eBookReaderSwitch/source/fitz/draw-edgebuffer.c

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#include "mupdf/fitz.h"
#include "draw-imp.h"
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#undef DEBUG_SCAN_CONVERTER
/* Define ourselves a 'fixed' type for clarity */
typedef int fixed;
#define fixed_shift 8
#define float2fixed(x) ((int)((x)*(1<<fixed_shift)))
#define fixed2int(x) ((int)((x)>>fixed_shift))
#define fixed_half (1<<(fixed_shift-1))
#define fixed_1 (1<<fixed_shift)
#define int2fixed(x) ((x)<<fixed_shift)
enum
{
DIRN_UNSET = -1,
DIRN_UP = 0,
DIRN_DOWN = 1
};
typedef struct
{
fixed left;
fixed right;
fixed y;
signed char d; /* 0 up (or horiz), 1 down, -1 uninited */
/* unset == 1, iff the values in the above are unset */
unsigned char unset;
/* can_save == 1, iff we are eligible to 'save'. i.e. if we
* have not yet output a cursor, and have not detected
* any line segments completely out of range. */
unsigned char can_save;
unsigned char saved;
fixed save_left;
fixed save_right;
int save_iy;
int save_d;
}
cursor_t;
typedef struct fz_edgebuffer_s
{
fz_rasterizer super;
int app;
int sorted;
int n;
int index_cap;
int *index;
int table_cap;
int *table;
/* cursor section, for use with any part of pixel mode */
cursor_t cursor[3];
} fz_edgebuffer;
static fz_rasterizer_insert_fn fz_insert_edgebuffer_app;
static fz_rasterizer_insert_fn fz_insert_edgebuffer;
#ifdef DEBUG_SCAN_CONVERTER
int debugging_scan_converter = 1;
static void
fz_edgebuffer_print(fz_context *ctx, fz_output *out, fz_edgebuffer * edgebuffer)
{
int i;
int height = edgebuffer->super.clip.y1 - edgebuffer->super.clip.y0;
fz_write_printf(ctx, out, "Edgebuffer %x\n", edgebuffer);
fz_write_printf(ctx, out, "xmin=%x xmax=%x base=%x height=%x\n",
edgebuffer->super.clip.x0, edgebuffer->super.clip.x1, edgebuffer->super.clip.y0, height);
for (i=0; i < height; i++) {
int offset = edgebuffer->index[i];
int *row = &edgebuffer->table[offset];
int count = *row++;
assert ((count & 1) == 0);
fz_write_printf(ctx, out, "%x @ %x: %d =", i, offset, count);
while (count-- > 0) {
int v = *row++;
fz_write_printf(ctx, out, " %x:%d", v&~1, v&1);
}
fz_write_printf(ctx, out, "\n");
}
}
static void
fz_edgebuffer_print_app(fz_context *ctx, fz_output *out, fz_edgebuffer * edgebuffer)
{
int i;
int height = edgebuffer->super.clip.y1 - edgebuffer->super.clip.y0;
fz_write_printf(ctx, out, "Edgebuffer %x\n", edgebuffer);
fz_write_printf(ctx, out, "xmin=%x xmax=%x base=%x height=%x\n",
edgebuffer->super.clip.x0, edgebuffer->super.clip.x1, edgebuffer->super.clip.y0, height);
if (edgebuffer->table == NULL)
return;
for (i=0; i < height; i++) {
int offset = edgebuffer->index[i];
int *row = &edgebuffer->table[offset];
int count = *row++;
int count0 = count;
fz_write_printf(ctx, out, "%x @ %x: %d =", i, offset, count);
while (count-- > 0) {
int l = *row++;
int r = *row++;
fz_write_printf(ctx, out, " %x:%x", l, r);
}
assert((count0 & 1) == 0); (void)count0;
fz_write_printf(ctx, out, "\n");
}
}
#endif
static void fz_drop_edgebuffer(fz_context *ctx, fz_rasterizer *r)
{
fz_edgebuffer *eb = (fz_edgebuffer *)r;
if (eb)
{
fz_free(ctx, eb->index);
fz_free(ctx, eb->table);
}
fz_free(ctx, eb);
}
static void index_edgebuffer_insert(fz_context *ctx, fz_rasterizer *ras, float fsx, float fsy, float fex, float fey, int rev)
{
fz_edgebuffer *eb = (fz_edgebuffer *)ras;
int iminy, imaxy;
int height = eb->super.clip.y1 - eb->super.clip.y0;
if (fsy == fey)
return;
if (fsx < fex)
{
if (fsx < eb->super.bbox.x0) eb->super.bbox.x0 = fsx;
if (fex > eb->super.bbox.x1) eb->super.bbox.x1 = fex;
}
else
{
if (fsx > eb->super.bbox.x1) eb->super.bbox.x1 = fsx;
if (fex < eb->super.bbox.x0) eb->super.bbox.x0 = fex;
}
if (fsy < fey)
{
if (fsy < eb->super.bbox.y0) eb->super.bbox.y0 = fsy;
if (fey > eb->super.bbox.y1) eb->super.bbox.y1 = fey;
}
else
{
if (fey < eb->super.bbox.y0) eb->super.bbox.y0 = fey;
if (fsy > eb->super.bbox.y1) eb->super.bbox.y1 = fsy;
}
/* To strictly match, this should be:
* iminy = int2fixed(float2fixed(fsy))
* imaxy = int2fixed(float2fixed(fsx))
* but this is faster. It can round differently,
* (on some machines at least) hence the iminy--; below.
*/
iminy = (int)fsy;
imaxy = (int)fey;
if (iminy > imaxy)
{
int t;
t = iminy; iminy = imaxy; imaxy = t;
}
imaxy++;
iminy--;
imaxy -= eb->super.clip.y0;
if (imaxy < 0)
return;
iminy -= eb->super.clip.y0;
if (iminy < 0)
iminy = 0;
else if (iminy > height)
return;
if (imaxy > height-1)
imaxy = height-1;
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
fprintf(stderr, "%x->%x:%d\n", iminy, imaxy, eb->n);
#endif
eb->index[iminy] += eb->n;
eb->index[imaxy+1] -= eb->n;
}
static void fz_postindex_edgebuffer(fz_context *ctx, fz_rasterizer *r)
{
fz_edgebuffer *eb = (fz_edgebuffer *)r;
int height = eb->super.clip.y1 - eb->super.clip.y0 + 1;
int n = eb->n;
int total = 0;
int delta = 0;
int i;
eb->super.fns.insert = (eb->app ? fz_insert_edgebuffer_app : fz_insert_edgebuffer);
for (i = 0; i < height; i++)
{
delta += eb->index[i];
eb->index[i] = total;
total += 1 + delta*n;
}
assert(delta == 0);
if (eb->table_cap < total)
{
eb->table = fz_realloc_array(ctx, eb->table, total, int);
eb->table_cap = total;
}
for (i = 0; i < height; i++)
{
eb->table[eb->index[i]] = 0;
}
}
static int fz_reset_edgebuffer(fz_context *ctx, fz_rasterizer *r)
{
fz_edgebuffer *eb = (fz_edgebuffer *)r;
int height = eb->super.clip.y1 - eb->super.clip.y0 + 1;
int n;
eb->sorted = 0;
if (eb->index_cap < height)
{
eb->index = fz_realloc_array(ctx, eb->index, height, int);
eb->index_cap = height;
}
memset(eb->index, 0, sizeof(int) * height);
n = 1;
if (eb->app)
{
n = 2;
eb->cursor[0].saved = 0;
eb->cursor[0].unset = 1;
eb->cursor[0].can_save = 1;
eb->cursor[0].d = DIRN_UNSET;
eb->cursor[1].saved = 0;
eb->cursor[1].unset = 1;
eb->cursor[1].can_save = 1;
eb->cursor[1].d = DIRN_UNSET;
eb->cursor[2].saved = 0;
eb->cursor[2].unset = 1;
eb->cursor[2].can_save = 1;
eb->cursor[2].d = DIRN_UNSET;
}
eb->n = n;
eb->super.fns.insert = index_edgebuffer_insert;
return 1;
}
static void mark_line(fz_context *ctx, fz_edgebuffer *eb, fixed sx, fixed sy, fixed ex, fixed ey)
{
int base_y = eb->super.clip.y0;
int height = eb->super.clip.y1 - eb->super.clip.y0;
int *table = eb->table;
int *index = eb->index;
int delta;
int iy, ih;
fixed clip_sy, clip_ey;
int dirn = DIRN_UP;
int *row;
if (fixed2int(sy + fixed_half-1) == fixed2int(ey + fixed_half-1))
return;
if (sy > ey) {
int t;
t = sy; sy = ey; ey = t;
t = sx; sx = ex; ex = t;
dirn = DIRN_DOWN;
}
if (fixed2int(sx) < eb->super.bbox.x0)
eb->super.bbox.x0 = fixed2int(sx);
if (fixed2int(sx + fixed_1 - 1) > eb->super.bbox.x1)
eb->super.bbox.x1 = fixed2int(sx + fixed_1 - 1);
if (fixed2int(ex) < eb->super.bbox.x0)
eb->super.bbox.x0 = fixed2int(ex);
if (fixed2int(ex + fixed_1 - 1) > eb->super.bbox.x1)
eb->super.bbox.x1 = fixed2int(ex + fixed_1 - 1);
if (fixed2int(sy) < eb->super.bbox.y0)
eb->super.bbox.y0 = fixed2int(sy);
if (fixed2int(ey + fixed_1 - 1) > eb->super.bbox.y1)
eb->super.bbox.y1 = fixed2int(ey + fixed_1 - 1);
/* Lines go from sy to ey, closed at the start, open at the end. */
/* We clip them to a region to make them closed at both ends. */
/* Thus the unset scanline marked (>= sy) is: */
clip_sy = ((sy + fixed_half - 1) & ~(fixed_1-1)) | fixed_half;
/* The last scanline marked (< ey) is: */
clip_ey = ((ey - fixed_half - 1) & ~(fixed_1-1)) | fixed_half;
/* Now allow for banding */
if (clip_sy < int2fixed(base_y) + fixed_half)
clip_sy = int2fixed(base_y) + fixed_half;
if (ey <= clip_sy)
return;
if (clip_ey > int2fixed(base_y + height - 1) + fixed_half)
clip_ey = int2fixed(base_y + height - 1) + fixed_half;
if (sy > clip_ey)
return;
delta = clip_sy - sy;
if (delta > 0)
{
int dx = ex - sx;
int dy = ey - sy;
int advance = (int)(((int64_t)dx * delta + (dy>>1)) / dy);
sx += advance;
sy += delta;
}
ex -= sx;
ey -= sy;
clip_ey -= clip_sy;
delta = ey - clip_ey;
if (delta > 0)
{
int advance = (int)(((int64_t)ex * delta + (ey>>1)) / ey);
ex -= advance;
ey -= delta;
}
ih = fixed2int(ey);
assert(ih >= 0);
iy = fixed2int(sy) - base_y;
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
fz_write_printf(ctx, fz_stderr(ctx), " iy=%x ih=%x\n", iy, ih);
#endif
assert(iy >= 0 && iy < height);
/* We always cross at least one scanline */
row = &table[index[iy]];
*row = (*row)+1; /* Increment the count */
row[*row] = (sx&~1) | dirn;
if (ih == 0)
return;
if (ex >= 0) {
int x_inc, n_inc, f;
/* We want to change sx by ex in ih steps. So each step, we add
* ex/ih to sx. That's x_inc + n_inc/ih.
*/
x_inc = ex/ih;
n_inc = ex-(x_inc*ih);
f = ih>>1;
delta = ih;
do {
int count;
iy++;
sx += x_inc;
f -= n_inc;
if (f < 0) {
f += ih;
sx++;
}
assert(iy >= 0 && iy < height);
row = &table[index[iy]];
count = *row = (*row)+1; /* Increment the count */
row[count] = (sx&~1) | dirn;
} while (--delta);
} else {
int x_dec, n_dec, f;
ex = -ex;
/* We want to change sx by ex in ih steps. So each step, we subtract
* ex/ih from sx. That's x_dec + n_dec/ih.
*/
x_dec = ex/ih;
n_dec = ex-(x_dec*ih);
f = ih>>1;
delta = ih;
do {
int count;
iy++;
sx -= x_dec;
f -= n_dec;
if (f < 0) {
f += ih;
sx--;
}
assert(iy >= 0 && iy < height);
row = &table[index[iy]];
count = *row = (*row)+1; /* Increment the count */
row[count] = (sx&~1) | dirn;
} while (--delta);
}
}
static void fz_insert_edgebuffer(fz_context *ctx, fz_rasterizer *ras, float fsx, float fsy, float fex, float fey, int rev)
{
fz_edgebuffer *eb = (fz_edgebuffer *)ras;
fixed sx = float2fixed(fsx);
fixed sy = float2fixed(fsy);
fixed ex = float2fixed(fex);
fixed ey = float2fixed(fey);
mark_line(ctx, eb, sx, sy, ex, ey);
}
static inline void
cursor_output(fz_edgebuffer * FZ_RESTRICT eb, int rev, int iy)
{
int *row;
int count;
int height = eb->super.clip.y1 - eb->super.clip.y0;
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
rev &= 1; /* Edge label 0 is forwards, 1 and 2 are reverse */
if (iy >= 0 && iy < height) {
if (cr->can_save) {
/* Save it for later in case we join up */
cr->save_left = cr->left;
cr->save_right = cr->right;
cr->save_iy = iy;
cr->save_d = cr->d;
cr->saved = 1;
} else {
/* Enter it into the table */
row = &eb->table[eb->index[iy]];
if (cr->d == DIRN_UNSET)
{
/* Move 0 0; line 10 0; line 0 0; */
/* FIXME */
}
else
{
*row = count = (*row)+1; /* Increment the count */
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
fprintf(stderr, "row: %x: %x->%x %c\n", iy, cr->left, cr->right, (cr->d^rev) == DIRN_UP ? '^' : (cr->d^rev) == DIRN_DOWN ? 'v' : '-');
#endif
assert(count <= (eb->index[iy+1] - eb->index[iy] - 1)/2);
row[2 * count - 1] = (cr->left&~1) | (cr->d ^ rev);
row[2 * count] = cr->right;
}
}
}
cr->can_save = 0;
}
static inline void
cursor_output_inrange(fz_edgebuffer * FZ_RESTRICT eb, int rev, int iy)
{
int *row;
int count;
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
rev &= 1; /* Edge label 0 is forwards, 1 and 2 are reverse */
assert(iy >= 0 && iy < eb->super.clip.y1 - eb->super.clip.y0);
if (cr->can_save) {
/* Save it for later in case we join up */
cr->save_left = cr->left;
cr->save_right = cr->right;
cr->save_iy = iy;
cr->save_d = cr->d;
cr->saved = 1;
} else {
/* Enter it into the table */
assert(cr->d != DIRN_UNSET);
row = &eb->table[eb->index[iy]];
*row = count = (*row)+1; /* Increment the count */
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
printf("row= %x: %x->%x %c\n", iy, cr->left, cr->right, (cr->d^rev) == DIRN_UP ? '^' : (cr->d^rev) == DIRN_DOWN ? 'v' : '-');
#endif
row[2 * count - 1] = (cr->left&~1) | (cr->d ^ rev);
row[2 * count] = cr->right;
}
cr->can_save = 0;
}
/* Step the cursor in y, allowing for maybe crossing a scanline */
static inline void
cursor_step(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int new_iy;
int base = eb->super.clip.y0;
int iy = fixed2int(cr->y) - base;
cr->y += dy;
new_iy = fixed2int(cr->y) - base;
if (new_iy != iy) {
cursor_output(eb, rev, iy);
cr->left = x;
cr->right = x;
} else {
if (x < cr->left)
cr->left = x;
if (x > cr->right)
cr->right = x;
}
}
/* Step the cursor in y, never by enough to cross a scanline. */
static inline void
cursor_never_step_vertical(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
assert(fixed2int(cr->y+dy) == fixed2int(cr->y));
cr->y += dy;
}
/* Step the cursor in y, never by enough to cross a scanline,
* knowing that we are moving left, and that the right edge
* has already been accounted for. */
static inline void
cursor_never_step_left(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
assert(fixed2int(cr->y+dy) == fixed2int(cr->y));
if (x < cr->left)
cr->left = x;
cr->y += dy;
}
/* Step the cursor in y, never by enough to cross a scanline,
* knowing that we are moving right, and that the left edge
* has already been accounted for. */
static inline void
cursor_never_step_right(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
assert(fixed2int(cr->y+dy) == fixed2int(cr->y));
if (x > cr->right)
cr->right = x;
cr->y += dy;
}
/* Step the cursor in y, always by enough to cross a scanline. */
static inline void
cursor_always_step(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int base = eb->super.clip.y0;
int iy = fixed2int(cr->y) - base;
cursor_output(eb, rev, iy);
cr->y += dy;
cr->left = x;
cr->right = x;
}
/* Step the cursor in y, always by enough to cross a scanline, as
* part of a vertical line, knowing that we are moving from a
* position guaranteed to be in the valid y range. */
static inline void
cursor_always_step_inrange_vertical(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int base = eb->super.clip.y0;
int iy = fixed2int(cr->y) - base;
cursor_output(eb, rev, iy);
cr->y += dy;
}
/* Step the cursor in y, always by enough to cross a scanline, as
* part of a left moving line, knowing that we are moving from a
* position guaranteed to be in the valid y range. */
static inline void
cursor_always_inrange_step_left(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int base = eb->super.clip.y0;
int iy = fixed2int(cr->y) - base;
cr->y += dy;
cursor_output_inrange(eb, rev, iy);
cr->right = x;
}
/* Step the cursor in y, always by enough to cross a scanline, as
* part of a right moving line, knowing that we are moving from a
* position guaranteed to be in the valid y range. */
static inline void
cursor_always_inrange_step_right(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed dy, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int base = eb->super.clip.y0;
int iy = fixed2int(cr->y) - base;
cr->y += dy;
cursor_output_inrange(eb, rev, iy);
cr->left = x;
}
static inline void cursor_init(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed y, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
assert(y >= int2fixed(eb->super.clip.y0) && y <= int2fixed(eb->super.clip.y1));
cr->y = y;
cr->left = x;
cr->right = x;
cr->d = DIRN_UNSET;
}
static inline void cursor_left_merge(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
if (x < cr->left)
cr->left = x;
}
static inline void cursor_left(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
cr->left = x;
}
static inline void cursor_right_merge(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
if (x > cr->right)
cr->right = x;
}
static inline void cursor_right(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
cr->right = x;
}
static inline void cursor_down(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int base = eb->super.clip.y0;
if (cr->d == DIRN_UP)
{
cursor_output(eb, rev, fixed2int(cr->y) - base);
cr->left = x;
cr->right = x;
}
cr->d = DIRN_DOWN;
}
static inline void cursor_up(fz_edgebuffer * FZ_RESTRICT eb, int rev, fixed x)
{
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
int base = eb->super.clip.y0;
if (cr->d == DIRN_DOWN)
{
cursor_output(eb, rev, fixed2int(cr->y) - base);
cr->left = x;
cr->right = x;
}
cr->d = DIRN_UP;
}
static inline int dirns_match(int d0, int d1)
{
return d0 == d1 || d0 == DIRN_UNSET || d1 == DIRN_UNSET;
}
static inline int dirn_flip(int d)
{
return d < 0 ? d : d^1;
}
static inline int dirns_merge(int d0, int d1)
{
if (d0 == DIRN_UNSET)
return d1;
assert(dirns_match(d0, d1));
return d0;
}
static void
cursor_flush(fz_edgebuffer * FZ_RESTRICT eb)
{
int base = eb->super.clip.y0;
int iy0, iy1, iy2;
cursor_t * FZ_RESTRICT cr0 = &eb->cursor[0];
cursor_t * FZ_RESTRICT cr1 = &eb->cursor[1];
cursor_t * FZ_RESTRICT cr2 = &eb->cursor[2];
if (cr0->unset)
{
assert(cr1->unset && cr2->unset);
return;
}
iy0 = fixed2int(cr0->y) - base;
iy1 = fixed2int(cr1->y) - base;
if (!cr2->unset)
{
assert(!cr1->unset);
iy2 = fixed2int(cr2->y) - base;
/* Try to merge the end of cursor 0 with the end of cursor 1 */
if (iy0 == iy1 && dirns_match(cr0->d, dirn_flip(cr1->d)))
{
/* Succeeded! Just one to output. */
cr0->d = dirns_merge(cr0->d, dirn_flip(cr1->d));
if (cr0->left > cr1->left)
cr0->left = cr1->left;
if (cr0->right < cr1->right)
cr0->right = cr1->right;
cr1->unset = 1; /* Stop us outputting cursor 1 later */
}
/* Try to merge the end of cursor 2 with the start of cursor 0 */
if (cr0->saved)
{
if (cr0->save_iy == iy2 && dirns_match(cr0->save_d, cr2->d))
{
cr0->save_d = dirns_merge(cr0->save_d, cr2->d);
if (cr0->save_left > cr2->left)
cr0->save_left = cr2->left;
if (cr0->save_right > cr2->right)
cr0->save_right = cr2->right;
cr2->unset = 1; /* Stop us outputting cursor 2 later */
}
}
else
{
/* Maybe cursor 0 never moved from the original pixel */
if (iy0 == iy2 && dirns_match(cr0->d, cr2->d))
{
cr0->d = dirns_merge(cr0->d, cr2->d);
if (cr0->left > cr2->left)
cr0->left = cr2->left;
if (cr0->right > cr2->right)
cr0->right = cr2->right;
cr2->unset = 1; /* Stop us outputting cursor 2 later */
}
}
/* Try to merge the start of cursor 2 with the start of cursor 1 */
if (cr1->saved)
{
if (cr2->saved)
{
if (cr2->save_iy == cr1->save_iy && dirns_match(cr2->save_d, dirn_flip(cr1->save_d)))
{
cr2->save_d = dirns_merge(cr2->save_d, dirn_flip(cr1->save_d));
if (cr2->save_left > cr1->save_left)
cr2->save_left = cr1->save_left;
if (cr2->save_right > cr1->save_right)
cr2->save_right = cr1->save_right;
cr1->saved = 0; /* Don't output cr1->saved again later */
}
}
else if (!cr2->unset)
{
/* Maybe cursor 2 never moved from the original pixel */
if (iy2 == cr1->save_iy && dirns_match(cr2->d, dirn_flip(cr1->save_d)))
{
cr2->d = dirns_merge(cr2->d, dirn_flip(cr1->save_d));
if (cr2->left > cr1->save_left)
cr2->left = cr1->save_left;
if (cr2->right > cr1->save_right)
cr2->right = cr1->save_right;
cr1->saved = 0; /* Don't output cr1->saved again later */
}
}
}
else if (!cr1->unset)
{
/* Cursor 1 might not have moved from the original pixel, hence nothing saved */
if (cr2->saved)
{
if (cr2->save_iy == iy1 && dirns_match(cr2->save_d, dirn_flip(cr1->d)))
{
cr2->save_d = dirns_merge(cr2->save_d, dirn_flip(cr1->d));
if (cr2->save_left > cr1->left)
cr2->save_left = cr1->left;
if (cr2->save_right > cr1->right)
cr2->save_right = cr1->right;
cr1->unset = 1; /* Stop us outputting cursor 1 later */
}
}
else if (!cr2->unset)
{
/* Maybe cursor 2 never moved from the original pixel */
if (iy2 == iy1 && dirns_match(cr2->d, dirn_flip(cr1->d)))
{
cr2->d = dirns_merge(cr2->d, dirn_flip(cr1->d));
if (cr2->left > cr1->left)
cr2->left = cr1->left;
if (cr2->right > cr1->right)
cr2->right = cr1->right;
cr1->unset = 1; /* Stop us outputting cursor 1 later */
}
}
}
else
{
/* Cursor 1 might not have moved from the original pixel, hence nothing saved,
* AND we might have merged it with cursor 0 already! */
if (cr2->saved)
{
if (iy0 == cr2->save_iy && dirns_match(cr0->d, cr2->save_d))
{
cr0->d = dirns_merge(cr0->d, cr2->save_d);
if (cr0->left > cr2->save_left)
cr0->left = cr2->save_left;
if (cr0->right > cr2->save_right)
cr0->right = cr2->save_right;
cr2->saved = 0; /* Stop us outputting saved cursor 2 later */
}
}
else if (!cr2->unset)
{
/* Maybe cursor 2 never moved from the original pixel */
if (iy0 == iy2 && dirns_match(cr0->d, cr2->d))
{
cr0->d = dirns_merge(cr0->d, cr2->d);
if (cr0->left > cr2->left)
cr0->left = cr2->left;
if (cr0->right > cr2->right)
cr0->right = cr2->right;
cr2->unset = 1; /* Stop us outputting cursor 2 later */
}
}
}
}
else
{
/* Try to merge the end of cursor 0 with the start of cursor 0 */
if (cr0->saved)
{
if (iy0 == cr0->save_iy && dirns_match(cr0->d, cr0->save_d))
{
cr0->d = dirns_merge(cr0->d, cr0->save_d);
if (cr0->left > cr0->save_left)
cr0->left = cr0->save_left;
if (cr0->right > cr0->save_right)
cr0->right = cr0->save_right;
cr0->saved = 0; /* Stop us outputting saved cursor 0 later */
}
}
if (!cr1->unset)
{
/* Try to merge the end of cursor 1 with the start of cursor 1 */
if (cr1->saved)
{
if (iy1 == cr1->save_iy && dirns_match(cr1->d, cr1->save_d))
{
cr1->d = dirns_merge(cr1->d, cr1->save_d);
if (cr1->left > cr1->save_left)
cr1->left = cr1->save_left;
if (cr1->right > cr1->save_right)
cr1->right = cr1->save_right;
cr1->saved = 0; /* Stop us outputting saved cursor 1 later */
}
}
}
}
if (!cr0->unset)
cursor_output(eb, 0, iy0);
if (cr0->saved)
{
cr0->left = cr0->save_left;
cr0->right = cr0->save_right;
cr0->d = cr0->save_d;
cursor_output(eb, 0, cr0->save_iy);
}
if (!cr1->unset)
cursor_output(eb, 1, iy1);
if (cr1->saved)
{
cr1->left = cr1->save_left;
cr1->right = cr1->save_right;
cr1->d = cr1->save_d;
cursor_output(eb, 1, cr1->save_iy);
}
if (!cr2->unset)
cursor_output(eb, 2, iy2);
if (cr2->saved)
{
cr2->left = cr2->save_left;
cr2->right = cr2->save_right;
cr2->d = cr2->save_d;
cursor_output(eb, 2, cr2->save_iy);
}
}
static void do_mark_line_app(fz_context *ctx, fz_edgebuffer *eb, fixed sx, fixed sy, fixed ex, fixed ey, int rev)
{
int base_y = eb->super.clip.y0;
int height = eb->super.clip.y1 - eb->super.clip.y0;
int isy, iey;
fixed y_steps;
fixed save_sy = sy;
fixed save_ex = ex;
fixed save_ey = ey;
int truncated;
cursor_t * FZ_RESTRICT cr = &eb->cursor[rev];
if (cr->unset)
cr->y = sy, cr->left = sx, cr->right = sx, cr->unset = 0;
/* Floating point inaccuracies can cause these not *quite* to be true. */
assert(cr->y == sy && cr->left <= sx && cr->right >= sx && cr->d >= DIRN_UNSET && cr->d <= DIRN_DOWN);
sy = cr->y;
if (cr->left > sx)
sx = cr->left;
else if (cr->right < sx)
sx = cr->right;
if (sx == ex && sy == ey)
return;
isy = fixed2int(sy) - base_y;
iey = fixed2int(ey) - base_y;
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
fz_write_printf(ctx, fz_stderr(ctx), "Marking line (app) from %x,%x to %x,%x (%x,%x) %d\n", sx, sy, ex, ey, isy, iey, rev);
#endif
if (isy < iey) {
/* Rising line */
if (iey < 0 || isy >= height) {
/* All line is outside. */
cr->y = ey;
cr->left = ex;
cr->right = ex;
cr->can_save = 0;
return;
}
if (isy < 0) {
/* Move sy up */
int y = ey - sy;
int new_sy = int2fixed(base_y);
int dy = new_sy - sy;
sx += (int)((((int64_t)(ex-sx))*dy + y/2)/y);
sy = new_sy;
cursor_init(eb, rev, sy, sx);
isy = 0;
}
truncated = iey > height;
if (truncated) {
/* Move ey down */
int y = ey - sy;
int new_ey = int2fixed(base_y + height);
int dy = ey - new_ey;
save_ex = ex;
save_ey = ey;
ex -= (int)((((int64_t)(ex-sx))*dy + y/2)/y);
ey = new_ey;
iey = height;
}
} else {
/* Falling line */
if (isy < 0 || iey >= height) {
/* All line is outside. */
cr->y = ey;
cr->left = ex;
cr->right = ex;
cr->can_save = 0;
return;
}
truncated = iey < 0;
if (truncated) {
/* Move ey up */
int y = ey - sy;
int new_ey = int2fixed(base_y);
int dy = ey - new_ey;
ex -= (int)((((int64_t)(ex-sx))*dy + y/2)/y);
ey = new_ey;
iey = 0;
}
if (isy >= height) {
/* Move sy down */
int y = ey - sy;
if (y) {
int new_sy = int2fixed(base_y + height);
int dy = new_sy - sy;
sx += (int)((((int64_t)(ex-sx))*dy + y/2)/y);
sy = new_sy;
cursor_init(eb, rev, sy, sx);
isy = height;
}
}
}
assert(cr->left <= sx);
assert(cr->right >= sx);
assert(cr->y == sy);
/* A note: The code below used to be of the form:
* if (isy == iey) ... deal with horizontal lines
* else if (ey > sy) {
* fixed y_steps = ey - sy;
* ... deal with rising lines ...
* } else {
* fixed y_steps = ey - sy;
* ... deal with falling lines
* }
* but that lead to problems, for instance, an example seen
* has sx=2aa8e, sy=8aee7, ex=7ffc1686, ey=8003e97a.
* Thus isy=84f, iey=ff80038a. We can see that ey < sy, but
* sy - ey < 0!
* We therefore rejig our code so that the choice between
* cases is done based on the sign of y_steps rather than
* the relative size of ey and sy.
*/
/* First, deal with lines that don't change scanline.
* This accommodates horizontal lines. */
if (isy == iey) {
if (save_sy == save_ey) {
/* Horizontal line. Don't change cr->d, don't flush. */
} else if (save_sy > save_ey) {
/* Falling line, flush if previous was rising */
cursor_down(eb, rev, sx);
} else {
/* Rising line, flush if previous was falling */
cursor_up(eb, rev, sx);
}
if (sx <= ex) {
cursor_left_merge(eb, rev, sx);
cursor_right_merge(eb, rev, ex);
} else {
cursor_left_merge(eb, rev, ex);
cursor_right_merge(eb, rev, sx);
}
cr->y = ey;
if (sy > save_ey)
goto endFalling;
} else if ((y_steps = ey - sy) > 0) {
/* We want to change from sy to ey, which are guaranteed to be on
* different scanlines. We do this in 3 phases.
* Phase 1 gets us from sy to the next scanline boundary.
* Phase 2 gets us all the way to the last scanline boundary.
* Phase 3 gets us from the last scanline boundary to ey.
*/
/* We want to change from sy to ey, which are guaranteed to be on
* different scanlines. We do this in 3 phases.
* Phase 1 gets us from sy to the next scanline boundary. (We may exit after phase 1).
* Phase 2 gets us all the way to the last scanline boundary. (This may be a null operation)
* Phase 3 gets us from the last scanline boundary to ey. (We are guaranteed to have output the cursor at least once before phase 3).
*/
int phase1_y_steps = (-sy) & (fixed_1 - 1);
int phase3_y_steps = ey & (fixed_1 - 1);
cursor_up(eb, rev, sx);
if (sx == ex) {
/* Vertical line. (Rising) */
/* Phase 1: */
cursor_left_merge(eb, rev, sx);
cursor_right_merge(eb, rev, sx);
if (phase1_y_steps) {
/* If phase 1 will move us into a new scanline, then we must
* flush it before we move. */
cursor_step(eb, rev, phase1_y_steps, sx);
sy += phase1_y_steps;
y_steps -= phase1_y_steps;
if (y_steps == 0)
goto end;
}
/* Phase 3: precalculation */
y_steps -= phase3_y_steps;
/* Phase 2: */
y_steps = fixed2int(y_steps);
assert(y_steps >= 0);
if (y_steps > 0) {
cursor_always_step(eb, rev, fixed_1, sx);
y_steps--;
while (y_steps) {
cursor_always_step_inrange_vertical(eb, rev, fixed_1, sx);
y_steps--;
}
}
/* Phase 3 */
assert(cr->left == sx && cr->right == sx);
cr->y += phase3_y_steps;
} else if (sx < ex) {
/* Lines increasing in x. (Rightwards, rising) */
int phase1_x_steps, phase3_x_steps;
fixed x_steps = ex - sx;
/* Phase 1: */
cursor_left_merge(eb, rev, sx);
if (phase1_y_steps) {
phase1_x_steps = (int)(((int64_t)x_steps * phase1_y_steps + y_steps/2) / y_steps);
sx += phase1_x_steps;
cursor_right_merge(eb, rev, sx);
x_steps -= phase1_x_steps;
cursor_step(eb, rev, phase1_y_steps, sx);
sy += phase1_y_steps;
y_steps -= phase1_y_steps;
if (y_steps == 0)
goto end;
}
/* Phase 3: precalculation */
phase3_x_steps = (int)(((int64_t)x_steps * phase3_y_steps + y_steps/2) / y_steps);
x_steps -= phase3_x_steps;
y_steps -= phase3_y_steps;
assert((y_steps & (fixed_1 - 1)) == 0);
/* Phase 2: */
y_steps = fixed2int(y_steps);
assert(y_steps >= 0);
if (y_steps) {
/* We want to change sx by x_steps in y_steps steps.
* So each step, we add x_steps/y_steps to sx. That's x_inc + n_inc/y_steps. */
int x_inc = x_steps/y_steps;
int n_inc = x_steps - (x_inc * y_steps);
int f = y_steps/2;
int d = y_steps;
/* Special casing the unset iteration, allows us to simplify
* the following loop. */
sx += x_inc;
f -= n_inc;
if (f < 0)
f += d, sx++;
cursor_right_merge(eb, rev, sx);
cursor_always_step(eb, rev, fixed_1, sx);
y_steps--;
while (y_steps) {
sx += x_inc;
f -= n_inc;
if (f < 0)
f += d, sx++;
cursor_right(eb, rev, sx);
cursor_always_inrange_step_right(eb, rev, fixed_1, sx);
y_steps--;
};
}
/* Phase 3 */
assert(cr->left <= ex && cr->right >= sx);
cursor_right(eb, rev, ex);
cr->y += phase3_y_steps;
} else {
/* Lines decreasing in x. (Leftwards, rising) */
int phase1_x_steps, phase3_x_steps;
fixed x_steps = sx - ex;
/* Phase 1: */
cursor_right_merge(eb, rev, sx);
if (phase1_y_steps) {
phase1_x_steps = (int)(((int64_t)x_steps * phase1_y_steps + y_steps/2) / y_steps);
x_steps -= phase1_x_steps;
sx -= phase1_x_steps;
cursor_left_merge(eb, rev, sx);
cursor_step(eb, rev, phase1_y_steps, sx);
sy += phase1_y_steps;
y_steps -= phase1_y_steps;
if (y_steps == 0)
goto end;
}
/* Phase 3: precalculation */
phase3_x_steps = (int)(((int64_t)x_steps * phase3_y_steps + y_steps/2) / y_steps);
x_steps -= phase3_x_steps;
y_steps -= phase3_y_steps;
assert((y_steps & (fixed_1 - 1)) == 0);
/* Phase 2: */
y_steps = fixed2int(y_steps);
assert(y_steps >= 0);
if (y_steps) {
/* We want to change sx by x_steps in y_steps steps.
* So each step, we sub x_steps/y_steps from sx. That's x_inc + n_inc/ey. */
int x_inc = x_steps/y_steps;
int n_inc = x_steps - (x_inc * y_steps);
int f = y_steps/2;
int d = y_steps;
/* Special casing the unset iteration, allows us to simplify
* the following loop. */
sx -= x_inc;
f -= n_inc;
if (f < 0)
f += d, sx--;
cursor_left_merge(eb, rev, sx);
cursor_always_step(eb, rev, fixed_1, sx);
y_steps--;
while (y_steps) {
sx -= x_inc;
f -= n_inc;
if (f < 0)
f += d, sx--;
cursor_left(eb, rev, sx);
cursor_always_inrange_step_left(eb, rev, fixed_1, sx);
y_steps--;
}
}
/* Phase 3 */
assert(cr->right >= ex && cr->left <= sx);
cursor_left(eb, rev, ex);
cr->y += phase3_y_steps;
}
} else {
/* So lines decreasing in y. */
/* We want to change from sy to ey, which are guaranteed to be on
* different scanlines. We do this in 3 phases.
* Phase 1 gets us from sy to the next scanline boundary. This never causes an output.
* Phase 2 gets us all the way to the last scanline boundary. This is guaranteed to cause an output.
* Phase 3 gets us from the last scanline boundary to ey. We are guaranteed to have outputted by now.
*/
int phase1_y_steps = sy & (fixed_1 - 1);
int phase3_y_steps = (-ey) & (fixed_1 - 1);
y_steps = -y_steps;
/* Cope with the awkward 0x80000000 case. */
if (y_steps < 0)
{
int mx, my;
mx = sx + ((ex-sx)>>1);
my = sy + ((ey-sy)>>1);
do_mark_line_app(ctx, eb, sx, sy, mx, my, rev);
do_mark_line_app(ctx, eb, mx, my, ex, ey, rev);
return;
}
cursor_down(eb, rev, sx);
if (sx == ex) {
/* Vertical line. (Falling) */
/* Phase 1: */
cursor_left_merge(eb, rev, sx);
cursor_right_merge(eb, rev, sx);
if (phase1_y_steps) {
/* Phase 1 in a falling line never moves us into a new scanline. */
cursor_never_step_vertical(eb, rev, -phase1_y_steps, sx);
sy -= phase1_y_steps;
y_steps -= phase1_y_steps;
if (y_steps == 0)
goto endFalling;
}
/* Phase 3: precalculation */
y_steps -= phase3_y_steps;
assert((y_steps & (fixed_1 - 1)) == 0);
/* Phase 2: */
y_steps = fixed2int(y_steps);
assert(y_steps >= 0);
if (y_steps) {
cursor_always_step(eb, rev, -fixed_1, sx);
y_steps--;
while (y_steps) {
cursor_always_step_inrange_vertical(eb, rev, -fixed_1, sx);
y_steps--;
}
}
/* Phase 3 */
if (phase3_y_steps > 0) {
cursor_step(eb, rev, -phase3_y_steps, sx);
assert(cr->left == sx && cr->right == sx);
}
} else if (sx < ex) {
/* Lines increasing in x. (Rightwards, falling) */
int phase1_x_steps, phase3_x_steps;
fixed x_steps = ex - sx;
/* Phase 1: */
cursor_left_merge(eb, rev, sx);
if (phase1_y_steps) {
phase1_x_steps = (int)(((int64_t)x_steps * phase1_y_steps + y_steps/2) / y_steps);
x_steps -= phase1_x_steps;
sx += phase1_x_steps;
/* Phase 1 in a falling line never moves us into a new scanline. */
cursor_never_step_right(eb, rev, -phase1_y_steps, sx);
sy -= phase1_y_steps;
y_steps -= phase1_y_steps;
if (y_steps == 0)
goto endFalling;
} else
cursor_right_merge(eb, rev, sx);
/* Phase 3: precalculation */
phase3_x_steps = (int)(((int64_t)x_steps * phase3_y_steps + y_steps/2) / y_steps);
x_steps -= phase3_x_steps;
y_steps -= phase3_y_steps;
assert((y_steps & (fixed_1 - 1)) == 0);
/* Phase 2: */
y_steps = fixed2int(y_steps);
assert(y_steps >= 0);
if (y_steps) {
/* We want to change sx by x_steps in y_steps steps.
* So each step, we add x_steps/y_steps to sx. That's x_inc + n_inc/ey. */
int x_inc = x_steps/y_steps;
int n_inc = x_steps - (x_inc * y_steps);
int f = y_steps/2;
int d = y_steps;
cursor_always_step(eb, rev, -fixed_1, sx);
sx += x_inc;
f -= n_inc;
if (f < 0)
f += d, sx++;
cursor_right(eb, rev, sx);
y_steps--;
while (y_steps) {
cursor_always_inrange_step_right(eb, rev, -fixed_1, sx);
sx += x_inc;
f -= n_inc;
if (f < 0)
f += d, sx++;
cursor_right(eb, rev, sx);
y_steps--;
}
}
/* Phase 3 */
if (phase3_y_steps > 0) {
cursor_step(eb, rev, -phase3_y_steps, sx);
cursor_right(eb, rev, ex);
assert(cr->left == sx && cr->right == ex);
}
} else {
/* Lines decreasing in x. (Falling) */
int phase1_x_steps, phase3_x_steps;
fixed x_steps = sx - ex;
/* Phase 1: */
cursor_right_merge(eb, rev, sx);
if (phase1_y_steps) {
phase1_x_steps = (int)(((int64_t)x_steps * phase1_y_steps + y_steps/2) / y_steps);
x_steps -= phase1_x_steps;
sx -= phase1_x_steps;
/* Phase 1 in a falling line never moves us into a new scanline. */
cursor_never_step_left(eb, rev, -phase1_y_steps, sx);
sy -= phase1_y_steps;
y_steps -= phase1_y_steps;
if (y_steps == 0)
goto endFalling;
} else
cursor_left_merge(eb, rev, sx);
/* Phase 3: precalculation */
phase3_x_steps = (int)(((int64_t)x_steps * phase3_y_steps + y_steps/2) / y_steps);
x_steps -= phase3_x_steps;
y_steps -= phase3_y_steps;
assert((y_steps & (fixed_1 - 1)) == 0);
/* Phase 2: */
y_steps = fixed2int(y_steps);
assert(y_steps >= 0);
if (y_steps) {
/* We want to change sx by x_steps in y_steps steps.
* So each step, we sub x_steps/y_steps from sx. That's x_inc + n_inc/ey. */
int x_inc = x_steps/y_steps;
int n_inc = x_steps - (x_inc * y_steps);
int f = y_steps/2;
int d = y_steps;
cursor_always_step(eb, rev, -fixed_1, sx);
sx -= x_inc;
f -= n_inc;
if (f < 0)
f += d, sx--;
cursor_left(eb, rev, sx);
y_steps--;
while (y_steps) {
cursor_always_inrange_step_left(eb, rev, -fixed_1, sx);
sx -= x_inc;
f -= n_inc;
if (f < 0)
f += d, sx--;
cursor_left(eb, rev, sx);
y_steps--;
}
}
/* Phase 3 */
if (phase3_y_steps > 0) {
cursor_step(eb, rev, -phase3_y_steps, sx);
cursor_left(eb, rev, ex);
assert(cr->left == ex && cr->right == sx);
}
}
endFalling:
if (truncated)
cursor_output(eb, rev, fixed2int(cr->y) - base_y);
}
end:
if (truncated) {
cr->left = save_ex;
cr->right = save_ex;
cr->y = save_ey;
}
}
static void mark_line_app(fz_context *ctx, fz_edgebuffer *eb, fixed sx, fixed sy, fixed ex, fixed ey, int rev)
{
if (rev == 1)
{
fixed t;
t = sx, sx = ex, ex = t;
t = sy, sy = ey, ey = t;
}
do_mark_line_app(ctx, eb, sx, sy, ex, ey, rev);
}
static void fz_insert_edgebuffer_app(fz_context *ctx, fz_rasterizer *ras, float fsx, float fsy, float fex, float fey, int rev)
{
fz_edgebuffer *eb = (fz_edgebuffer *)ras;
fixed sx = float2fixed(fsx);
fixed sy = float2fixed(fsy);
fixed ex = float2fixed(fex);
fixed ey = float2fixed(fey);
if (fsx < fex)
{
if (fsx < eb->super.bbox.x0) eb->super.bbox.x0 = fsx;
if (fex > eb->super.bbox.x1) eb->super.bbox.x1 = fex;
}
else
{
if (fsx > eb->super.bbox.x1) eb->super.bbox.x1 = fsx;
if (fex < eb->super.bbox.x0) eb->super.bbox.x0 = fex;
}
if (fsy < fey)
{
if (fsy < eb->super.bbox.y0) eb->super.bbox.y0 = fsy;
if (fey > eb->super.bbox.y1) eb->super.bbox.y1 = fey;
}
else
{
if (fey < eb->super.bbox.y0) eb->super.bbox.y0 = fey;
if (fsy > eb->super.bbox.y1) eb->super.bbox.y1 = fsy;
}
mark_line_app(ctx, eb, sx, sy, ex, ey, rev);
}
static int intcmp(const void *a, const void *b)
{
return *((int*)a) - *((int *)b);
}
static void fz_convert_edgebuffer(fz_context *ctx, fz_rasterizer *ras, int eofill, const fz_irect *clip, fz_pixmap *pix, unsigned char *color, fz_overprint *eop)
{
fz_edgebuffer *eb = (fz_edgebuffer *)ras;
int scanlines = ras->clip.y1 - ras->clip.y0;
int i, n, a, pl, pr;
int *table = eb->table;
int *index = eb->index;
uint8_t *out;
fz_solid_color_painter_t *fn;
fn = fz_get_solid_color_painter(pix->n, color, pix->alpha, eop);
assert(fn);
if (fn == NULL)
return;
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, err, "Before sort:\n");
fz_edgebuffer_print(ctx, err, eb);
}
#endif
if (!eb->sorted)
{
eb->sorted = 1;
for (i = 0; i < scanlines; i++)
{
int *row = &table[index[i]];
int rowlen = *row++;
/* Bubblesort short runs, qsort longer ones. */
/* FIXME: Check "6" below */
if (rowlen <= 6) {
int j, k;
for (j = 0; j < rowlen-1; j++)
{
int t = row[j];
for (k = j+1; k < rowlen; k++)
{
int s = row[k];
if (t > s)
row[k] = t, t = row[j] = s;
}
}
} else
qsort(row, rowlen, sizeof(int), intcmp);
}
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, err, "Before filter: %s\n", eofill ? "EO" : "NZ");
fz_edgebuffer_print(ctx, err, eb);
}
#endif
for (i=0; i < scanlines; i++) {
int *row = &table[index[i]];
int *rowstart = row;
int rowlen = *row++;
int *rowout = row;
while (rowlen > 0)
{
int left, right;
if (eofill) {
/* Even Odd */
left = (*row++)&~1;
right = (*row++)&~1;
rowlen -= 2;
} else {
/* Non-Zero */
int w;
left = *row++;
w = ((left&1)-1) | (left&1);
rowlen--;
do {
right = *row++;
rowlen--;
w += ((right&1)-1) | (right&1);
} while (w != 0);
left &= ~1;
right &= ~1;
}
if (right > left) {
*rowout++ = left;
*rowout++ = right;
}
}
*rowstart = (rowout-rowstart)-1;
}
}
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, err, "Before render:\n");
fz_edgebuffer_print(ctx, err, eb);
}
#endif
n = pix->n;
a = pix->alpha;
pl = fz_maxi(ras->clip.x0, pix->x);
pr = fz_mini(ras->clip.x1, pix->x + pix->w);
pr -= pl;
out = pix->samples + pix->stride * fz_maxi(ras->clip.y0 - pix->y, 0) + fz_maxi(ras->clip.x0 - pix->x, 0) * n;
if (scanlines > pix->y + pix->h - ras->clip.y0)
scanlines = pix->y + pix->h - ras->clip.y0;
for (i = fz_maxi(pix->y - ras->clip.y0, 0); i < scanlines; i++) {
int *row = &table[index[i]];
int rowlen = *row++;
while (rowlen > 0) {
int left, right;
left = *row++;
right = *row++;
rowlen -= 2;
left = fixed2int(left + fixed_half) - pl;
right = fixed2int(right + fixed_half) - pl;
if (right <= 0)
continue;
if (left >= pr)
continue;
if (right > pr)
right = pr;
if (left < 0)
left = 0;
right -= left;
if (right > 0) {
(*fn)(out + left*n, n, right, color, a, eop);
}
}
out += pix->stride;
}
}
static int edgecmp(const void *a, const void *b)
{
int left = ((int*)a)[0];
int right = ((int*)b)[0];
left -= right;
if (left)
return left;
return ((int*)a)[1] - ((int*)b)[1];
}
static void fz_convert_edgebuffer_app(fz_context *ctx, fz_rasterizer *ras, int eofill, const fz_irect *clip, fz_pixmap *pix, unsigned char *color, fz_overprint *eop)
{
fz_edgebuffer *eb = (fz_edgebuffer *)ras;
int scanlines = ras->clip.y1 - ras->clip.y0;
int i, n, a, pl, pr;
int *table = eb->table;
int *index = eb->index;
uint8_t *out;
fz_solid_color_painter_t *fn;
fn = fz_get_solid_color_painter(pix->n, color, pix->alpha, eop);
assert(fn);
if (fn == NULL)
return;
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, err, "Before sort:\n");
fz_edgebuffer_print_app(ctx, err, eb);
}
#endif
if (!eb->sorted)
{
eb->sorted = 1;
for (i = 0; i < scanlines; i++)
{
int *row = &table[index[i]];
int rowlen = *row++;
/* Bubblesort short runs, qsort longer ones. */
/* FIXME: Check "6" below */
if (rowlen <= 6) {
int j, k;
for (j = 0; j < rowlen-1; j++) {
int * FZ_RESTRICT t = &row[j<<1];
for (k = j+1; k < rowlen; k++) {
int * FZ_RESTRICT s = &row[k<<1];
int tmp;
if (t[0] < s[0])
continue;
if (t[0] > s[0])
tmp = t[0], t[0] = s[0], s[0] = tmp;
else if (t[0] <= s[1])
continue;
tmp = t[1]; t[1] = s[1]; s[1] = tmp;
}
}
} else
qsort(row, rowlen, 2*sizeof(int), edgecmp);
}
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, err, "Before filter: %s\n", eofill ? "EO" : "NZ");
fz_edgebuffer_print_app(ctx, err, eb);
}
#endif
for (i=0; i < scanlines; i++) {
int *row = &table[index[i]];
int rowlen = *row++;
int *rowstart = row;
int *rowout = row;
int ll, lr, rl, rr, wind, marked_to;
/* Avoid double setting pixels, by keeping where we have marked to. */
marked_to = int2fixed(clip->x0);
while (rowlen > 0) {
if (eofill) {
/* Even Odd */
ll = (*row++)&~1;
lr = *row;
row += 2;
rowlen-=2;
/* We will fill solidly from ll to at least lr, possibly further */
assert(rowlen >= 0);
rr = (*row++);
if (rr > lr)
lr = rr;
} else {
/* Non-Zero */
int w;
ll = *row++;
lr = *row++;
wind = -(ll&1) | 1;
ll &= ~1;
rowlen--;
assert(rowlen > 0);
do {
rl = *row++;
rr = *row++;
w = -(rl&1) | 1;
rl &= ~1;
rowlen--;
if (rr > lr)
lr = rr;
wind += w;
if (wind == 0)
break;
} while (rowlen > 0);
}
if (marked_to >= lr)
continue;
if (marked_to >= ll) {
if (rowout == rowstart)
ll = marked_to;
else {
rowout -= 2;
ll = *rowout;
}
}
if (lr > ll) {
*rowout++ = ll;
*rowout++ = lr;
marked_to = lr;
}
}
rowstart[-1] = rowout-rowstart;
}
}
#ifdef DEBUG_SCAN_CONVERTER
if (debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, err, "Before render:\n");
fz_edgebuffer_print_app(ctx, err, eb);
}
#endif
n = pix->n;
a = pix->alpha;
pl = clip->x0;
pr = clip->x1 - pl;
out = pix->samples + pix->stride * (clip->y0 - pix->y) + (clip->x0 - pix->x) * n;
if (scanlines > clip->y1 - ras->clip.y0)
scanlines = clip->y1 - ras->clip.y0;
i = (clip->y0 - ras->clip.y0);
if (i < 0)
return;
for (; i < scanlines; i++) {
int *row = &table[index[i]];
int rowlen = *row++;
while (rowlen > 0) {
int left, right;
left = *row++;
right = *row++;
rowlen -= 2;
left = fixed2int(left + fixed_half) - pl;
right = fixed2int(right + fixed_half) - pl;
if (right <= 0)
continue;
if (left >= pr)
break;
if (right > pr)
right = pr;
if (left < 0)
left = 0;
right -= left;
if (right > 0) {
(*fn)(out + left*n, n, right, color, a, eop);
}
}
out += pix->stride;
}
}
static void fz_gap_edgebuffer(fz_context *ctx, fz_rasterizer *ras)
{
fz_edgebuffer *eb = (fz_edgebuffer *)ras;
if (eb->app)
{
#ifdef DEBUG_SCAN_CONVERTER
if (0 && debugging_scan_converter)
{
fz_output *err = fz_stderr(ctx);
fz_write_printf(ctx, fz_stderr(ctx), "Pen up move.\n");
fz_write_printf(ctx, err, "Before flush:\n");
fz_edgebuffer_print_app(ctx, err, eb);
}
#endif
cursor_flush(eb);
eb->cursor[0].saved = 0;
eb->cursor[0].unset = 1;
eb->cursor[0].can_save = 1;
eb->cursor[0].d = DIRN_UNSET;
eb->cursor[1].saved = 0;
eb->cursor[1].unset = 1;
eb->cursor[1].can_save = 1;
eb->cursor[1].d = DIRN_UNSET;
eb->cursor[2].saved = 0;
eb->cursor[2].unset = 1;
eb->cursor[2].can_save = 1;
eb->cursor[2].d = DIRN_UNSET;
}
}
static int fz_is_rect_edgebuffer(fz_context *ctx, fz_rasterizer *r)
{
return 0;
}
static const fz_rasterizer_fns edgebuffer_app =
{
fz_drop_edgebuffer,
fz_reset_edgebuffer,
fz_postindex_edgebuffer,
fz_insert_edgebuffer_app,
NULL,
fz_gap_edgebuffer,
fz_convert_edgebuffer_app,
fz_is_rect_edgebuffer,
1 /* Reusable */
};
static const fz_rasterizer_fns edgebuffer_cop =
{
fz_drop_edgebuffer,
fz_reset_edgebuffer,
fz_postindex_edgebuffer,
fz_insert_edgebuffer,
NULL,
NULL, /* gap */
fz_convert_edgebuffer,
fz_is_rect_edgebuffer,
1 /* Reusable */
};
fz_rasterizer *
fz_new_edgebuffer(fz_context *ctx, fz_edgebuffer_rule rule)
{
fz_edgebuffer *eb;
eb = fz_new_derived_rasterizer(ctx, fz_edgebuffer, rule == FZ_EDGEBUFFER_ANY_PART_OF_PIXEL ? &edgebuffer_app : &edgebuffer_cop);
eb->app = rule == FZ_EDGEBUFFER_ANY_PART_OF_PIXEL;
return &eb->super;
}