/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * $URL$ * $Id$ * */ #include "sci/gfx/gfx_system.h" #include "sci/gfx/gfx_resource.h" #include "sci/gfx/gfx_tools.h" namespace Sci { gfx_mode_t mode_1x1_color_index = { /* Fake 1x1 mode */ /* xfact */ 1, /* yfact */ 1, /* bytespp */ 1, /* flags */ 0, /* palette */ NULL, /* color masks */ 0, 0, 0, 0, /* color shifts */ 0, 0, 0, 0 }; static void gfxr_free_loop(gfx_driver_t *driver, gfxr_loop_t *loop) { int i; if (loop->cels) { for (i = 0; i < loop->cels_nr; i++) if (loop->cels[i]) gfx_free_pixmap(driver, loop->cels[i]); free(loop->cels); } } void gfxr_free_view(gfx_driver_t *driver, gfxr_view_t *view) { int i; if (view->palette) view->palette->free(); if (view->loops) { for (i = 0; i < view->loops_nr; i++) gfxr_free_loop(driver, view->loops + i); free(view->loops); } free(view); } static void pixmap_endianness_reverse_2_simple(byte *data, int area) { int c; for (c = 0; c < area; c++) { byte val = *data; *data = data[1]; data[1] = val; data += 2; } } static void pixmap_endianness_reverse_2(byte *data, int area) { int c; int sl = sizeof(unsigned long); for (c = 0; c < (area & ~(sl - 1)); c += (sl >> 1)) { unsigned long temp; memcpy(&temp, data, sl); // The next line will give warnings on 32 bit archs, but that's OK. #if SIZEOF_LONG < 8 temp = 0; #else temp = ((temp & 0xff00ff00ff00ff00l) >> 8) | ((temp & 0x00ff00ff00ff00ffl) << 8); #endif memcpy(data, &temp, sl); data += sl; } pixmap_endianness_reverse_2_simple(data, area & (sl - 1)); } static void pixmap_endianness_reverse_3_simple(byte *data, int area) { int c; for (c = 0; c < area; c++) { byte val0 = data[0]; data[0] = data[2]; data[2] = val0; data += 3; } } static void pixmap_endianness_reverse_4_simple(byte *data, int area) { int c; for (c = 0; c < area; c++) { byte val0 = data[0]; byte val1 = data[1]; data[0] = data[3]; data[3] = val0; data[1] = data[2]; data[2] = val1; data += 4; } } static void pixmap_endianness_reverse_4(byte *data, int area) { int c; int sl = sizeof(unsigned long); for (c = 0; c < (area & ~(sl - 1)); c += (sl >> 2)) { unsigned long temp; memcpy(&temp, data, sl); // The next lines will give warnings on 32 bit archs, but that's OK. #if SIZEOF_LONG < 8 temp = 0l; #else temp = ((temp & 0xffff0000ffff0000l) >> 16) | ((temp & 0x0000ffff0000ffffl) << 16); temp = ((temp & 0xff00ff00ff00ff00l) >> 8) | ((temp & 0x00ff00ff00ff00ffl) << 8); #endif memcpy(data, &temp, sl); data += sl; } pixmap_endianness_reverse_4_simple(data, area & (sl - 1)); } gfx_pixmap_t *gfxr_endianness_adjust(gfx_pixmap_t *pixmap, gfx_mode_t *mode) { int bytespp; byte *data; if (!pixmap || !pixmap->data || !mode) { GFXERROR("gfxr_endianness_adjust(): Invoked with invalid values\n"); BREAKPOINT(); return NULL; } if (!(mode->flags & GFX_MODE_FLAG_REVERSE_ENDIAN)) return pixmap; bytespp = mode->bytespp; data = pixmap->data; switch (bytespp) { case 1: break; case 2: pixmap_endianness_reverse_2(data, pixmap->xl * pixmap->yl); break; case 3: pixmap_endianness_reverse_3_simple(data, pixmap->xl * pixmap->yl); break; case 4: pixmap_endianness_reverse_4(data, pixmap->xl * pixmap->yl); break; default: fprintf(stderr, "gfxr_endianness_adjust(): Cannot adjust endianness for %d bytespp!\n", bytespp); return NULL; } return pixmap; } } // End of namespace Sci // Now construct the pixmap scaling functions #define EXTRA_BYTE_OFFSET 0 #define SIZETYPE uint8 #define FUNCNAME _gfx_xlate_pixmap_unfiltered_1 #define FUNCNAME_LINEAR _gfx_xlate_pixmap_linear_1 #define FUNCNAME_TRILINEAR _gfx_xlate_pixmap_trilinear_1 #define COPY_BYTES 1 #include "gfx_pixmap_scale.cpp" #undef COPY_BYTES #define SIZETYPE uint16 #define FUNCNAME _gfx_xlate_pixmap_unfiltered_2 #define FUNCNAME_LINEAR _gfx_xlate_pixmap_linear_2 #define FUNCNAME_TRILINEAR _gfx_xlate_pixmap_trilinear_2 #define COPY_BYTES 2 #include "gfx_pixmap_scale.cpp" #undef COPY_BYTES #ifdef SCUMM_BIG_ENDIAN # undef EXTRA_BYTE_OFFSET # define EXTRA_BYTE_OFFSET 1 #endif // SCUMM_BIG_ENDIAN #define SIZETYPE uint32 #define FUNCNAME _gfx_xlate_pixmap_unfiltered_3 #define FUNCNAME_LINEAR _gfx_xlate_pixmap_linear_3 #define FUNCNAME_TRILINEAR _gfx_xlate_pixmap_trilinear_3 #define COPY_BYTES 3 #include "gfx_pixmap_scale.cpp" #undef COPY_BYTES #ifdef SCUMM_BIG_ENDIAN # undef EXTRA_BYTE_OFFSET # define EXTRA_BYTE_OFFSET 0 #endif // SCUMM_BIG_ENDIAN #define SIZETYPE uint32 #define FUNCNAME _gfx_xlate_pixmap_unfiltered_4 #define FUNCNAME_LINEAR _gfx_xlate_pixmap_linear_4 #define FUNCNAME_TRILINEAR _gfx_xlate_pixmap_trilinear_4 #define COPY_BYTES 4 #include "gfx_pixmap_scale.cpp" #undef COPY_BYTES #undef EXTRA_BYTE_OFFSET #undef SIZETYPE namespace Sci { static void _gfx_xlate_pixmap_unfiltered(gfx_mode_t *mode, gfx_pixmap_t *pxm, int scale) { switch (mode->bytespp) { case 1: _gfx_xlate_pixmap_unfiltered_1(mode, pxm, scale); break; case 2: _gfx_xlate_pixmap_unfiltered_2(mode, pxm, scale); break; case 3: _gfx_xlate_pixmap_unfiltered_3(mode, pxm, scale); break; case 4: _gfx_xlate_pixmap_unfiltered_4(mode, pxm, scale); break; default: GFXERROR("Invalid mode->bytespp=%d\n", mode->bytespp); } if (pxm->flags & GFX_PIXMAP_FLAG_SCALED_INDEX) { pxm->xl = pxm->index_xl; pxm->yl = pxm->index_yl; } else { pxm->xl = pxm->index_xl * mode->xfact; pxm->yl = pxm->index_yl * mode->yfact; } } static void _gfx_xlate_pixmap_linear(gfx_mode_t *mode, gfx_pixmap_t *pxm, int scale) { if (mode->palette || !scale) { // fall back to unfiltered _gfx_xlate_pixmap_unfiltered(mode, pxm, scale); return; } pxm->xl = pxm->index_xl * mode->xfact; pxm->yl = pxm->index_yl * mode->yfact; switch (mode->bytespp) { case 1: _gfx_xlate_pixmap_linear_1(mode, pxm, scale); break; case 2: _gfx_xlate_pixmap_linear_2(mode, pxm, scale); break; case 3: _gfx_xlate_pixmap_linear_3(mode, pxm, scale); break; case 4: _gfx_xlate_pixmap_linear_4(mode, pxm, scale); break; default: GFXERROR("Invalid mode->bytespp=%d\n", mode->bytespp); } } static void _gfx_xlate_pixmap_trilinear(gfx_mode_t *mode, gfx_pixmap_t *pxm, int scale) { if (mode->palette || !scale) { // fall back to unfiltered _gfx_xlate_pixmap_unfiltered(mode, pxm, scale); return; } pxm->xl = pxm->index_xl * mode->xfact; pxm->yl = pxm->index_yl * mode->yfact; switch (mode->bytespp) { case 1: _gfx_xlate_pixmap_trilinear_1(mode, pxm, scale); break; case 2: _gfx_xlate_pixmap_trilinear_2(mode, pxm, scale); break; case 3: _gfx_xlate_pixmap_trilinear_3(mode, pxm, scale); break; case 4: _gfx_xlate_pixmap_trilinear_4(mode, pxm, scale); break; default: GFXERROR("Invalid mode->bytespp=%d\n", mode->bytespp); } } void gfx_xlate_pixmap(gfx_pixmap_t *pxm, gfx_mode_t *mode, gfx_xlate_filter_t filter) { int was_allocated = 0; if (mode->palette) { if (pxm->palette && pxm->palette != mode->palette) pxm->palette->mergeInto(mode->palette); } if (!pxm->data) { pxm->data = (byte*)sci_malloc(mode->xfact * mode->yfact * pxm->index_xl * pxm->index_yl * mode->bytespp + 1); // +1: Eases coying on BE machines in 24 bpp packed mode // Assume that memory, if allocated already, will be sufficient // Allocate alpha map if (!mode->alpha_mask && pxm->colors_nr() < GFX_PIC_COLORS) pxm->alpha_map = (byte*)sci_malloc(mode->xfact * mode->yfact * pxm->index_xl * pxm->index_yl + 1); } else was_allocated = 1; switch (filter) { case GFX_XLATE_FILTER_NONE: _gfx_xlate_pixmap_unfiltered(mode, pxm, !(pxm->flags & GFX_PIXMAP_FLAG_SCALED_INDEX)); break; case GFX_XLATE_FILTER_LINEAR: _gfx_xlate_pixmap_linear(mode, pxm, !(pxm->flags & GFX_PIXMAP_FLAG_SCALED_INDEX)); break; case GFX_XLATE_FILTER_TRILINEAR: _gfx_xlate_pixmap_trilinear(mode, pxm, !(pxm->flags & GFX_PIXMAP_FLAG_SCALED_INDEX)); break; default: GFXERROR("Attempt to filter pixmap %04x in invalid mode #%d\n", pxm->ID, filter); if (!was_allocated) { if (!mode->alpha_mask && pxm->colors_nr() < GFX_PIC_COLORS) free(pxm->alpha_map); free(pxm->data); } } } void gfxr_free_pic(gfx_driver_t *driver, gfxr_pic_t *pic) { gfx_free_pixmap(driver, pic->visual_map); gfx_free_pixmap(driver, pic->priority_map); gfx_free_pixmap(driver, pic->control_map); pic->visual_map = NULL; pic->priority_map = NULL; pic->control_map = NULL; if (pic->priorityTable) free(pic->priorityTable); pic->priorityTable = NULL; if (pic->undithered_buffer) free(pic->undithered_buffer); pic->undithered_buffer = 0; free(pic); } } // End of namespace Sci