels);
blue = fixed_mul(blue, spixels);
if (im->has_alpha)
alpha = fixed_mul(alpha, spixels);
}
/* Clamping to allow for rounding errors above */
if (red > FIXED_255) red = FIXED_255;
if (green > FIXED_255) green = FIXED_255;
if (blue > FIXED_255) blue = FIXED_255;
if (im->has_alpha && alpha > FIXED_255) alpha = FIXED_255;
/*
DEBUG_TRACE(" -> %d, %d %x (%d %d %d %d)\n",
x, y, COL_FULL(fixed_to_int(red), fixed_to_int(green), fixed_to_int(blue), fixed_to_int(alpha)),
fixed_to_int(red), fixed_to_int(green), fixed_to_int(blue), fixed_to_int(alpha));
*/
if (im->orientation != ORIENTATION_NORMAL) {
int ox, oy; // new destination pixel coordinates after rotating
image_get_rotated_coords(im, x, y, &ox, &oy);
if (im->orientation >= 5) {
// 90 and 270 rotations, width/height are swapped so we have to use alternate put_pix method
put_pix_rotated(
im, ox, oy, im->target_height,
COL_FULL(fixed_to_int(red), fixed_to_int(green), fixed_to_int(blue), fixed_to_int(alpha))
);
}
else {
put_pix(
im, ox, oy,
COL_FULL(fixed_to_int(red), fixed_to_int(green), fixed_to_int(blue), fixed_to_int(alpha))
);
}
}
else {
put_pix(
im, x, y,
COL_FULL(fixed_to_int(red), fixed_to_int(green), fixed_to_int(blue), fixed_to_int(alpha))
);
}
}
}
}
void menu_input( void ) {
switch (last_key) {
#if defined(TARGET_GP2X) || defined(TARGET_UNIX)
case SDLK_ESCAPE:
quit = true;
break;
#endif
case GP2X_KB_SELECT:
toggle_file_selector();
case GP2X_KB_START:
case GP2X_KB_Y:
case GP2X_KB_X:
toggle_menu();
need_redraw = true;
break;
case GP2X_KB_A:
case GP2X_KB_B:
switch (menu_select) {
case 2:
set_scale(int_to_fixed(1));
break;
case 3:
set_scale(fit_inside);
fit_pref = 0;
break;
case 4:
set_scale(fit_outside);
fit_pref = 1;
break;
case 6:
auto_fit = !auto_fit;
break;
case 7:
auto_rotate = !auto_rotate;
break;
case 9:
toggle_file_selector();
break;
case 10:
show_hidden = !show_hidden;
toggle_file_visibility();
break;
case 11:
toggle_menu();
break;
case 12:
quit = true;
break;
}
need_redraw = true;
break;
default:
break;
}
if (input[0]) {
switch (--menu_select) {
case 1:
menu_select = 12;
break;
case 5:
case 8:
menu_select--;
break;
}
delay += 150;
need_redraw = true;
}
if (input[2]) {
switch (++menu_select) {
case 5:
case 8:
menu_select++;
break;
case 13:
menu_select = 2;
break;
}
delay += 150;
need_redraw = true;
}
}