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mpv/video/out/placebo/ra_pl.c

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vo_gpu: vulkan: use libplacebo instead This commit rips out the entire mpv vulkan implementation in favor of exposing lightweight wrappers on top of libplacebo instead, which provides much of the same except in a more up-to-date and polished form. This (finally) unifies the code base between mpv and libplacebo, which is something I've been hoping to do for a long time. Note: The ra_pl wrappers are abstract enough from the actual libplacebo device type that we can in theory re-use them for other devices like d3d11 or even opengl in the future, so I moved them to a separate directory for the time being. However, the rest of the code is still vulkan-specific, so I've kept the "vulkan" naming and file paths, rather than introducing a new `--gpu-api` type. (Which would have been ended up with significantly more code duplicaiton) Plus, the code and functionality is similar enough that for most users this should just be a straight-up drop-in replacement. Note: This commit excludes some changes; specifically, the updates to context_win and hwdec_cuda are deferred to separate commits for authorship reasons.
2018-11-10 12:53:33 +01:00
#include "common/common.h"
#include "common/msg.h"
#include "ra_pl.h"
#include "utils.h"
struct ra_pl {
const struct pl_gpu *gpu;
};
static inline const struct pl_gpu *get_gpu(struct ra *ra)
{
struct ra_pl *p = ra->priv;
return p->gpu;
}
static struct ra_fns ra_fns_pl;
struct ra *ra_create_pl(const struct pl_gpu *gpu, struct mp_log *log)
{
assert(gpu);
struct ra *ra = talloc_zero(NULL, struct ra);
ra->log = log;
ra->fns = &ra_fns_pl;
struct ra_pl *p = ra->priv = talloc_zero(ra, struct ra_pl);
p->gpu = gpu;
ra->glsl_version = gpu->glsl.version;
ra->glsl_vulkan = gpu->glsl.vulkan;
ra->glsl_es = gpu->glsl.gles;
ra->caps = RA_CAP_DIRECT_UPLOAD | RA_CAP_NESTED_ARRAY | RA_CAP_FRAGCOORD;
if (gpu->caps & PL_GPU_CAP_COMPUTE)
ra->caps |= RA_CAP_COMPUTE | RA_CAP_NUM_GROUPS;
if (gpu->caps & PL_GPU_CAP_PARALLEL_COMPUTE)
ra->caps |= RA_CAP_PARALLEL_COMPUTE;
if (gpu->caps & PL_GPU_CAP_INPUT_VARIABLES)
ra->caps |= RA_CAP_GLOBAL_UNIFORM;
if (gpu->limits.max_tex_1d_dim)
ra->caps |= RA_CAP_TEX_1D;
if (gpu->limits.max_tex_3d_dim)
ra->caps |= RA_CAP_TEX_3D;
if (gpu->limits.max_ubo_size)
ra->caps |= RA_CAP_BUF_RO;
if (gpu->limits.max_ssbo_size)
ra->caps |= RA_CAP_BUF_RW;
if (gpu->limits.min_gather_offset && gpu->limits.max_gather_offset)
ra->caps |= RA_CAP_GATHER;
// Semi-hack: assume all textures are blittable if r8 is
const struct pl_fmt *r8 = pl_find_named_fmt(gpu, "r8");
if (r8->caps & PL_FMT_CAP_BLITTABLE)
ra->caps |= RA_CAP_BLIT;
ra->max_texture_wh = gpu->limits.max_tex_2d_dim;
ra->max_shmem = gpu->limits.max_shmem_size;
ra->max_pushc_size = gpu->limits.max_pushc_size;
// Set up format wrappers
for (int i = 0; i < gpu->num_formats; i++) {
const struct pl_fmt *plfmt = gpu->formats[i];
static const enum ra_ctype fmt_type_map[PL_FMT_TYPE_COUNT] = {
[PL_FMT_UNORM] = RA_CTYPE_UNORM,
[PL_FMT_UINT] = RA_CTYPE_UINT,
[PL_FMT_FLOAT] = RA_CTYPE_FLOAT,
};
enum ra_ctype type = fmt_type_map[plfmt->type];
if (!type || !(plfmt->caps & PL_FMT_CAP_SAMPLEABLE))
continue;
struct ra_format *rafmt = talloc_zero(ra, struct ra_format);
*rafmt = (struct ra_format) {
.name = plfmt->name,
.priv = (void *) plfmt,
.ctype = type,
.ordered = pl_fmt_is_ordered(plfmt),
.num_components = plfmt->num_components,
.pixel_size = plfmt->texel_size,
.linear_filter = plfmt->caps & PL_FMT_CAP_LINEAR,
.renderable = plfmt->caps & PL_FMT_CAP_RENDERABLE,
.glsl_format = plfmt->glsl_format,
};
for (int c = 0; c < plfmt->num_components; c++) {
rafmt->component_size[c] = plfmt->host_bits[c];
rafmt->component_depth[c] = plfmt->component_depth[c];
}
MP_TARRAY_APPEND(ra, ra->formats, ra->num_formats, rafmt);
}
return ra;
}
static void destroy_ra_pl(struct ra *ra)
{
talloc_free(ra);
}
static struct ra_format *map_fmt(struct ra *ra, const struct pl_fmt *plfmt)
{
for (int i = 0; i < ra->num_formats; i++) {
if (ra->formats[i]->priv == plfmt)
return ra->formats[i];
}
MP_ERR(ra, "Failed mapping pl_fmt '%s' to ra_fmt?\n", plfmt->name);
return NULL;
}
bool mppl_wrap_tex(struct ra *ra, const struct pl_tex *pltex,
struct ra_tex *out_tex)
{
if (!pltex)
return false;
*out_tex = (struct ra_tex) {
.params = {
.dimensions = pl_tex_params_dimension(pltex->params),
.w = pltex->params.w,
.h = pltex->params.h,
.d = pltex->params.d,
.format = map_fmt(ra, pltex->params.format),
.render_src = pltex->params.sampleable,
.render_dst = pltex->params.renderable,
.storage_dst = pltex->params.storable,
.blit_src = pltex->params.blit_src,
.blit_dst = pltex->params.blit_dst,
.host_mutable = pltex->params.host_writable,
.downloadable = pltex->params.host_readable,
.src_linear = pltex->params.sample_mode == PL_TEX_SAMPLE_LINEAR,
.src_repeat = pltex->params.address_mode == PL_TEX_ADDRESS_REPEAT,
},
.priv = (void *) pltex,
};
return !!out_tex->params.format;
}
static struct ra_tex *tex_create_pl(struct ra *ra,
const struct ra_tex_params *params)
{
const struct pl_gpu *gpu = get_gpu(ra);
// Check size limits
bool ok = false;
switch (params->dimensions) {
case 1:
ok = params->w <= gpu->limits.max_tex_1d_dim;
break;
case 2:
ok = params->w <= gpu->limits.max_tex_2d_dim &&
params->h <= gpu->limits.max_tex_2d_dim;
break;
case 3:
ok = params->w <= gpu->limits.max_tex_2d_dim &&
params->h <= gpu->limits.max_tex_2d_dim &&
params->d <= gpu->limits.max_tex_2d_dim;
break;
};
if (!ok) {
MP_ERR(ra, "Texture size %dx%dx%d exceeds dimension limits!\n",
params->w, params->h, params->d);
return NULL;
}
const struct pl_tex *pltex = pl_tex_create(gpu, &(struct pl_tex_params) {
.w = params->w,
.h = params->dimensions >= 2 ? params->h : 0,
.d = params->dimensions >= 3 ? params->d : 0,
.format = params->format->priv,
.sampleable = params->render_src,
.renderable = params->render_dst,
.storable = params->storage_dst,
.blit_src = params->blit_src,
.blit_dst = params->blit_dst || params->render_dst,
.host_writable = params->host_mutable,
.host_readable = params->downloadable,
.sample_mode = params->src_linear ? PL_TEX_SAMPLE_LINEAR
: PL_TEX_SAMPLE_NEAREST,
.address_mode = params->src_repeat ? PL_TEX_ADDRESS_REPEAT
: PL_TEX_ADDRESS_CLAMP,
.initial_data = params->initial_data,
});
struct ra_tex *ratex = talloc_ptrtype(NULL, ratex);
if (!mppl_wrap_tex(ra, pltex, ratex)) {
pl_tex_destroy(gpu, &pltex);
talloc_free(ratex);
return NULL;
}
return ratex;
}
static void tex_destroy_pl(struct ra *ra, struct ra_tex *tex)
{
if (!tex)
return;
pl_tex_destroy(get_gpu(ra), (const struct pl_tex **) &tex->priv);
talloc_free(tex);
}
static int texel_stride_w(size_t stride, const struct pl_tex *tex)
{
size_t texel_size = tex->params.format->texel_size;
int texels = stride / texel_size;
assert(texels * texel_size == stride);
return texels;
}
static bool tex_upload_pl(struct ra *ra, const struct ra_tex_upload_params *params)
{
const struct pl_tex *tex = params->tex->priv;
struct pl_tex_transfer_params pl_params = {
.tex = tex,
.buf = params->buf ? params->buf->priv : NULL,
.buf_offset = params->buf_offset,
.ptr = (void *) params->src,
};
if (params->tex->params.dimensions == 2) {
pl_params.stride_w = texel_stride_w(params->stride, tex);
if (params->rc) {
pl_params.rc = (struct pl_rect3d) {
.x0 = params->rc->x0, .x1 = params->rc->x1,
.y0 = params->rc->y0, .y1 = params->rc->y1,
};
}
}
return pl_tex_upload(get_gpu(ra), &pl_params);
}
static bool tex_download_pl(struct ra *ra, struct ra_tex_download_params *params)
{
const struct pl_tex *tex = params->tex->priv;
struct pl_tex_transfer_params pl_params = {
.tex = tex,
.ptr = params->dst,
.stride_w = texel_stride_w(params->stride, tex),
};
return pl_tex_download(get_gpu(ra), &pl_params);
}
static struct ra_buf *buf_create_pl(struct ra *ra,
const struct ra_buf_params *params)
{
static const enum pl_buf_type buf_type[] = {
[RA_BUF_TYPE_TEX_UPLOAD] = PL_BUF_TEX_TRANSFER,
[RA_BUF_TYPE_SHADER_STORAGE] = PL_BUF_STORAGE,
[RA_BUF_TYPE_UNIFORM] = PL_BUF_UNIFORM,
[RA_BUF_TYPE_SHARED_MEMORY] = 0,
};
const struct pl_gpu *gpu = get_gpu(ra);
size_t max_size[] = {
[PL_BUF_TEX_TRANSFER] = gpu->limits.max_xfer_size,
[PL_BUF_UNIFORM] = gpu->limits.max_ubo_size,
[PL_BUF_STORAGE] = gpu->limits.max_ssbo_size,
};
if (params->size > max_size[buf_type[params->type]]) {
MP_ERR(ra, "Buffer size %zu exceeds size limits!\n", params->size);
return NULL;
}
const struct pl_buf *plbuf = pl_buf_create(gpu, &(struct pl_buf_params) {
.type = buf_type[params->type],
.size = params->size,
.host_mapped = params->host_mapped,
.host_writable = params->host_mutable,
.initial_data = params->initial_data,
});
if (!plbuf)
return NULL;
struct ra_buf *rabuf = talloc_ptrtype(NULL, rabuf);
*rabuf = (struct ra_buf) {
.params = *params,
.data = plbuf->data,
.priv = (void *) plbuf,
};
rabuf->params.initial_data = NULL;
return rabuf;
}
static void buf_destroy_pl(struct ra *ra, struct ra_buf *buf)
{
if (!buf)
return;
pl_buf_destroy(get_gpu(ra), (const struct pl_buf **) &buf->priv);
talloc_free(buf);
}
static void buf_update_pl(struct ra *ra, struct ra_buf *buf, ptrdiff_t offset,
const void *data, size_t size)
{
pl_buf_write(get_gpu(ra), buf->priv, offset, data, size);
}
static bool buf_poll_pl(struct ra *ra, struct ra_buf *buf)
{
return !pl_buf_poll(get_gpu(ra), buf->priv, 0);
}
static void clear_pl(struct ra *ra, struct ra_tex *dst, float color[4],
struct mp_rect *scissor)
{
// TODO: implement scissor clearing by bltting a 1x1 tex instead
pl_tex_clear(get_gpu(ra), dst->priv, color);
}
static void blit_pl(struct ra *ra, struct ra_tex *dst, struct ra_tex *src,
struct mp_rect *dst_rc, struct mp_rect *src_rc)
{
struct pl_rect3d plsrc = {0}, pldst = {0};
if (src_rc) {
plsrc.x0 = MPMIN(MPMAX(src_rc->x0, 0), src->params.w);
plsrc.y0 = MPMIN(MPMAX(src_rc->y0, 0), src->params.h);
plsrc.x1 = MPMIN(MPMAX(src_rc->x1, 0), src->params.w);
plsrc.y1 = MPMIN(MPMAX(src_rc->y1, 0), src->params.h);
}
if (dst_rc) {
pldst.x0 = MPMIN(MPMAX(dst_rc->x0, 0), dst->params.w);
pldst.y0 = MPMIN(MPMAX(dst_rc->y0, 0), dst->params.h);
pldst.x1 = MPMIN(MPMAX(dst_rc->x1, 0), dst->params.w);
pldst.y1 = MPMIN(MPMAX(dst_rc->y1, 0), dst->params.h);
}
pl_tex_blit(get_gpu(ra), dst->priv, src->priv, pldst, plsrc);
}
static const enum pl_var_type var_type[RA_VARTYPE_COUNT] = {
[RA_VARTYPE_INT] = PL_VAR_SINT,
[RA_VARTYPE_FLOAT] = PL_VAR_FLOAT,
};
static const enum pl_desc_type desc_type[RA_VARTYPE_COUNT] = {
[RA_VARTYPE_TEX] = PL_DESC_SAMPLED_TEX,
[RA_VARTYPE_IMG_W] = PL_DESC_STORAGE_IMG,
[RA_VARTYPE_BUF_RO] = PL_DESC_BUF_UNIFORM,
[RA_VARTYPE_BUF_RW] = PL_DESC_BUF_STORAGE,
};
static const enum pl_fmt_type fmt_type[RA_VARTYPE_COUNT] = {
[RA_VARTYPE_INT] = PL_FMT_SINT,
[RA_VARTYPE_FLOAT] = PL_FMT_FLOAT,
[RA_VARTYPE_BYTE_UNORM] = PL_FMT_UNORM,
};
static const size_t var_size[RA_VARTYPE_COUNT] = {
[RA_VARTYPE_INT] = sizeof(int),
[RA_VARTYPE_FLOAT] = sizeof(float),
[RA_VARTYPE_BYTE_UNORM] = sizeof(uint8_t),
};
static struct ra_layout uniform_layout_pl(struct ra_renderpass_input *inp)
{
// To get the alignment requirements, we try laying this out with
// an offset of 1 and then see where it ends up. This will always be
// the minimum alignment requirement.
struct pl_var_layout layout = pl_buf_uniform_layout(1, &(struct pl_var) {
.name = inp->name,
.type = var_type[inp->type],
.dim_v = inp->dim_v,
.dim_m = inp->dim_m,
.dim_a = 1,
});
return (struct ra_layout) {
.align = layout.offset,
.stride = layout.stride,
.size = layout.size,
};
}
static struct ra_layout push_constant_layout_pl(struct ra_renderpass_input *inp)
{
struct pl_var_layout layout = pl_push_constant_layout(1, &(struct pl_var) {
.name = inp->name,
.type = var_type[inp->type],
.dim_v = inp->dim_v,
.dim_m = inp->dim_m,
.dim_a = 1,
});
return (struct ra_layout) {
.align = layout.offset,
.stride = layout.stride,
.size = layout.size,
};
}
static int desc_namespace_pl(struct ra *ra, enum ra_vartype type)
{
return pl_desc_namespace(get_gpu(ra), desc_type[type]);
}
struct pass_priv {
const struct pl_pass *pl_pass;
uint16_t *inp_index; // index translation map
// Space to hold the descriptor bindings and variable updates
struct pl_desc_binding *binds;
struct pl_var_update *varups;
int num_varups;
};
static struct ra_renderpass *renderpass_create_pl(struct ra *ra,
const struct ra_renderpass_params *params)
{
void *tmp = talloc_new(NULL);
const struct pl_gpu *gpu = get_gpu(ra);
struct ra_renderpass *pass = NULL;
static const enum pl_pass_type pass_type[] = {
[RA_RENDERPASS_TYPE_RASTER] = PL_PASS_RASTER,
[RA_RENDERPASS_TYPE_COMPUTE] = PL_PASS_COMPUTE,
};
struct pl_var *vars = NULL;
struct pl_desc *descs = NULL;
int num_vars = 0, num_descs = 0;
struct pass_priv *priv = talloc_ptrtype(tmp, priv);
priv->inp_index = talloc_zero_array(priv, uint16_t, params->num_inputs);
for (int i = 0; i < params->num_inputs; i++) {
const struct ra_renderpass_input *inp = &params->inputs[i];
if (var_type[inp->type]) {
priv->inp_index[i] = num_vars;
MP_TARRAY_APPEND(tmp, vars, num_vars, (struct pl_var) {
.name = inp->name,
.type = var_type[inp->type],
.dim_v = inp->dim_v,
.dim_m = inp->dim_m,
.dim_a = 1,
});
} else if (desc_type[inp->type]) {
priv->inp_index[i] = num_descs;
MP_TARRAY_APPEND(tmp, descs, num_descs, (struct pl_desc) {
.name = inp->name,
.type = desc_type[inp->type],
.binding = inp->binding,
.access = inp->type == RA_VARTYPE_IMG_W ? PL_DESC_ACCESS_WRITEONLY
: inp->type == RA_VARTYPE_BUF_RW ? PL_DESC_ACCESS_READWRITE
: PL_DESC_ACCESS_READONLY,
});
}
}
// Allocate space to store the bindings map persistently
priv->binds = talloc_zero_array(priv, struct pl_desc_binding, num_descs);
struct pl_pass_params pl_params = {
.type = pass_type[params->type],
.variables = vars,
.num_variables = num_vars,
.descriptors = descs,
.num_descriptors = num_descs,
.push_constants_size = params->push_constants_size,
.glsl_shader = params->type == RA_RENDERPASS_TYPE_COMPUTE
? params->compute_shader
: params->frag_shader,
.cached_program = params->cached_program.start,
.cached_program_len = params->cached_program.len,
};
struct pl_blend_params blend_params;
if (params->type == RA_RENDERPASS_TYPE_RASTER) {
pl_params.vertex_shader = params->vertex_shader;
pl_params.vertex_type = PL_PRIM_TRIANGLE_LIST;
pl_params.vertex_stride = params->vertex_stride;
pl_params.target_dummy.params.format = params->target_format->priv;
pl_params.load_target = !params->invalidate_target;
if (params->enable_blend) {
pl_params.blend_params = &blend_params;
blend_params = (struct pl_blend_params) {
// Same enum order as ra_blend
.src_rgb = (enum ra_blend) params->blend_src_rgb,
.dst_rgb = (enum ra_blend) params->blend_dst_rgb,
.src_alpha = (enum ra_blend) params->blend_src_alpha,
.dst_alpha = (enum ra_blend) params->blend_dst_alpha,
};
}
for (int i = 0; i < params->num_vertex_attribs; i++) {
const struct ra_renderpass_input *inp = &params->vertex_attribs[i];
struct pl_vertex_attrib attrib = {
.name = inp->name,
.offset = inp->offset,
.location = i,
.fmt = pl_find_fmt(gpu, fmt_type[inp->type], inp->dim_v, 0,
var_size[inp->type] * 8, PL_FMT_CAP_VERTEX),
};
if (!attrib.fmt) {
MP_ERR(ra, "Failed mapping vertex attrib '%s' to pl_fmt?\n",
inp->name);
goto error;
}
MP_TARRAY_APPEND(tmp, pl_params.vertex_attribs,
pl_params.num_vertex_attribs, attrib);
}
}
priv->pl_pass = pl_pass_create(gpu, &pl_params);
if (!priv->pl_pass)
goto error;
pass = talloc_ptrtype(NULL, pass);
*pass = (struct ra_renderpass) {
.params = *ra_renderpass_params_copy(pass, params),
.priv = talloc_steal(pass, priv),
};
pass->params.cached_program = (struct bstr) {
.start = (void *) priv->pl_pass->params.cached_program,
.len = priv->pl_pass->params.cached_program_len,
};
// fall through
error:
talloc_free(tmp);
return pass;
}
static void renderpass_destroy_pl(struct ra *ra, struct ra_renderpass *pass)
{
if (!pass)
return;
struct pass_priv *priv = pass->priv;
pl_pass_destroy(get_gpu(ra), (const struct pl_pass **) &priv->pl_pass);
talloc_free(pass);
}
static void renderpass_run_pl(struct ra *ra,
const struct ra_renderpass_run_params *params)
{
struct pass_priv *p = params->pass->priv;
p->num_varups = 0;
for (int i = 0; i < params->num_values; i++) {
const struct ra_renderpass_input_val *val = &params->values[i];
const struct ra_renderpass_input *inp = &params->pass->params.inputs[i];
if (var_type[inp->type]) {
MP_TARRAY_APPEND(p, p->varups, p->num_varups, (struct pl_var_update) {
.index = p->inp_index[val->index],
.data = val->data,
});
} else {
struct pl_desc_binding bind;
switch (inp->type) {
case RA_VARTYPE_TEX:
case RA_VARTYPE_IMG_W:
bind.object = (* (struct ra_tex **) val->data)->priv;
break;
case RA_VARTYPE_BUF_RO:
case RA_VARTYPE_BUF_RW:
bind.object = (* (struct ra_buf **) val->data)->priv;
break;
default: abort();
};
p->binds[p->inp_index[val->index]] = bind;
};
}
struct pl_pass_run_params pl_params = {
.pass = p->pl_pass,
.var_updates = p->varups,
.num_var_updates = p->num_varups,
.desc_bindings = p->binds,
.push_constants = params->push_constants,
};
if (p->pl_pass->params.type == PL_PASS_RASTER) {
pl_params.target = params->target->priv;
pl_params.viewport = mp_rect2d_to_pl(params->viewport);
pl_params.scissors = mp_rect2d_to_pl(params->scissors);
pl_params.vertex_data = params->vertex_data;
pl_params.vertex_count = params->vertex_count;
} else {
for (int i = 0; i < MP_ARRAY_SIZE(pl_params.compute_groups); i++)
pl_params.compute_groups[i] = params->compute_groups[i];
}
pl_pass_run(get_gpu(ra), &pl_params);
}
static struct ra_fns ra_fns_pl = {
.destroy = destroy_ra_pl,
.tex_create = tex_create_pl,
.tex_destroy = tex_destroy_pl,
.tex_upload = tex_upload_pl,
.tex_download = tex_download_pl,
.buf_create = buf_create_pl,
.buf_destroy = buf_destroy_pl,
.buf_update = buf_update_pl,
.buf_poll = buf_poll_pl,
.clear = clear_pl,
.blit = blit_pl,
.uniform_layout = uniform_layout_pl,
.push_constant_layout = push_constant_layout_pl,
.desc_namespace = desc_namespace_pl,
.renderpass_create = renderpass_create_pl,
.renderpass_destroy = renderpass_destroy_pl,
.renderpass_run = renderpass_run_pl,
};