#include #include "fitz-internal.h" fz_path * fz_new_path(fz_context *ctx) { fz_path *path; path = fz_malloc_struct(ctx, fz_path); path->len = 0; path->cap = 0; path->items = NULL; path->last = -1; return path; } fz_path * fz_clone_path(fz_context *ctx, fz_path *old) { fz_path *path; assert(old); path = fz_malloc_struct(ctx, fz_path); fz_try(ctx) { path->len = old->len; path->cap = old->len; path->items = fz_malloc_array(ctx, path->cap, sizeof(fz_path_item)); memcpy(path->items, old->items, sizeof(fz_path_item) * path->len); } fz_catch(ctx) { fz_free(ctx, path); fz_rethrow(ctx); } return path; } void fz_free_path(fz_context *ctx, fz_path *path) { if (path == NULL) return; fz_free(ctx, path->items); fz_free(ctx, path); } static void grow_path(fz_context *ctx, fz_path *path, int n) { int newcap = path->cap; if (path->len + n <= path->cap) { path->last = path->len; return; } while (path->len + n > newcap) newcap = newcap + 36; path->items = fz_resize_array(ctx, path->items, newcap, sizeof(fz_path_item)); path->cap = newcap; path->last = path->len; } fz_point fz_currentpoint(fz_context *ctx, fz_path *path) { fz_point c, m; int i; c.x = c.y = m.x = m.y = 0; i = 0; while (i < path->len) { switch (path->items[i++].k) { case FZ_MOVETO: m.x = c.x = path->items[i++].v; m.y = c.y = path->items[i++].v; break; case FZ_LINETO: c.x = path->items[i++].v; c.y = path->items[i++].v; break; case FZ_CURVETO: i += 4; c.x = path->items[i++].v; c.y = path->items[i++].v; break; case FZ_CLOSE_PATH: c = m; } } return c; } void fz_moveto(fz_context *ctx, fz_path *path, float x, float y) { if (path->last >= 0 && path->items[path->last].k == FZ_MOVETO) { /* No point in having MOVETO then MOVETO */ path->len = path->last; } grow_path(ctx, path, 3); path->items[path->len++].k = FZ_MOVETO; path->items[path->len++].v = x; path->items[path->len++].v = y; } void fz_lineto(fz_context *ctx, fz_path *path, float x, float y) { float x0, y0; if (path->last < 0) { fz_warn(ctx, "lineto with no current point"); return; } if (path->items[path->last].k == FZ_CLOSE_PATH) { x0 = path->items[path->last-2].v; y0 = path->items[path->last-1].v; } else { x0 = path->items[path->len-2].v; y0 = path->items[path->len-1].v; } /* Anything other than MoveTo followed by LineTo the same place is a nop */ if (path->items[path->last].k != FZ_MOVETO && x0 == x && y0 == y) return; grow_path(ctx, path, 3); path->items[path->len++].k = FZ_LINETO; path->items[path->len++].v = x; path->items[path->len++].v = y; } void fz_curveto(fz_context *ctx, fz_path *path, float x1, float y1, float x2, float y2, float x3, float y3) { float x0, y0; if (path->last < 0) { fz_warn(ctx, "curveto with no current point"); return; } if (path->items[path->last].k == FZ_CLOSE_PATH) { x0 = path->items[path->last-2].v; y0 = path->items[path->last-1].v; } else { x0 = path->items[path->len-2].v; y0 = path->items[path->len-1].v; } /* Check for degenerate cases: */ if (x0 == x1 && y0 == y1) { if (x2 == x3 && y2 == y3) { /* If (x1,y1)==(x2,y2) and prev wasn't a moveto, then skip */ if (x1 == x2 && y1 == y2 && path->items[path->last].k != FZ_MOVETO) return; /* Otherwise a line will suffice */ fz_lineto(ctx, path, x3, y3); return; } if (x1 == x2 && y1 == y2) { /* A line will suffice */ fz_lineto(ctx, path, x3, y3); return; } } else if (x1 == x2 && y1 == y2 && x2 == x3 && y2 == y3) { /* A line will suffice */ fz_lineto(ctx, path, x3, y3); return; } grow_path(ctx, path, 7); path->items[path->len++].k = FZ_CURVETO; path->items[path->len++].v = x1; path->items[path->len++].v = y1; path->items[path->len++].v = x2; path->items[path->len++].v = y2; path->items[path->len++].v = x3; path->items[path->len++].v = y3; } void fz_curvetov(fz_context *ctx, fz_path *path, float x2, float y2, float x3, float y3) { float x1, y1; if (path->last < 0) { fz_warn(ctx, "curvetov with no current point"); return; } if (path->items[path->last].k == FZ_CLOSE_PATH) { x1 = path->items[path->last-2].v; y1 = path->items[path->last-1].v; } else { x1 = path->items[path->len-2].v; y1 = path->items[path->len-1].v; } fz_curveto(ctx, path, x1, y1, x2, y2, x3, y3); } void fz_curvetoy(fz_context *ctx, fz_path *path, float x1, float y1, float x3, float y3) { fz_curveto(ctx, path, x1, y1, x3, y3, x3, y3); } void fz_closepath(fz_context *ctx, fz_path *path) { if (path->last < 0) { fz_warn(ctx, "closepath with no current point"); return; } /* CLOSE following a CLOSE is a NOP */ if (path->items[path->last].k == FZ_CLOSE_PATH) return; grow_path(ctx, path, 1); path->items[path->len++].k = FZ_CLOSE_PATH; } static inline fz_rect bound_expand(fz_rect r, fz_point p) { if (p.x < r.x0) r.x0 = p.x; if (p.y < r.y0) r.y0 = p.y; if (p.x > r.x1) r.x1 = p.x; if (p.y > r.y1) r.y1 = p.y; return r; } fz_rect fz_bound_path(fz_context *ctx, fz_path *path, fz_stroke_state *stroke, fz_matrix ctm) { fz_point p; fz_rect r; int i = 0; /* If the path is empty, return the empty rectangle here - don't wait * for it to be expanded in the stroked case below. */ if (path->len == 0) return fz_empty_rect; /* A path must start with a moveto - and if that's all there is * then the path is empty. */ if (path->len == 3) return fz_empty_rect; p.x = path->items[1].v; p.y = path->items[2].v; p = fz_transform_point(ctm, p); r.x0 = r.x1 = p.x; r.y0 = r.y1 = p.y; while (i < path->len) { switch (path->items[i++].k) { case FZ_CURVETO: p.x = path->items[i++].v; p.y = path->items[i++].v; r = bound_expand(r, fz_transform_point(ctm, p)); p.x = path->items[i++].v; p.y = path->items[i++].v; r = bound_expand(r, fz_transform_point(ctm, p)); p.x = path->items[i++].v; p.y = path->items[i++].v; r = bound_expand(r, fz_transform_point(ctm, p)); break; case FZ_MOVETO: if (i + 2 == path->len) { /* Trailing Moveto - cannot affect bbox */ i += 2; break; } /* fallthrough */ case FZ_LINETO: p.x = path->items[i++].v; p.y = path->items[i++].v; r = bound_expand(r, fz_transform_point(ctm, p)); break; case FZ_CLOSE_PATH: break; } } if (stroke) { fz_adjust_rect_for_stroke(&r, stroke, &ctm); } return r; } void fz_adjust_rect_for_stroke(fz_rect *r, fz_stroke_state *stroke, fz_matrix *ctm) { float expand; if (!stroke) return; expand = stroke->linewidth; if (expand == 0) expand = 1.0f; expand *= fz_matrix_max_expansion(*ctm); if ((stroke->linejoin == FZ_LINEJOIN_MITER || stroke->linejoin == FZ_LINEJOIN_MITER_XPS) && stroke->miterlimit > 1) expand *= stroke->miterlimit; r->x0 -= expand; r->y0 -= expand; r->x1 += expand; r->y1 += expand; } void fz_transform_path(fz_context *ctx, fz_path *path, fz_matrix ctm) { fz_point p; int k, i = 0; while (i < path->len) { switch (path->items[i++].k) { case FZ_CURVETO: for (k = 0; k < 3; k++) { p.x = path->items[i].v; p.y = path->items[i+1].v; p = fz_transform_point(ctm, p); path->items[i].v = p.x; path->items[i+1].v = p.y; i += 2; } break; case FZ_MOVETO: case FZ_LINETO: p.x = path->items[i].v; p.y = path->items[i+1].v; p = fz_transform_point(ctm, p); path->items[i].v = p.x; path->items[i+1].v = p.y; i += 2; break; case FZ_CLOSE_PATH: break; } } } #ifndef NDEBUG void fz_print_path(fz_context *ctx, FILE *out, fz_path *path, int indent) { float x, y; int i = 0; int n; while (i < path->len) { for (n = 0; n < indent; n++) fputc(' ', out); switch (path->items[i++].k) { case FZ_MOVETO: x = path->items[i++].v; y = path->items[i++].v; fprintf(out, "%g %g m\n", x, y); break; case FZ_LINETO: x = path->items[i++].v; y = path->items[i++].v; fprintf(out, "%g %g l\n", x, y); break; case FZ_CURVETO: x = path->items[i++].v; y = path->items[i++].v; fprintf(out, "%g %g ", x, y); x = path->items[i++].v; y = path->items[i++].v; fprintf(out, "%g %g ", x, y); x = path->items[i++].v; y = path->items[i++].v; fprintf(out, "%g %g c\n", x, y); break; case FZ_CLOSE_PATH: fprintf(out, "h\n"); break; } } } #endif fz_stroke_state * fz_keep_stroke_state(fz_context *ctx, fz_stroke_state *stroke) { fz_lock(ctx, FZ_LOCK_ALLOC); if (!stroke) return NULL; if (stroke->refs > 0) stroke->refs++; fz_unlock(ctx, FZ_LOCK_ALLOC); return stroke; } void fz_drop_stroke_state(fz_context *ctx, fz_stroke_state *stroke) { int drop; if (!stroke) return; fz_lock(ctx, FZ_LOCK_ALLOC); drop = (stroke->refs > 0 ? --stroke->refs == 0 : 0); fz_unlock(ctx, FZ_LOCK_ALLOC); if (drop) fz_free(ctx, stroke); } fz_stroke_state * fz_new_stroke_state_with_len(fz_context *ctx, int len) { fz_stroke_state *state; len -= nelem(state->dash_list); if (len < 0) len = 0; state = Memento_label(fz_malloc(ctx, sizeof(*state) + sizeof(state->dash_list[0]) * len), "fz_stroke_state"); state->refs = 1; state->start_cap = FZ_LINECAP_BUTT; state->dash_cap = FZ_LINECAP_BUTT; state->end_cap = FZ_LINECAP_BUTT; state->linejoin = FZ_LINEJOIN_MITER; state->linewidth = 1; state->miterlimit = 10; state->dash_phase = 0; state->dash_len = 0; memset(state->dash_list, 0, sizeof(state->dash_list[0]) * (len + nelem(state->dash_list))); return state; } fz_stroke_state * fz_new_stroke_state(fz_context *ctx) { return fz_new_stroke_state_with_len(ctx, 0); } fz_stroke_state * fz_unshare_stroke_state_with_len(fz_context *ctx, fz_stroke_state *shared, int len) { int single, unsize, shsize, shlen, drop; fz_stroke_state *unshared; fz_lock(ctx, FZ_LOCK_ALLOC); single = (shared->refs == 1); fz_unlock(ctx, FZ_LOCK_ALLOC); shlen = shared->dash_len - nelem(shared->dash_list); if (shlen < 0) shlen = 0; shsize = sizeof(*shared) + sizeof(shared->dash_list[0]) * shlen; len -= nelem(shared->dash_list); if (len < 0) len = 0; if (single && shlen >= len) return shared; unsize = sizeof(*unshared) + sizeof(unshared->dash_list[0]) * len; unshared = Memento_label(fz_malloc(ctx, unsize), "fz_stroke_state"); memcpy(unshared, shared, (shsize > unsize ? unsize : shsize)); unshared->refs = 1; fz_lock(ctx, FZ_LOCK_ALLOC); drop = (shared->refs > 0 ? --shared->refs == 0 : 0); fz_unlock(ctx, FZ_LOCK_ALLOC); if (drop) fz_free(ctx, shared); return unshared; } fz_stroke_state * fz_unshare_stroke_state(fz_context *ctx, fz_stroke_state *shared) { return fz_unshare_stroke_state_with_len(ctx, shared, shared->dash_len); }