/* * Copyright (C) 2008 VMware, Inc. * Copyright (C) 2014 Broadcom * Copyright (C) 2018-2019 Alyssa Rosenzweig * Copyright (C) 2019-2020 Collabora, Ltd. * * 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, sublicense, * 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 above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * 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 NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS 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. * */ #include "util/macros.h" #include "util/u_math.h" #include "pan_texture.h" /* Generates a texture descriptor. Ideally, descriptors are immutable after the * texture is created, so we can keep these hanging around in GPU memory in a * dedicated BO and not have to worry. In practice there are some minor gotchas * with this (the driver sometimes will change the format of a texture on the * fly for compression) but it's fast enough to just regenerate the descriptor * in those cases, rather than monkeypatching at drawtime. * * A texture descriptor consists of a 32-byte mali_texture_descriptor structure * followed by a variable number of pointers. Due to this variance and * potentially large size, we actually upload directly rather than returning * the descriptor. Whether the user does a copy themselves or not is irrelevant * to us here. */ /* Check if we need to set a custom stride by computing the "expected" * stride and comparing it to what the user actually wants. Only applies * to linear textures, since tiled/compressed textures have strict * alignment requirements for their strides as it is */ static bool panfrost_needs_explicit_stride( struct panfrost_slice *slices, uint16_t width, unsigned first_level, unsigned last_level, unsigned bytes_per_pixel) { for (unsigned l = first_level; l <= last_level; ++l) { unsigned actual = slices[l].stride; unsigned expected = u_minify(width, l) * bytes_per_pixel; if (actual != expected) return true; } return false; } /* A Scalable Texture Compression (ASTC) corresponds to just a few texture type * in the hardware, but in fact can be parametrized to have various widths and * heights for the so-called "stretch factor". It turns out these parameters * are stuffed in the bottom bits of the payload pointers. This functions * computes these magic stuffing constants based on the ASTC format in use. The * constant in a given dimension is 3-bits, and two are stored side-by-side for * each active dimension. */ static unsigned panfrost_astc_stretch(unsigned dim) { assert(dim >= 4 && dim <= 12); return MIN2(dim, 11) - 4; } /* Texture addresses are tagged with information about compressed formats. * AFBC uses a bit for whether the colorspace transform is enabled (RGB and * RGBA only). * For ASTC, this is a "stretch factor" encoding the block size. */ static unsigned panfrost_compression_tag( const struct util_format_description *desc, enum mali_format format, enum mali_texture_layout layout) { if (layout == MALI_TEXTURE_AFBC) return desc->nr_channels >= 3; else if (format == MALI_ASTC_HDR_SUPP || format == MALI_ASTC_SRGB_SUPP) return (panfrost_astc_stretch(desc->block.height) << 3) | panfrost_astc_stretch(desc->block.width); else return 0; } /* Cubemaps have 6 faces as "layers" in between each actual layer. We * need to fix this up. TODO: logic wrong in the asserted out cases ... * can they happen, perhaps from cubemap arrays? */ static void panfrost_adjust_cube_dimensions( unsigned *first_face, unsigned *last_face, unsigned *first_layer, unsigned *last_layer) { *first_face = *first_layer % 6; *last_face = *last_layer % 6; *first_layer /= 6; *last_layer /= 6; assert((*first_layer == *last_layer) || (*first_face == 0 && *last_face == 5)); } /* Following the texture descriptor is a number of pointers. How many? */ static unsigned panfrost_texture_num_elements( unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, bool is_cube, bool manual_stride) { unsigned first_face = 0, last_face = 0; if (is_cube) { panfrost_adjust_cube_dimensions(&first_face, &last_face, &first_layer, &last_layer); } unsigned levels = 1 + last_level - first_level; unsigned layers = 1 + last_layer - first_layer; unsigned faces = 1 + last_face - first_face; unsigned num_elements = levels * layers * faces; if (manual_stride) num_elements *= 2; return num_elements; } /* Conservative estimate of the size of the texture payload a priori. * Average case, size equal to the actual size. Worst case, off by 2x (if * a manual stride is not needed on a linear texture). Returned value * must be greater than or equal to the actual size, so it's safe to use * as an allocation amount */ unsigned panfrost_estimate_texture_payload_size( unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, enum mali_texture_type type, enum mali_texture_layout layout) { /* Assume worst case */ unsigned manual_stride = (layout == MALI_TEXTURE_LINEAR); unsigned elements = panfrost_texture_num_elements( first_level, last_level, first_layer, last_layer, type == MALI_TEX_CUBE, manual_stride); return sizeof(mali_ptr) * elements; } /* Bifrost requires a tile stride for tiled textures. This stride is computed * as (16 * bpp * width) assuming there is at least one tile (width >= 16). * Otherwise if width < 16, the blob puts zero. Interactions with AFBC are * currently unknown. */ static unsigned panfrost_nonlinear_stride(enum mali_texture_layout layout, unsigned bytes_per_pixel, unsigned width) { if (layout == MALI_TEXTURE_TILED) { return (width < 16) ? 0 : (16 * bytes_per_pixel * ALIGN_POT(width, 16)); } else { unreachable("TODO: AFBC on Bifrost"); } } static void panfrost_emit_texture_payload( mali_ptr *payload, const struct util_format_description *desc, enum mali_format mali_format, enum mali_texture_type type, enum mali_texture_layout layout, unsigned width, unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, unsigned cube_stride, bool manual_stride, mali_ptr base, struct panfrost_slice *slices) { base |= panfrost_compression_tag(desc, mali_format, layout); /* Inject the addresses in, interleaving array indices, mip levels, * cube faces, and strides in that order */ unsigned first_face = 0, last_face = 0, face_mult = 1; if (type == MALI_TEX_CUBE) { face_mult = 6; panfrost_adjust_cube_dimensions(&first_face, &last_face, &first_layer, &last_layer); } unsigned idx = 0; for (unsigned w = first_layer; w <= last_layer; ++w) { for (unsigned l = first_level; l <= last_level; ++l) { for (unsigned f = first_face; f <= last_face; ++f) { payload[idx++] = base + panfrost_texture_offset( slices, type == MALI_TEX_3D, cube_stride, l, w * face_mult + f); if (manual_stride) { payload[idx++] = (layout == MALI_TEXTURE_LINEAR) ? slices[l].stride : panfrost_nonlinear_stride(layout, MAX2(desc->block.bits / 8, 1), u_minify(width, l)); } } } } } void panfrost_new_texture( void *out, uint16_t width, uint16_t height, uint16_t depth, uint16_t array_size, enum pipe_format format, enum mali_texture_type type, enum mali_texture_layout layout, unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, unsigned cube_stride, unsigned swizzle, mali_ptr base, struct panfrost_slice *slices) { const struct util_format_description *desc = util_format_description(format); unsigned bytes_per_pixel = util_format_get_blocksize(format); enum mali_format mali_format = panfrost_pipe_format_table[desc->format].hw; assert(mali_format); bool manual_stride = (layout == MALI_TEXTURE_LINEAR) && panfrost_needs_explicit_stride(slices, width, first_level, last_level, bytes_per_pixel); struct mali_texture_descriptor descriptor = { .width = MALI_POSITIVE(u_minify(width, first_level)), .height = MALI_POSITIVE(u_minify(height, first_level)), .depth = MALI_POSITIVE(u_minify(depth, first_level)), .array_size = MALI_POSITIVE(array_size), .format = { .swizzle = panfrost_translate_swizzle_4(desc->swizzle), .format = mali_format, .srgb = (desc->colorspace == UTIL_FORMAT_COLORSPACE_SRGB), .type = type, .layout = layout, .manual_stride = manual_stride, .unknown2 = 1, }, .levels = last_level - first_level, .swizzle = swizzle }; memcpy(out, &descriptor, sizeof(descriptor)); mali_ptr *payload = (mali_ptr *) (out + sizeof(struct mali_texture_descriptor)); panfrost_emit_texture_payload( payload, desc, mali_format, type, layout, width, first_level, last_level, first_layer, last_layer, cube_stride, manual_stride, base, slices); } void panfrost_new_texture_bifrost( struct bifrost_texture_descriptor *descriptor, uint16_t width, uint16_t height, uint16_t depth, uint16_t array_size, enum pipe_format format, enum mali_texture_type type, enum mali_texture_layout layout, unsigned first_level, unsigned last_level, unsigned first_layer, unsigned last_layer, unsigned cube_stride, unsigned swizzle, mali_ptr base, struct panfrost_slice *slices, struct panfrost_bo *payload) { const struct util_format_description *desc = util_format_description(format); enum mali_format mali_format = panfrost_pipe_format_table[desc->format].hw; assert(mali_format); panfrost_emit_texture_payload( (mali_ptr *) payload->cpu, desc, mali_format, type, layout, width, first_level, last_level, first_layer, last_layer, cube_stride, true, /* Stride explicit on Bifrost */ base, slices); descriptor->format_unk = 0x2; descriptor->type = type; descriptor->format = mali_format; descriptor->srgb = (desc->colorspace == UTIL_FORMAT_COLORSPACE_SRGB); descriptor->format_unk3 = 0x0; descriptor->width = MALI_POSITIVE(u_minify(width, first_level)); descriptor->height = MALI_POSITIVE(u_minify(height, first_level)); descriptor->swizzle = swizzle; descriptor->layout = layout; descriptor->levels = last_level - first_level; descriptor->unk1 = 0x0; descriptor->levels_unk = 0; descriptor->level_2 = 0; descriptor->payload = payload->gpu; descriptor->array_size = MALI_POSITIVE(array_size); descriptor->unk4 = 0x0; descriptor->depth = MALI_POSITIVE(u_minify(depth, first_level)); descriptor->unk5 = 0x0; } /* Computes sizes for checksumming, which is 8 bytes per 16x16 tile. * Checksumming is believed to be a CRC variant (CRC64 based on the size?). * This feature is also known as "transaction elimination". */ #define CHECKSUM_TILE_WIDTH 16 #define CHECKSUM_TILE_HEIGHT 16 #define CHECKSUM_BYTES_PER_TILE 8 unsigned panfrost_compute_checksum_size( struct panfrost_slice *slice, unsigned width, unsigned height) { unsigned aligned_width = ALIGN_POT(width, CHECKSUM_TILE_WIDTH); unsigned aligned_height = ALIGN_POT(height, CHECKSUM_TILE_HEIGHT); unsigned tile_count_x = aligned_width / CHECKSUM_TILE_WIDTH; unsigned tile_count_y = aligned_height / CHECKSUM_TILE_HEIGHT; slice->checksum_stride = tile_count_x * CHECKSUM_BYTES_PER_TILE; return slice->checksum_stride * tile_count_y; } unsigned panfrost_get_layer_stride(struct panfrost_slice *slices, bool is_3d, unsigned cube_stride, unsigned level) { return is_3d ? slices[level].size0 : cube_stride; } /* Computes the offset into a texture at a particular level/face. Add to * the base address of a texture to get the address to that level/face */ unsigned panfrost_texture_offset(struct panfrost_slice *slices, bool is_3d, unsigned cube_stride, unsigned level, unsigned face) { unsigned layer_stride = panfrost_get_layer_stride(slices, is_3d, cube_stride, level); return slices[level].offset + (face * layer_stride); }