/************************************************************************** * * Copyright 2009 Ben Skeggs * Copyright 2009 Younes Manton * Copyright 2010 Luca Barbieri * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sub license, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES * OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NON-INFRINGEMENT. IN NO EVENT SHALL THE COPYRIGHT HOLDERS, AUTHORS * AND/OR ITS SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE * USE OR OTHER DEALINGS IN THE SOFTWARE. * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial portions * of the Software. * **************************************************************************/ /* this code has no Mesa or Gallium dependency and can be reused in the classic Mesa driver or DDX */ #include #include #include #include #include #include #include #include #include #include "nv04_2d.h" #include "nouveau/nv_object.xml.h" #include "nouveau/nv_m2mf.xml.h" #include "nv01_2d.xml.h" /* avoid depending on Mesa/Gallium */ #ifdef __GNUC__ #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) #else #define likely(x) !!(x) #define unlikely(x) !!(x) #endif #define MIN2( A, B ) ( (A)<(B) ? (A) : (B) ) #define MAX2( A, B ) ( (A)>(B) ? (A) : (B) ) struct nv04_2d_context { struct nouveau_notifier *ntfy; struct nouveau_grobj *surf2d; struct nouveau_grobj *swzsurf; struct nouveau_grobj *m2mf; struct nouveau_grobj *rect; struct nouveau_grobj *sifm; struct nouveau_grobj *blit; }; static inline int align(int value, int alignment) { return (value + alignment - 1) & ~(alignment - 1); } static inline int util_is_pot(unsigned x) { return (x & (x - 1)) == 0; } /* Integer base-2 logarithm, rounded towards zero. */ static inline unsigned log2i(unsigned i) { unsigned r = 0; if (i & 0xffff0000) { i >>= 16; r += 16; } if (i & 0x0000ff00) { i >>= 8; r += 8; } if (i & 0x000000f0) { i >>= 4; r += 4; } if (i & 0x0000000c) { i >>= 2; r += 2; } if (i & 0x00000002) { r += 1; } return r; } //#define NV04_REGION_DEBUG // Yes, we really want to inline everything, since all the functions are used only once #if defined(__GNUC__) && !defined(DEBUG) #define inline __attribute__((always_inline)) inline #endif static inline unsigned nv04_swizzle_bits_square(unsigned x, unsigned y) { unsigned u = (x & 0x001) << 0 | (x & 0x002) << 1 | (x & 0x004) << 2 | (x & 0x008) << 3 | (x & 0x010) << 4 | (x & 0x020) << 5 | (x & 0x040) << 6 | (x & 0x080) << 7 | (x & 0x100) << 8 | (x & 0x200) << 9 | (x & 0x400) << 10 | (x & 0x800) << 11; unsigned v = (y & 0x001) << 1 | (y & 0x002) << 2 | (y & 0x004) << 3 | (y & 0x008) << 4 | (y & 0x010) << 5 | (y & 0x020) << 6 | (y & 0x040) << 7 | (y & 0x080) << 8 | (y & 0x100) << 9 | (y & 0x200) << 10 | (y & 0x400) << 11 | (y & 0x800) << 12; return v | u; } /* rectangular swizzled textures are linear concatenations of swizzled square tiles */ static inline unsigned nv04_swizzle_bits_2d(unsigned x, unsigned y, unsigned w, unsigned h) { if(h <= 1) return x; else { unsigned s = MIN2(w, h); unsigned m = s - 1; return (((x | y) & ~m) * s) | nv04_swizzle_bits_square(x & m, y & m); } } // general 3D texture case static inline unsigned nv04_swizzle_bits(unsigned x, unsigned y, unsigned z, unsigned w, unsigned h, unsigned d) { if(d <= 1) return nv04_swizzle_bits_2d(x, y, w, h); else { // TODO: autogenerate code for all possible texture sizes (13 * 13 * 13 with dims <= 4096) and do a single indirect call unsigned v = 0; w >>= 1; h >>= 1; d >>= 1; for(int i = 0;;) { int oldi = i; if(likely(w)) { v |= (x & 1) << i; x >>= 1; w >>= 1; ++i; } if(likely(h)) { v |= (y & 1) << i; y >>= 1; h >>= 1; ++i; } if(likely(d)) { v |= (z & 1) << i; z >>= 1; d >>= 1; ++i; } if(i == oldi) break; } return v; } } unsigned nv04_region_begin(struct nv04_region* rgn, unsigned w, unsigned h) { if(rgn->pitch) return rgn->pitch * rgn->y + (rgn->x << rgn->bpps); else return nv04_swizzle_bits(rgn->x, rgn->y, rgn->z, rgn->w, rgn->h, rgn->d) << rgn->bpps; } unsigned nv04_region_end(struct nv04_region* rgn, unsigned w, unsigned h) { if(rgn->pitch) return rgn->pitch * (rgn->y + h - 1) + ((rgn->x + w) << rgn->bpps); else return (nv04_swizzle_bits(rgn->x + w - 1, rgn->y + h - 1, rgn->z, rgn->w, rgn->h, rgn->d) + 1) << rgn->bpps; } // *pitch = -1 -> use 3D swizzling for (x, y), *pitch = 0 -> use 2D swizzling, other *pitch -> use linear calculations // returns 2 if pixel order is 3D-swizzled and 1 if subrect is 2D-swizzled /* *pitch == -1 ret = 0 -> 3D swizzled subrect * *pitch == 0 ret = 0 -> 2D swizzled subrect * *pitch > 0 ret = 0 -> linear subrect * *pitch > 0 ret = 1 -> linear subrect, but with swizzled 3D data inside */ static inline void nv04_region_print(struct nv04_region* rgn) { fprintf(stderr, "<%i[%i]> ", rgn->bo->handle, rgn->offset); if(rgn->pitch) fprintf(stderr, "lin %i", rgn->pitch); else fprintf(stderr, "swz %ix%ix%i", rgn->w, rgn->h, rgn->d); fprintf(stderr, " (%i, %i, %i)", rgn->x, rgn->y, rgn->z); } static inline void nv04_region_assert(struct nv04_region* rgn, unsigned w, unsigned h) { unsigned end = rgn->offset + nv04_region_end(rgn, w, h); assert(rgn->offset <= (int)rgn->bo->size); assert(end <= rgn->bo->size); (void) end; if(!rgn->pitch) { assert(util_is_pot(rgn->w)); assert(util_is_pot(rgn->h)); } } /* determine if region can be linearized or fake-linearized */ static inline int nv04_region_is_contiguous(struct nv04_region* rgn, int w, int h) { int surf_min; int rect_min; if(rgn->pitch) return rgn->pitch == w << rgn->bpps; // redundant, but this is the fast path for the common case if(w == rgn->w && h == rgn->h && rgn->d <= 1) return 1; // must be POT if((w & (w - 1)) || (h & (h - 1))) return 0; // must be aligned if((rgn->x & (w - 1)) || (rgn->y & (h - 1))) return 0; if(rgn->d > 1) return 0; surf_min = MIN2(rgn->w, rgn->h); rect_min = MIN2(w, h); if((rect_min == surf_min) || (w == h) || (w == 2 * h)) return 1; return 0; } // double the pitch until it is larger than the alignment, or the height becomes odd or 1 static inline void nv04_region_contiguous_shape(struct nv04_region* rgn, int* w, int* h, int align) { while(!(*h & 1) && (*w << rgn->bpps) < (1 << align)) { *w <<= 1; *h >>= 1; } while((*w << rgn->bpps) > 16384 && !(*w & 1)) { *w >>= 1; *h <<= 1; } #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tCONTIGUOUS %ix%i\n", *w, *h); #endif } static inline void nv04_region_linearize_contiguous(struct nv04_region* rgn, unsigned w, unsigned h) { int pos; if(rgn->pitch) { rgn->offset += rgn->y * rgn->pitch + (rgn->x << rgn->bpps); rgn->x = 0; rgn->y = 0; } else { rgn->offset += (rgn->w * rgn->h * rgn->z) << rgn->bpps; pos = nv04_swizzle_bits(rgn->x, rgn->y, rgn->z, rgn->w, rgn->h, rgn->d); rgn->x = pos & (w - 1); rgn->y = pos / w; } rgn->pitch = w << rgn->bpps; #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tLINEARIZE "); nv04_region_print(rgn); fprintf(stderr, "\n"); #endif } /* preserve the offset! */ /* rgn->pitch = util_format_get_stride(rgn->format, w); int pos = nv04_swizzle_bits(rgn->x, rgn->y, rgn->z, rgn->w, rgn->h, rgn->d); rgn->x = pos & (w - 1); rgn->y = pos & ~(w - 1); */ /* rgn->offset += rgn->pitch = util_format_get_stride(rgn->format, w); rgn->x = 0; rgn->y = 0; */ /* This code will get used for, and always succeed on: * - 4x2 1bpp swizzled texture mipmap levels * - linear regions created by linearization * * This code will get used for, and MAY work for: * - misaligned texture blanket * - linear surfaces created without wide_pitch (in this case, it will only work if we are lucky) * * The general case requires splitting the region in 2. */ static inline int nv04_region_do_align_offset(struct nv04_region* rgn, unsigned w, unsigned h, int shift) { if(rgn->pitch > 0) { assert(!(rgn->offset & ((1 << rgn->bpps) - 1))); // fatal! if(h <= 1) { int delta; rgn->offset += rgn->y * rgn->pitch + (rgn->x << rgn->bpps); delta = rgn->offset & ((1 << shift) - 1); rgn->y = 0; rgn->x = delta >> rgn->bpps; rgn->offset -= delta; rgn->pitch = align((rgn->x + w) << rgn->bpps, 1 << shift); } else { int delta = rgn->offset & ((1 << shift) - 1); int newxo = (rgn->x << rgn->bpps) + delta; int dy = newxo / rgn->pitch; newxo -= dy * rgn->pitch; if((newxo + (w << rgn->bpps)) > rgn->pitch) { // TODO: split the region into two rectangles (!) if *really* necessary, unless the hardware actually supports "wrapping" rectangles // this does not happen if the surface is pitch-aligned, which it should always be assert(0); return -1; } rgn->x = newxo >> rgn->bpps; rgn->y += dy; } } else { int size; int min; int v; // we don't care about the alignment of 3D surfaces since the 2D engine can't use them if(rgn->d < 0) return -1; min = MIN2(rgn->w, rgn->h); size = min * min << rgn->bpps; // this is unfixable, and should not be happening if(rgn->offset & (size - 1)) return -1; v = (rgn->offset & ((1 << shift) - 1)) / size; rgn->offset -= v * size; if(rgn->h == min) { unsigned w; rgn->x += rgn->h * v; w = rgn->w + rgn->h * v; while(rgn->w < w) rgn->w += rgn->w; } else { unsigned h; rgn->y += rgn->w * v; h = rgn->h + rgn->w * v; while(rgn->h < h) rgn->h += rgn->h; } } #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tALIGNED "); nv04_region_print(rgn); fprintf(stderr, "\n"); #endif return 0; } // both pitch and shift // will leave the region unchanged if it fails static inline int nv04_region_align(struct nv04_region* rgn, unsigned w, unsigned h, int shift) { if(rgn->pitch & ((1 << shift) - 1)) { if(h == 1) goto do_align; /* this will fix pitch too in this case */ else return -1; } if(rgn->offset & ((1 << shift) - 1)) { do_align: if(nv04_region_do_align_offset(rgn, w, h, shift)) return -1; } return 0; } /* this contains 22 different copy loops after preprocessing. unfortunately, it's necessary */ void nv04_region_copy_cpu(struct nv04_region* dst, struct nv04_region* src, int w, int h) { uint8_t* mdst; uint8_t* msrc; int size; if(dst->bo != src->bo) { nouveau_bo_map(dst->bo, NOUVEAU_BO_WR); nouveau_bo_map(src->bo, NOUVEAU_BO_RD); } else nouveau_bo_map(dst->bo, NOUVEAU_BO_WR | NOUVEAU_BO_RD); mdst = (uint8_t*)dst->bo->map + dst->offset; msrc = (uint8_t*)src->bo->map + src->offset; size = w << dst->bpps; nv04_region_assert(dst, w, h); nv04_region_assert(src, w, h); #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tRGN_COPY_CPU [%i, %i: %i] ", w, h, dst->bpps); for(int i = 0; i < 2; ++i) { nv04_region_print(i ? src : dst); fprintf(stderr, i ? "\n" : " <- "); } // for(int i = 0; i < 16; ++i) // fprintf(stderr, "%02x ", msrc[i]); // fprintf(stderr, "\n"); #endif // TODO: support overlapping copies! if(src->pitch && dst->pitch) { mdst += dst->y * dst->pitch + (dst->x << dst->bpps); msrc += src->y * src->pitch + (src->x << src->bpps); if(dst->bo != src->bo) goto simple; else if(mdst < msrc) { if(mdst + size <= msrc) { simple: for(int iy = 0; iy < h; ++iy) { assert(mdst + size <= (uint8_t*)dst->bo->map + dst->bo->size); assert(msrc + size <= (uint8_t*)src->bo->map + src->bo->size); memcpy(mdst, msrc, size); msrc += src->pitch; mdst += dst->pitch; } } else { for(int iy = 0; iy < h; ++iy) { assert(mdst + size <= (uint8_t*)dst->bo->map + dst->bo->size); assert(msrc + size <= (uint8_t*)src->bo->map + src->bo->size); memmove(mdst, msrc, size); msrc += src->pitch; mdst += dst->pitch; } } } else { /* copy backwards so we don't destroy data we have to read yet */ if(msrc + size <= mdst) { for(int iy = h - 1; iy >= 0; --iy) { assert(mdst + size <= (uint8_t*)dst->bo->map + dst->bo->size); assert(msrc + size <= (uint8_t*)src->bo->map + src->bo->size); memcpy(mdst, msrc, size); msrc += src->pitch; mdst += dst->pitch; } } else { for(int iy = h - 1; iy >= 0; --iy) { assert(mdst + size <= (uint8_t*)dst->bo->map + dst->bo->size); assert(msrc + size <= (uint8_t*)src->bo->map + src->bo->size); memmove(mdst, msrc, size); msrc += src->pitch; mdst += dst->pitch; } } } } else { int* dswx = NULL; int* dswy = NULL; int* sswx = NULL; int* sswy = NULL; int dir; if(!dst->pitch) { dswx = alloca(w * sizeof(int)); for(int ix = 0; ix < w; ++ix) // we are adding, so z cannot be contributed by both dswx[ix] = nv04_swizzle_bits(dst->x + ix, 0, 0, dst->w, dst->h, dst->d); dswy = alloca(h * sizeof(int)); for(int iy = 0; iy < h; ++iy) dswy[iy] = nv04_swizzle_bits(0, dst->y + iy, dst->z, dst->w, dst->h, dst->d); } if(!src->pitch) { sswx = alloca(w * sizeof(int)); for(int ix = 0; ix < w; ++ix) sswx[ix] = nv04_swizzle_bits(src->x + ix, 0, 0, src->w, src->h, src->d); sswy = alloca(h * sizeof(int)); for(int iy = 0; iy < h; ++iy) sswy[iy] = nv04_swizzle_bits(0, src->y + iy, src->z, src->w, src->h, src->d); } dir = 1; /* do backwards copies for overlapping swizzled surfaces */ if(dst->pitch == src->pitch && dst->offset == src->offset) { if(dst->y > src->y || (dst->y == src->y && dst->x > src->x)) dir = -1; } #define SWIZZLED_COPY_LOOPS if(dir == 1) { int dir = 1; #define LOOP_Y for(int iy = 0; iy < h; ++iy) #define LOOP_X for(int ix = 0; ix < w; ++ix) #include "nv04_2d_loops.h" #undef LOOP_X #undef LOOP_Y } else { int dir = -1; #define LOOP_Y for(int iy = h - 1; iy >= 0; --iy) #define LOOP_X for(int ix = w - 1; ix >= 0; --ix) #include "nv04_2d_loops.h" #undef LOOP_X #undef LOOP_Y } #undef SWIZZLED_COPY_LOOP } if(src->bo != dst->bo) nouveau_bo_unmap(src->bo); nouveau_bo_unmap(dst->bo); } /* TODO: if the destination is swizzled, we are doing random writes, which causes write combining to fail * the alternative is to read, modify and copy back, which may or may not be faster * loading 3D textures is a common case that hits this and could probably benefit from the temporary */ void nv04_region_fill_cpu(struct nv04_region* dst, int w, int h, unsigned value) { uint8_t* mdst = (nouveau_bo_map(dst->bo, NOUVEAU_BO_WR), (uint8_t*)dst->bo->map + dst->offset); #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tRGN_FILL_CPU "); nv04_region_print(dst); fprintf(stderr, "\n"); #endif nv04_region_assert(dst, w, h); if(dst->pitch) { unsigned size = w << dst->bpps; #define FILL(T) do { \ for(int iy = 0; iy < h; ++iy) \ { \ assert((char*)((T*)mdst + w) <= (char*)dst->bo->map + dst->bo->size); \ for(int ix = 0; ix < w; ++ix) \ ((T*)mdst)[ix] = (T)value; \ mdst += dst->pitch; \ } \ } while(0) mdst += dst->y * dst->pitch + (dst->x << dst->bpps); if(dst->bpps == 0) { ms: assert(mdst + size * h <= (uint8_t*)dst->bo->map + dst->bo->size); if(size == dst->pitch) memset(mdst, (uint8_t)value, size * h); else { for(int iy = 0; iy < h; ++iy) { assert(mdst + size <= (uint8_t*)dst->bo->map + dst->bo->size); memset(mdst, (uint8_t)value, size); mdst += dst->pitch; } } } else if(dst->bpps == 1) { if(!((uint8_t)value ^ (uint8_t)(value >> 8))) goto ms; FILL(uint16_t); } else if(dst->bpps == 2) { if(value == (uint8_t)value * 0x1010101) goto ms; FILL(uint32_t); } else assert(0); #undef FILL } else { int* dswx; int* dswy; dswx = alloca(w * sizeof(int)); for(int ix = 0; ix < w; ++ix) dswx[ix] = nv04_swizzle_bits(dst->x + ix, 0, dst->z, dst->w, dst->h, dst->d); dswy = alloca(h * sizeof(int)); for(int iy = 0; iy < h; ++iy) dswy[iy] = nv04_swizzle_bits(0, dst->y + iy, dst->z, dst->w, dst->h, dst->d); #define FILL(T) do { \ T tvalue = (T)value; \ for(int iy = 0; iy < h; ++iy) \ { \ T* pdst = (T*)mdst + dswy[iy]; \ for(int ix = 0; ix < w; ++ix) \ { \ assert((uint8_t*)&pdst[dswx[ix] + 1] <= (uint8_t*)dst->bo->map + dst->bo->size); \ pdst[dswx[ix]] = tvalue; \ } \ } \ } while(0) if(dst->bpps == 0) FILL(uint8_t); else if(dst->bpps == 1) FILL(uint16_t); else if(dst->bpps == 2) FILL(uint32_t); else assert(0 && "unhandled bpp"); #undef FILL } nouveau_bo_unmap(dst->bo); } static inline int nv04_region_cs2d_format(struct nv04_region* rgn) { switch(rgn->bpps) { case 0: return NV04_CONTEXT_SURFACES_2D_FORMAT_Y8; case 1: if(rgn->one_bits >= 1) return NV04_CONTEXT_SURFACES_2D_FORMAT_X1R5G5B5_X1R5G5B5; else return NV04_CONTEXT_SURFACES_2D_FORMAT_R5G6B5; case 2: if(rgn->one_bits >= 8) return NV04_CONTEXT_SURFACES_2D_FORMAT_X8R8G8B8_X8R8G8B8; else return NV04_CONTEXT_SURFACES_2D_FORMAT_A8R8G8B8; default: return -1; } } static inline int nv04_region_sifm_format(struct nv04_region* rgn) { switch(rgn->bpps) { case 0: return NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_FORMAT_Y8; case 1: if(rgn->one_bits >= 1) return NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_FORMAT_X1R5G5B5; else return NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_FORMAT_R5G6B5; case 2: if(rgn->one_bits >= 8) return NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_FORMAT_X8R8G8B8; else return NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_FORMAT_A8R8G8B8; default: return -1; } } static void nv04_region_copy_swizzle(struct nv04_2d_context *ctx, struct nv04_region* dst, struct nv04_region* src, int w, int h) { struct nouveau_channel *chan = ctx->swzsurf->channel; struct nouveau_grobj *swzsurf = ctx->swzsurf; struct nouveau_grobj *sifm = ctx->sifm; int cs2d_format = nv04_region_cs2d_format(dst); int sifm_format = nv04_region_sifm_format(src); /* Max width & height may not be the same on all HW, but must be POT */ unsigned max_shift = 10; unsigned cw = 1 << max_shift; unsigned ch = 1 << max_shift; unsigned sx = dst->x >> max_shift; unsigned sy = dst->y >> max_shift; unsigned ex = (dst->x + w - 1) >> max_shift; unsigned ey = (dst->y + h - 1) >> max_shift; unsigned chunks = (ex - sx + 1) * (ey - sy + 1); unsigned chunk_size; if(dst->w < cw) cw = dst->w; if(dst->h < ch) ch = dst->h; chunk_size = cw * ch << dst->bpps; #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tRGN_COPY_SWIZZLE [%i, %i: %i] ", w, h, dst->bpps); for(int i = 0; i < 2; ++i) { nv04_region_print(i ? src : dst); fprintf(stderr, i ? "\n" : " <- "); } #endif nv04_region_assert(dst, w, h); nv04_region_assert(src, w, h); MARK_RING (chan, 8 + chunks * 17, 2 + chunks * 2); BEGIN_RING(chan, swzsurf, NV04_SWIZZLED_SURFACE_DMA_IMAGE, 1); OUT_RELOCo(chan, dst->bo, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); BEGIN_RING(chan, swzsurf, NV04_SWIZZLED_SURFACE_FORMAT, 1); OUT_RING (chan, cs2d_format | log2i(cw) << NV04_SWIZZLED_SURFACE_FORMAT_BASE_SIZE_U__SHIFT | log2i(ch) << NV04_SWIZZLED_SURFACE_FORMAT_BASE_SIZE_V__SHIFT); BEGIN_RING(chan, sifm, NV03_SCALED_IMAGE_FROM_MEMORY_DMA_IMAGE, 1); OUT_RELOCo(chan, src->bo, NOUVEAU_BO_GART | NOUVEAU_BO_VRAM | NOUVEAU_BO_RD); BEGIN_RING(chan, sifm, NV04_SCALED_IMAGE_FROM_MEMORY_SURFACE, 1); OUT_RING (chan, swzsurf->handle); assert(!(dst->offset & 63)); for (int cy = sy; cy <= ey; ++cy) { int ry = MAX2(0, (int)(dst->y - ch * cy)); int rh = MIN2((int)ch, (int)(dst->y - ch * cy + h)) - ry; for (int cx = sx; cx <= ex; ++cx) { int rx = MAX2(0, (int)(dst->x - cw * cx)); int rw = MIN2((int)cw, (int)(dst->x - cw * cx + w)) - rx; unsigned dst_offset; unsigned src_offset; BEGIN_RING(chan, swzsurf, NV04_SWIZZLED_SURFACE_OFFSET, 1); dst_offset = dst->offset + (nv04_swizzle_bits_2d(cx * cw, cy * ch, dst->w, dst->h) << dst->bpps); assert(dst_offset <= dst->bo->size); assert(dst_offset + chunk_size <= dst->bo->size); OUT_RELOCl(chan, dst->bo, dst_offset, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); BEGIN_RING(chan, sifm, NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_CONVERSION, 9); OUT_RING (chan, NV03_SCALED_IMAGE_FROM_MEMORY_COLOR_CONVERSION_TRUNCATE); OUT_RING (chan, sifm_format); OUT_RING (chan, NV03_SCALED_IMAGE_FROM_MEMORY_OPERATION_SRCCOPY); OUT_RING (chan, rx | (ry << NV03_SCALED_IMAGE_FROM_MEMORY_CLIP_POINT_Y__SHIFT)); OUT_RING (chan, rh << NV03_SCALED_IMAGE_FROM_MEMORY_CLIP_SIZE_H__SHIFT | rw); OUT_RING (chan, rx | (ry << NV03_SCALED_IMAGE_FROM_MEMORY_OUT_POINT_Y__SHIFT)); OUT_RING (chan, rh << NV03_SCALED_IMAGE_FROM_MEMORY_OUT_SIZE_H__SHIFT | rw); OUT_RING (chan, 1 << 20); OUT_RING (chan, 1 << 20); BEGIN_RING(chan, sifm, NV03_SCALED_IMAGE_FROM_MEMORY_SIZE, 4); OUT_RING (chan, rh << NV03_SCALED_IMAGE_FROM_MEMORY_SIZE_H__SHIFT | align(rw, 8)); OUT_RING (chan, src->pitch | NV03_SCALED_IMAGE_FROM_MEMORY_FORMAT_ORIGIN_CENTER | NV03_SCALED_IMAGE_FROM_MEMORY_FORMAT_FILTER_POINT_SAMPLE); src_offset = src->offset + (cy * ch + ry + src->y - dst->y) * src->pitch + ((cx * cw + rx + src->x - dst->x) << src->bpps); assert(src_offset <= src->bo->size); assert(src_offset + (src->pitch * (rh - 1)) + (rw << src->bpps) <= src->bo->size); OUT_RELOCl(chan, src->bo, src_offset, NOUVEAU_BO_GART | NOUVEAU_BO_VRAM | NOUVEAU_BO_RD); OUT_RING (chan, 0); } } } static inline void nv04_copy_m2mf_begin(struct nv04_2d_context *ctx, struct nouveau_bo* dstbo, struct nouveau_bo* srcbo, unsigned commands) { struct nouveau_channel *chan = ctx->m2mf->channel; struct nouveau_grobj *m2mf = ctx->m2mf; MARK_RING (chan, 3 + commands * 9, 2 + commands * 2); BEGIN_RING(chan, m2mf, NV04_M2MF_DMA_BUFFER_IN, 2); OUT_RELOCo(chan, srcbo, NOUVEAU_BO_GART | NOUVEAU_BO_VRAM | NOUVEAU_BO_RD); OUT_RELOCo(chan, dstbo, NOUVEAU_BO_GART | NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); } static inline void nv04_copy_m2mf_body(struct nv04_2d_context *ctx, struct nouveau_bo* dstbo, int* pdstoff, unsigned dstpitch, struct nouveau_bo* srcbo, int* psrcoff, unsigned srcpitch, unsigned size, unsigned lines) { struct nouveau_channel *chan = ctx->m2mf->channel; struct nouveau_grobj *m2mf = ctx->m2mf; #ifdef NV04_REGION_DEBUG fprintf(stderr, "\t\t\tCOPY_M2MF_BODY [%i, %i] <%i[%u]> lin %u <- <%i[%u]> lin %u\n", size, lines, dstbo->handle, *pdstoff, dstpitch, srcbo->handle, *psrcoff, srcpitch); #endif BEGIN_RING(chan, m2mf, NV04_M2MF_OFFSET_IN, 8); OUT_RELOCl(chan, srcbo, *psrcoff, NOUVEAU_BO_VRAM | NOUVEAU_BO_GART | NOUVEAU_BO_RD); OUT_RELOCl(chan, dstbo, *pdstoff, NOUVEAU_BO_VRAM | NOUVEAU_BO_GART | NOUVEAU_BO_WR); OUT_RING (chan, srcpitch); OUT_RING (chan, dstpitch); OUT_RING (chan, size); OUT_RING (chan, lines); OUT_RING (chan, 0x0101); OUT_RING (chan, 0); *psrcoff += srcpitch * lines; *pdstoff += dstpitch * lines; } static void nv04_copy_m2mf(struct nv04_2d_context *ctx, struct nouveau_bo* dstbo, int dstoff, unsigned dstpitch, struct nouveau_bo* srcbo, int srcoff, unsigned srcpitch, unsigned size, unsigned h) { unsigned max_pitch = 32767; unsigned max_lines = 2047; #ifdef NV04_REGION_DEBUG fprintf(stderr, "\t\tCOPY_M2MF [%i, %i] <%i[%i]> lin %u <- <%i[%i]> lin %u\n", size, h, dstbo->handle, dstoff, dstpitch, srcbo->handle, srcoff, srcpitch); #endif if(srcpitch <= max_pitch && dstpitch <= max_pitch) { unsigned full_pages = h / max_lines; unsigned leftover_lines = h - full_pages * max_lines; nv04_copy_m2mf_begin(ctx, dstbo, srcbo, full_pages + !!leftover_lines); for(unsigned i = 0; i < full_pages; ++i) nv04_copy_m2mf_body(ctx, dstbo, &dstoff, dstpitch, srcbo, &srcoff, srcpitch, size, max_lines); if(leftover_lines) nv04_copy_m2mf_body(ctx, dstbo, &dstoff, dstpitch, srcbo, &srcoff, srcpitch, size, leftover_lines); } else { unsigned lines = size / max_pitch; unsigned leftover = size - lines * max_pitch; unsigned full_pages = lines / max_lines; unsigned leftover_lines = lines - full_pages * max_lines; unsigned srcgap = srcpitch - size; unsigned dstgap = dstpitch - size; nv04_copy_m2mf_begin(ctx, dstbo, srcbo, h * (full_pages + !!leftover_lines + !!leftover)); for(unsigned i = 0; i < h; ++i) { for(unsigned j = 0; j < full_pages; ++j) nv04_copy_m2mf_body(ctx, dstbo, &dstoff, max_pitch, srcbo, &srcoff, max_pitch, max_pitch, max_lines); if(leftover_lines) nv04_copy_m2mf_body(ctx, dstbo, &dstoff, max_pitch, srcbo, &srcoff, max_pitch, max_pitch, leftover_lines); if(leftover) nv04_copy_m2mf_body(ctx, dstbo, &dstoff, leftover, srcbo, &srcoff, leftover, leftover, 1); srcoff += srcgap; dstoff += dstgap; } } } void nv04_memcpy(struct nv04_2d_context *ctx, struct nouveau_bo* dstbo, int dstoff, struct nouveau_bo* srcbo, int srcoff, unsigned size) { #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tMEMCPY [%i] <%i[%i]> <- <%i[%i]>\n", size, dstbo->handle, dstoff, srcbo->handle, srcoff); #endif nv04_copy_m2mf(ctx, dstbo, dstoff, size, srcbo, srcoff, size, size, 1); } static void nv04_region_copy_m2mf(struct nv04_2d_context *ctx, struct nv04_region *dst, struct nv04_region *src, int w, int h) { #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tRGN_COPY_M2MF [%i, %i: %i] ", w, h, dst->bpps); for(int i = 0; i < 2; ++i) { nv04_region_print(i ? src : dst); fprintf(stderr, i ? "\n" : " <- "); } #endif nv04_region_assert(dst, w, h); nv04_region_assert(src, w, h); assert(src->pitch); assert(dst->pitch); nv04_copy_m2mf(ctx, dst->bo, dst->offset + dst->y * dst->pitch + (dst->x << dst->bpps), dst->pitch, src->bo, src->offset + src->y * src->pitch + (src->x << src->bpps), src->pitch, w << src->bpps, h); } static inline void nv04_region_copy_blit(struct nv04_2d_context *ctx, struct nv04_region* dst, struct nv04_region* src, int w, int h) { struct nouveau_channel *chan = ctx->surf2d->channel; struct nouveau_grobj *surf2d = ctx->surf2d; struct nouveau_grobj *blit = ctx->blit; int cs2d_format = nv04_region_cs2d_format(dst); #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tRGN_COPY_BLIT [%i, %i: %i] ", w, h, dst->bpps); for(int i = 0; i < 2; ++i) { nv04_region_print(i ? src : dst); fprintf(stderr, i ? "\n" : " <- "); } #endif assert(!(src->pitch & 63) && src->pitch); assert(!(dst->pitch & 63) && dst->pitch); nv04_region_assert(dst, w, h); nv04_region_assert(src, w, h); MARK_RING (chan, 12, 4); BEGIN_RING(chan, surf2d, NV04_CONTEXT_SURFACES_2D_DMA_IMAGE_SOURCE, 2); OUT_RELOCo(chan, src->bo, NOUVEAU_BO_VRAM | NOUVEAU_BO_RD); OUT_RELOCo(chan, dst->bo, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); BEGIN_RING(chan, surf2d, NV04_CONTEXT_SURFACES_2D_FORMAT, 4); OUT_RING (chan, cs2d_format); OUT_RING (chan, (dst->pitch << 16) | src->pitch); OUT_RELOCl(chan, src->bo, src->offset, NOUVEAU_BO_VRAM | NOUVEAU_BO_RD); OUT_RELOCl(chan, dst->bo, dst->offset, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); BEGIN_RING(chan, blit, 0x0300, 3); OUT_RING (chan, (src->y << 16) | src->x); OUT_RING (chan, (dst->y << 16) | dst->x); OUT_RING (chan, ( h << 16) | w); } /* THEOREM: a non-linearizable swizzled destination is always 64 byte aligned, except for 4x2 mipmap levels of swizzled 1bpp surfaces * HYPOTESIS: * 1. The first mipmap level is 64-byte-aligned * PROOF: * 1. Thus, all mipmaps level with a parent which is 64-byte or more in size are. * 2. At 1bpp, the smallest levels with a <= 32-byte parent are either Nx1 or 1xN or size <=8, thus 4x2, 2x2 or 2x4 * 3. Nx1, 1xN, 2x4, 2x2 have all subrects linearizable. 4x2 does not. * 4. At 2/4bpp or more, the smallest levels with a 32-byte parent are 1xN, Nx1 or 2x2 * * However, nv04_region_align handles that. */ // 0 -> done, 1 -> do with 3D engine or CPU, -1 -> do with CPU // dst and src may be modified, and the possibly modified version should be passed to nv04_region_cpu if necessary int nv04_region_copy_2d(struct nv04_2d_context *ctx, struct nv04_region* dst, struct nv04_region* src, int w, int h, int dst_to_gpu, int src_on_gpu) { assert(src->bpps == dst->bpps); #ifdef NV04_REGION_DEBUG fprintf(stderr, "RGN_COPY [%i, %i: %i] ", w, h, dst->bpps); for(int i = 0; i < 2; ++i) { int gpu = i ? src_on_gpu : dst_to_gpu; nv04_region_print(i ? src : dst); fprintf(stderr, " %s", gpu ? "gpu" : "cpu"); fprintf(stderr, i ? "\n" : " <- "); } #endif // if they are contiguous and either both swizzled or both linear, reshape if(!dst->pitch == !src->pitch && nv04_region_is_contiguous(dst, w, h) && nv04_region_is_contiguous(src, w, h)) { nv04_region_contiguous_shape(dst, &w, &h, 6); nv04_region_linearize_contiguous(dst, w, h); nv04_region_linearize_contiguous(src, w, h); } #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tOPT "); for(int i = 0; i < 2; ++i) { nv04_region_print(i ? src : dst); fprintf(stderr, i ? "\n" : " <- "); } #endif /* if the destination is not for GPU _and_ source is on CPU, use CPU */ /* if the destination is not for GPU _or_ source is on CPU, use CPU only if we think it's faster than the GPU */ /* TODO: benchmark to find out in which cases exactly we should prefer the CPU */ if((!dst_to_gpu && !src_on_gpu) || (!dst->pitch && dst->d > 1) /* 3D swizzled destination are unwritable by the GPU, and 2D swizzled ones are readable only by the 3D engine */ ) return -1; /* there is no known way to read 2D/3D-swizzled surfaces with the 2D engine * ask the caller to use the 3D engine * If a format cannot be sampled from the 3D engine there is no point in making it swizzled, so we must not do so */ else if(!src->pitch) { #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tCOPY_ENG3D\n"); #endif return 1; } /* Setup transfer to swizzle the texture to vram if needed */ else { if (!dst->pitch) { if(!dst_to_gpu) { #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tCOPY_ENG3D\n"); #endif return 1; } else { assert(!nv04_region_align(dst, w, h, 6)); nv04_region_copy_swizzle(ctx, dst, src, w, h); return 0; } } else { /* NV_CONTEXT_SURFACES_2D has buffer alignment restrictions, fallback * to NV_M2MF in this case. * TODO: is this also true for the source? possibly not * TODO: should we just always use m2mf? * TODO: if not, add support for multiple operations to copy_blit */ if (!dst_to_gpu || w > 2047 || h > 2047 || (w & 1) || nv04_region_align(src, w, h, 6) || nv04_region_align(dst, w, h, 6) ) nv04_region_copy_m2mf(ctx, dst, src, w, h); else nv04_region_copy_blit(ctx, dst, src, w, h); return 0; } } } static inline void nv04_region_fill_gdirect(struct nv04_2d_context *ctx, struct nv04_region* dst, int w, int h, unsigned value) { struct nouveau_channel *chan = ctx->surf2d->channel; struct nouveau_grobj *surf2d = ctx->surf2d; struct nouveau_grobj *rect = ctx->rect; int cs2d_format, gdirect_format; #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tFILL_GDIRECT\n"); #endif assert(!(dst->pitch & 63) && dst->pitch); nv04_region_assert(dst, w, h); switch(dst->bpps) { case 0: gdirect_format = NV04_GDI_RECTANGLE_TEXT_COLOR_FORMAT_A8R8G8B8; cs2d_format = NV04_CONTEXT_SURFACES_2D_FORMAT_Y8; break; case 1: gdirect_format = NV04_GDI_RECTANGLE_TEXT_COLOR_FORMAT_A16R5G6B5; cs2d_format = NV04_CONTEXT_SURFACES_2D_FORMAT_Y16; break; case 2: gdirect_format = NV04_GDI_RECTANGLE_TEXT_COLOR_FORMAT_A8R8G8B8; cs2d_format = NV04_CONTEXT_SURFACES_2D_FORMAT_Y32; break; default: assert(0); gdirect_format = 0; cs2d_format = 0; break; } MARK_RING (chan, 15, 4); BEGIN_RING(chan, surf2d, NV04_CONTEXT_SURFACES_2D_DMA_IMAGE_SOURCE, 2); OUT_RELOCo(chan, dst->bo, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); OUT_RELOCo(chan, dst->bo, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); BEGIN_RING(chan, surf2d, NV04_CONTEXT_SURFACES_2D_FORMAT, 4); OUT_RING (chan, cs2d_format); OUT_RING (chan, (dst->pitch << 16) | dst->pitch); OUT_RELOCl(chan, dst->bo, dst->offset, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); OUT_RELOCl(chan, dst->bo, dst->offset, NOUVEAU_BO_VRAM | NOUVEAU_BO_WR); BEGIN_RING(chan, rect, NV04_GDI_RECTANGLE_TEXT_COLOR_FORMAT, 1); OUT_RING (chan, gdirect_format); BEGIN_RING(chan, rect, NV04_GDI_RECTANGLE_TEXT_COLOR1_A, 1); OUT_RING (chan, value); BEGIN_RING(chan, rect, NV04_GDI_RECTANGLE_TEXT_UNCLIPPED_RECTANGLE_POINT(0), 2); OUT_RING (chan, (dst->x << 16) | dst->y); OUT_RING (chan, ( w << 16) | h); } int nv04_region_fill_2d(struct nv04_2d_context *ctx, struct nv04_region *dst, int w, int h, unsigned value) { if(!w || !h) return 0; #ifdef NV04_REGION_DEBUG fprintf(stderr, "FILL [%i, %i: %i] ", w, h, dst->bpps); nv04_region_print(dst); fprintf(stderr, " <- 0x%x\n", value); #endif if(nv04_region_is_contiguous(dst, w, h)) { nv04_region_contiguous_shape(dst, &w, &h, 6); nv04_region_linearize_contiguous(dst, w, h); } // TODO: maybe do intermediate copies for some cases instead of using the 3D engine/CPU /* GdiRect doesn't work together with swzsurf, so the 3D engine, or an intermediate copy, is the only option here */ if(!dst->pitch) { #ifdef NV04_REGION_DEBUG fprintf(stderr, "\tFILL_ENG3D\n"); #endif return 1; } else if(!nv04_region_align(dst, w, h, 6)) { nv04_region_fill_gdirect(ctx, dst, w, h, value); return 0; } else return -1; } void nv04_2d_context_takedown(struct nv04_2d_context *ctx) { nouveau_notifier_free(&ctx->ntfy); nouveau_grobj_free(&ctx->m2mf); nouveau_grobj_free(&ctx->surf2d); nouveau_grobj_free(&ctx->swzsurf); nouveau_grobj_free(&ctx->rect); nouveau_grobj_free(&ctx->blit); nouveau_grobj_free(&ctx->sifm); free(ctx); } struct nv04_2d_context * nv04_2d_context_init(struct nouveau_channel* chan) { struct nv04_2d_context *ctx = calloc(1, sizeof(struct nv04_2d_context)); unsigned handle = 0x88000000, class; int ret; if (!ctx) return NULL; ret = nouveau_notifier_alloc(chan, handle++, 1, &ctx->ntfy); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } ret = nouveau_grobj_alloc(chan, handle++, 0x0039, &ctx->m2mf); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } BEGIN_RING(chan, ctx->m2mf, NV04_M2MF_DMA_NOTIFY, 1); OUT_RING (chan, ctx->ntfy->handle); if (chan->device->chipset < 0x10) class = NV04_CONTEXT_SURFACES_2D; else class = NV10_CONTEXT_SURFACES_2D; ret = nouveau_grobj_alloc(chan, handle++, class, &ctx->surf2d); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } BEGIN_RING(chan, ctx->surf2d, NV04_CONTEXT_SURFACES_2D_DMA_IMAGE_SOURCE, 2); OUT_RING (chan, chan->vram->handle); OUT_RING (chan, chan->vram->handle); if (chan->device->chipset < 0x10) class = NV04_IMAGE_BLIT; else class = NV11_IMAGE_BLIT; ret = nouveau_grobj_alloc(chan, handle++, class, &ctx->blit); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } BEGIN_RING(chan, ctx->blit, NV01_IMAGE_BLIT_DMA_NOTIFY, 1); OUT_RING (chan, ctx->ntfy->handle); BEGIN_RING(chan, ctx->blit, NV04_IMAGE_BLIT_SURFACES, 1); OUT_RING (chan, ctx->surf2d->handle); BEGIN_RING(chan, ctx->blit, NV01_IMAGE_BLIT_OPERATION, 1); OUT_RING (chan, NV01_IMAGE_BLIT_OPERATION_SRCCOPY); ret = nouveau_grobj_alloc(chan, handle++, NV04_GDI_RECTANGLE_TEXT, &ctx->rect); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } BEGIN_RING(chan, ctx->rect, NV04_GDI_RECTANGLE_TEXT_DMA_NOTIFY, 1); OUT_RING (chan, ctx->ntfy->handle); BEGIN_RING(chan, ctx->rect, NV04_GDI_RECTANGLE_TEXT_SURFACE, 1); OUT_RING (chan, ctx->surf2d->handle); BEGIN_RING(chan, ctx->rect, NV04_GDI_RECTANGLE_TEXT_OPERATION, 1); OUT_RING (chan, NV04_GDI_RECTANGLE_TEXT_OPERATION_SRCCOPY); BEGIN_RING(chan, ctx->rect, NV04_GDI_RECTANGLE_TEXT_MONOCHROME_FORMAT, 1); OUT_RING (chan, NV04_GDI_RECTANGLE_TEXT_MONOCHROME_FORMAT_LE); switch (chan->device->chipset & 0xf0) { case 0x00: case 0x10: class = NV04_SWIZZLED_SURFACE; break; case 0x20: class = NV11_SWIZZLED_SURFACE; break; case 0x30: class = NV30_SWIZZLED_SURFACE; break; case 0x40: case 0x60: class = NV40_SWIZZLED_SURFACE; break; default: /* Famous last words: this really can't happen.. */ assert(0); break; } ret = nouveau_grobj_alloc(chan, handle++, class, &ctx->swzsurf); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } /* all the Gallium MARK_RING calculations assume no autobinding, so do that now */ if(ctx->swzsurf->bound == NOUVEAU_GROBJ_UNBOUND) nouveau_grobj_autobind(ctx->swzsurf); switch (chan->device->chipset & 0xf0) { case 0x10: case 0x20: class = NV10_SCALED_IMAGE_FROM_MEMORY; break; case 0x30: class = NV30_SCALED_IMAGE_FROM_MEMORY; break; case 0x40: case 0x60: class = NV40_SCALED_IMAGE_FROM_MEMORY; break; default: class = NV04_SCALED_IMAGE_FROM_MEMORY; break; } ret = nouveau_grobj_alloc(chan, handle++, class, &ctx->sifm); if (ret) { nv04_2d_context_takedown(ctx); return NULL; } /* all the Gallium MARK_RING calculations assume no autobinding, so do that now */ if(ctx->sifm->bound == NOUVEAU_GROBJ_UNBOUND) nouveau_grobj_autobind(ctx->sifm); return ctx; }