/*
vkparse.c
Parser for scripted vulkan structs
Copyright (C) 2020 Bill Currie <bill@taniwha.org>
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:
Free Software Foundation, Inc.
59 Temple Place - Suite 330
Boston, MA 02111-1307, USA
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include <string.h>
#include "QF/cmem.h"
#include "QF/cvar.h"
#include "QF/dstring.h"
#include "QF/hash.h"
#include "QF/mathlib.h"
#include "QF/va.h"
#include "QF/Vulkan/debug.h"
#include "QF/Vulkan/device.h"
#include "QF/Vulkan/instance.h"
#include "QF/Vulkan/image.h"
#include "QF/Vulkan/pipeline.h"
#include "QF/Vulkan/render.h"
#include "QF/Vulkan/shader.h"
#include "vid_vulkan.h"
#include "vkparse.h"
#include "libs/video/renderer/vulkan/vkparse.hinc"
typedef struct parseres_s {
const char *name;
plfield_t *field;
size_t offset;
} parseres_t;
typedef struct parseref_s {
const char *name;
plparser_t parse;
size_t size;
} parserref_t;
typedef struct handleref_s {
char *name;
uint64_t handle;
} handleref_t;
static void flag_or (const exprval_t *val1, const exprval_t *val2,
exprval_t *result, exprctx_t *ctx)
{
*(int *) (result->value) = *(int *) (val1->value) | *(int *) (val2->value);
}
static void flag_and (const exprval_t *val1, const exprval_t *val2,
exprval_t *result, exprctx_t *ctx)
{
*(int *) (result->value) = *(int *) (val1->value) & *(int *) (val2->value);
}
static void flag_cast_int (const exprval_t *val1, const exprval_t *val2,
exprval_t *result, exprctx_t *ctx)
{
// FIXME should check value is valid
*(int *) (result->value) = *(int *) (val2->value);
}
static void flag_not (const exprval_t *val, exprval_t *result, exprctx_t *ctx)
{
*(int *) (result->value) = ~(*(int *) (val->value));
}
binop_t flag_binops[] = {
{ '|', 0, 0, flag_or },
{ '&', 0, 0, flag_and },
{ '=', &cexpr_int, 0, flag_cast_int },
{ '=', &cexpr_plitem, 0, cexpr_cast_plitem },
{}
};
binop_t enum_binops[] = {
{ '=', &cexpr_plitem, 0, cexpr_cast_plitem },
{}
};
unop_t flag_unops[] = {
{ '~', 0, flag_not },
{}
};
typedef struct parse_single_s {
pltype_t type;
size_t stride;
plparser_t parser;
void *data;
size_t value_offset;
} parse_single_t;
typedef struct parse_array_s {
pltype_t type;
size_t stride;
plparser_t parser;
void *data;
size_t value_offset;
size_t size_offset;
} parse_array_t;
typedef struct parse_fixed_array_s {
pltype_t type;
size_t stride;
plparser_t parser;
void *data;
size_t size;
} parse_fixed_array_t;
typedef struct parse_data_s {
size_t value_offset;
size_t size_offset;
} parse_data_t;
typedef struct parse_string_s {
size_t value_offset;
} parse_string_t;
typedef struct parse_custom_s {
int (*parse) (const plitem_t *item, void **data,
plitem_t *messages, parsectx_t *context);
size_t *offsets;
size_t num_offsets;
} parse_custom_t;
static plfield_t *__attribute__((used))
find_field (plfield_t *fields, const char *field_name,
const plitem_t *item, plitem_t *messages)
{
for (plfield_t *f = fields; f->name; f++) {
if (strcmp (f->name, field_name) == 0) {
return f;
}
}
PL_Message (messages, item, "error: unknown field '%s'", field_name);
return 0;
}
static int
parse_basic (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
int ret = 1;
parsectx_t *pctx = context;
__auto_type etype = (exprtype_t *) field->data;
exprctx_t ectx = *pctx->ectx;
exprval_t result = { etype, data };
ectx.result = &result;
ectx.item = item;
const char *valstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_basic: %s %zd %d %p %p: %s\n",
// field->name, field->offset, field->type, field->parser,
// field->data, valstr);
if (strcmp (valstr, "VK_SUBPASS_EXTERNAL") == 0) {
//FIXME handle subpass in a separate parser?
*(uint32_t *) data = VK_SUBPASS_EXTERNAL;
} else {
ret = !cexpr_eval_string (valstr, &ectx);
if (!ret) {
PL_Message (messages, item, "error parsing %s: %s",
field->name, valstr);
}
}
//Sys_MaskPrintf (SYS_vulkan_parse, " %x\n", *(uint32_t *)data);
return ret;
}
static int
parse_int32_t (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
int ret = 1;
int val = 0;
parsectx_t *pctx = context;
exprval_t result = { &cexpr_int, &val };
exprctx_t ectx = *pctx->ectx;
ectx.result = &result;
ectx.item = item;
const char *valstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse,
// "parse_int32_t: %s %zd %d %p %p %s\n",
// field->name, field->offset, field->type, field->parser,
// field->data, valstr);
ret = !cexpr_eval_string (valstr, &ectx);
if (!ret) {
PL_Message (messages, item, "error parsing %s: %s",
field->name, valstr);
}
*(int32_t *) data = val;
//Sys_MaskPrintf (SYS_vulkan_parse, " %d\n", *(int32_t *)data);
return ret;
}
static int
parse_uint32_t (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
int ret = 1;
// use size_t (and cexpr_size_t) for val so references to array sizes
// can be used
size_t val = 0;
parsectx_t *pctx = context;
exprval_t result = { &cexpr_size_t, &val };
exprctx_t ectx = *pctx->ectx;
ectx.result = &result;
ectx.item = item;
const char *valstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_uint32_t: %s %zd %d %p %p: %s\n",
// field->name, field->offset, field->type, field->parser,
// field->data, valstr);
if (strcmp (valstr, "VK_SUBPASS_EXTERNAL") == 0) {
//FIXME handle subpass in a separate parser?
*(uint32_t *) data = VK_SUBPASS_EXTERNAL;
} else {
//Sys_MaskPrintf (SYS_vulkan_parse,
// "parse_uint32_t: %s %zd %d %p %p %s\n",
// field->name, field->offset, field->type, field->parser,
// field->data, valstr);
ret = !cexpr_eval_string (valstr, &ectx);
if (!ret) {
PL_Message (messages, item, "error parsing %s: %s",
field->name, valstr);
}
*(uint32_t *) data = val;
//Sys_MaskPrintf (SYS_vulkan_parse, " %d\n", *(uint32_t *)data);
}
return ret;
}
static int
parse_enum (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
int ret = 1;
__auto_type enm = (exprenum_t *) field->data;
parsectx_t *pctx = context;
exprctx_t ectx = *pctx->ectx;
exprval_t result = { enm->type, data };
ectx.parent = pctx->ectx;
ectx.symtab = enm->symtab;
ectx.result = &result;
const char *valstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_enum: %s %zd %d %p %p %s\n",
// field->name, field->offset, field->type, field->parser,
// field->data, valstr);
ret = !cexpr_parse_enum (enm, valstr, &ectx, data);
if (!ret) {
PL_Message (messages, item, "error parsing enum: %s", valstr);
}
//Sys_MaskPrintf (SYS_vulkan_parse, " %d\n", *(int *)data);
return ret;
}
static const plitem_t *
parse_reference (const plitem_t *item, const char *type, plitem_t *messages,
parsectx_t *pctx)
{
exprctx_t ectx = *pctx->ectx;
plitem_t *refItem = 0;
exprval_t result = { &cexpr_plitem, &refItem };
ectx.result = &result;
ectx.item = item;
const char *name = PL_String (item);
if (cexpr_eval_string (name, &ectx)) {
PL_Message (messages, item, "not a %s reference", type);
return 0;
}
return refItem;
}
static void *
vkparse_alloc (void *context, size_t size)
{
parsectx_t *pctx = context;
return cmemalloc (pctx->ectx->memsuper, size);
}
static int
parse_ignore (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
return 1;
}
static int __attribute__((used))
parse_labeledsingle (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type single = (parse_single_t *) field->data;
void *flddata = (byte *)data + single->value_offset;
//Sys_MaskPrintf (SYS_vulkan_parse,"parse_labeledsingle: %s %zd %d %p %p\n",
// field->name, field->offset,
// field->type, field->parser, field->data);
const char *key = PL_KeyAtIndex (item, 0);
if (!key) {
PL_Message (messages, item, "missing item");
return 0;
}
item = PL_ObjectForKey (item, key);
if (!PL_CheckType (single->type, PL_Type (item))) {
PL_TypeMismatch (messages, item, field->name, single->type,
PL_Type (item));
return 0;
}
plfield_t f = { key, 0, single->type, single->parser, 0 };
void *value = vkparse_alloc (context, single->stride);
memset (value, 0, single->stride);
if (!single->parser (&f, item, value, messages, context)) {
return 0;
}
*(void **) flddata = value;
return 1;
}
static int
parse_single (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type single = (parse_single_t *) field->data;
void *flddata = (byte *)data + single->value_offset;
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_single: %s %zd %d %p %p\n",
// field->name, field->offset,
// field->type, field->parser, field->data);
if (!PL_CheckType (single->type, PL_Type (item))) {
PL_TypeMismatch (messages, item, field->name, single->type,
PL_Type (item));
return 0;
}
plfield_t f = { field->name, 0, single->type, single->parser, 0 };
void *value = vkparse_alloc (context, single->stride);
memset (value, 0, single->stride);
if (!single->parser (&f, item, value, messages, context)) {
return 0;
}
*(void **) flddata = value;
return 1;
}
static int __attribute__((used))
parse_labeledarray (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type array = (parse_array_t *) field->data;
__auto_type value = (void **) ((byte *)data + array->value_offset);
__auto_type size = (uint32_t *) ((byte *)data + array->size_offset);
plelement_t element = {
array->type,
array->stride,
vkparse_alloc,
array->parser,
array->data,
};
plfield_t f = { 0, 0, 0, 0, &element };
typedef struct arr_s DARRAY_TYPE(byte) arr_t;
arr_t *arr;
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_array: %s %zd %d %p %p %p\n",
// field->name, field->offset, field->type, field->parser,
// field->data, data);
//Sys_MaskPrintf (SYS_vulkan_parse, " %d %zd %p %zd %zd\n", array->type,
// array->stride, array->parser, array->value_offset,
// array->size_offset);
if (!PL_ParseLabeledArray (&f, item, &arr, messages, context)) {
return 0;
}
*value = vkparse_alloc (context, array->stride * arr->size);
memcpy (*value, arr->a, array->stride * arr->size);
if ((void *) size >= data) {
*size = arr->size;
}
return 1;
}
static int
parse_array (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type array = (parse_array_t *) field->data;
__auto_type value = (void **) ((byte *)data + array->value_offset);
__auto_type size = (uint32_t *) ((byte *)data + array->size_offset);
plelement_t element = {
array->type,
array->stride,
vkparse_alloc,
array->parser,
array->data,
};
plfield_t f = { 0, 0, 0, 0, &element };
typedef struct arr_s DARRAY_TYPE(byte) arr_t;
arr_t *arr;
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_array: %s %zd %d %p %p %p\n",
// field->name, field->offset, field->type, field->parser,
// field->data, data);
//Sys_MaskPrintf (SYS_vulkan_parse, " %d %zd %p %zd %zd\n", array->type,
// array->stride, array->parser, array->value_offset,
// array->size_offset);
if (!PL_ParseArray (&f, item, &arr, messages, context)) {
return 0;
}
*value = vkparse_alloc (context, array->stride * arr->size);
memcpy (*value, arr->a, array->stride * arr->size);
if ((void *) size >= data) {
*size = arr->size;
}
return 1;
}
static int __attribute__((used))
parse_fixed_array (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type array = (parse_fixed_array_t *) field->data;
plelement_t element = {
array->type,
array->stride,
vkparse_alloc,
array->parser,
array->data,
};
plfield_t f = { 0, 0, 0, 0, &element };
typedef struct arr_s DARRAY_TYPE(byte) arr_t;
arr_t *arr;
if (!PL_ParseArray (&f, item, &arr, messages, context)) {
return 0;
}
memset (data, 0, array->stride * array->size);
size_t size = min (array->size, arr->size);
memcpy (data, arr->a, array->stride * size);
return 1;
}
static char *
vkstrdup (parsectx_t *context, const char *str)
{
size_t len = strlen (str) + 1;
char *dup = vkparse_alloc (context, len);
memcpy (dup, str, len);
return dup;
}
static __attribute__((used)) parse_string_t parse_string_array = { 0 };
static int
parse_string (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type string = (parse_string_t *) field->data;
__auto_type value = (char **) ((byte *)data + string->value_offset);
const char *str = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_string: %s %zd %d %p %p %p\n",
// field->name, field->offset, field->type, field->parser,
// field->data, data);
//Sys_MaskPrintf (SYS_vulkan_parse, " %zd\n", string->value_offset);
//Sys_MaskPrintf (SYS_vulkan_parse, " %s\n", str);
*value = vkstrdup (context, str);
return 1;
}
static int
parse_custom (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
__auto_type custom = (parse_custom_t *) field->data;
void **offsets = alloca (custom->num_offsets * sizeof (void *));
for (size_t i = 0; i < custom->num_offsets; i++) {
offsets[i] = data + custom->offsets[i];
}
return custom->parse (item, offsets, messages, context);
}
static int
parse_inherit (const plfield_t *field, const plitem_t *item,
void *data, plitem_t *messages, void *context)
{
parsectx_t *pctx = context;
exprctx_t ectx = *pctx->ectx;
plitem_t *inheritItem = 0;
exprval_t result = { &cexpr_plitem, &inheritItem };
ectx.result = &result;
ectx.item = item;
const char *inheritstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_inherit: %s\n", inheritstr);
int ret = !cexpr_eval_string (inheritstr, &ectx);
if (ret) {
ret = PL_ParseStruct (field->data, inheritItem, data, messages,
context);
}
return ret;
}
static hashtab_t *parser_table;
static int
parse_next (const plfield_t *field, const plitem_t *item, void *data,
plitem_t *messages, void *context)
{
const char *type_name = PL_String (PL_ObjectAtIndex (item, 0));
plitem_t *next_def = PL_ObjectAtIndex (item, 1);
if (!type_name || PL_Type (next_def) != QFDictionary) {
PL_Message (messages, item, "invalid @next");
return 0;
}
parserref_t *parser = Hash_Find (parser_table, type_name);
if (!parser) {
PL_Message (messages, item, "Invalid type for @next: %s", type_name);
return 0;
}
void *data_ptr = vkparse_alloc (context, parser->size);
memset (data_ptr, 0, parser->size);
if (!parser->parse (field, next_def, data_ptr, messages, context)) {
return 0;
}
*(void **) data = data_ptr;
return 1;
}
static int
parse_RGBA (const plitem_t *item, void **data,
plitem_t *messages, parsectx_t *context)
{
int ret = 1;
exprctx_t ectx = *context->ectx;
exprval_t result = { &cexpr_vector, data[0] };
ectx.result = &result;
ectx.item = item;
const char *valstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse, "parse_RGBA: %s\n", valstr);
ret = !cexpr_eval_string (valstr, &ectx);
//Sys_MaskPrintf (SYS_vulkan_parse, " "VEC4F_FMT"\n",
// VEC4_EXP (*(vec4f_t *)data[0]));
return ret;
}
uint64_t
QFV_GetHandle (hashtab_t *tab, const char *name)
{
handleref_t *hr = Hash_Find (tab, name);
if (hr) {
return hr->handle;
}
return 0;
}
void
QFV_AddHandle (hashtab_t *tab, const char *name, uint64_t handle)
{
handleref_t *hr = malloc (sizeof (handleref_t));
hr->name = strdup (name);
hr->handle = handle;
Hash_Add (tab, hr);
}
static int
parse_VkShaderModule (const plitem_t *item, void **data,
plitem_t *messages, parsectx_t *pctx)
{
__auto_type handle = (VkShaderModule *) data[0];
vulkan_ctx_t *ctx = pctx->vctx;
qfv_device_t *device = ctx->device;
scriptctx_t *sctx = ctx->script_context;
const char *name = PL_String (item);
*handle = (VkShaderModule) QFV_GetHandle (sctx->shaderModules, name);
if (*handle) {
return 1;
}
qfvPushDebug (ctx, va (ctx->va_ctx, "parse_VkShaderModule: %d", PL_Line (item)));
*handle = QFV_CreateShaderModule (device, name);
qfvPopDebug (ctx);
if (!*handle) {
PL_Message (messages, item, "could not find shader %s", name);
return 0;
}
QFV_AddHandle (sctx->shaderModules, name, (uint64_t) *handle);
return 1;
}
exprtype_t VkImage_type = {
.name = "VkImage",
.size = sizeof (VkImage),
.binops = 0,
.unops = 0,
.data = 0
};
exprtype_t VkImageView_type = {
.name = "VkImageView",
.size = sizeof (VkImageView),
.binops = 0,
.unops = 0,
.data = 0
};
static const char *
handleref_getkey (const void *hr, void *unused)
{
return ((handleref_t *)hr)->name;
}
static void
handleref_free (void *hr, void *_ctx)
{
__auto_type handleref = (handleref_t *) hr;
free (handleref->name);
free (handleref);
}
static void
setLayout_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type layout = (VkDescriptorSetLayout) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (layout) {
dfunc->vkDestroyDescriptorSetLayout (device->dev, layout, 0);
}
handleref_free (handleref, ctx);
}
static void
shaderModule_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type module = (VkShaderModule) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (module) {
dfunc->vkDestroyShaderModule (device->dev, module, 0);
}
handleref_free (handleref, ctx);
}
static void
pipelineLayout_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type layout = (VkPipelineLayout) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (layout) {
dfunc->vkDestroyPipelineLayout (device->dev, layout, 0);
};
handleref_free (handleref, ctx);
}
static void
descriptorPool_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type pool = (VkDescriptorPool) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (pool) {
dfunc->vkDestroyDescriptorPool (device->dev, pool, 0);
};
handleref_free (handleref, ctx);
}
static void
sampler_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type sampler = (VkSampler) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (sampler) {
dfunc->vkDestroySampler (device->dev, sampler, 0);
};
handleref_free (handleref, ctx);
}
static void
image_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type image = (VkImage) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (image) {
dfunc->vkDestroyImage (device->dev, image, 0);
};
handleref_free (handleref, ctx);
}
static void
imageView_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type imageView = (VkImageView) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (imageView) {
dfunc->vkDestroyImageView (device->dev, imageView, 0);
};
handleref_free (handleref, ctx);
}
static void
renderpass_free (void *hr, void *_ctx)
{
scriptctx_t *sctx = _ctx;
__auto_type handleref = (handleref_t *) hr;
__auto_type renderpass = (VkRenderPass) handleref->handle;
__auto_type ctx = sctx->vctx;
qfv_device_t *device = ctx->device;
qfv_devfuncs_t *dfunc = device->funcs;
if (renderpass) {
dfunc->vkDestroyRenderPass (device->dev, renderpass, 0);
};
handleref_free (handleref, ctx);
}
static hashtab_t *enum_symtab;
typedef struct data_array_s DARRAY_TYPE(byte) data_array_t;
static void
data_array (const exprval_t **params, exprval_t *result, exprctx_t *context)
{
size_t offset = 0;
// params are in reverse order, but this works for calculating the size
// of the buffer
for (const exprval_t **param = params; *param; param++) {
offset += (*param)->type->size;
}
__auto_type data = DARRAY_ALLOCFIXED_OBJ (data_array_t, offset,
cmemalloc, context->memsuper);
for (const exprval_t **param = params; *param; param++) {
size_t size = (*param)->type->size;
// pre-decrement offset because params are in reverse order
offset -= size;
memcpy (data->a + offset, (*param)->value, size);
}
*(data_array_t **) result->value = data;
}
static exprtype_t data_array_type = {
.name = "array",
.size = sizeof (data_array_t *),
.binops = 0,
.unops = 0,
};
static exprfunc_t data_array_func[] = {
{ &data_array_type, -1, 0, data_array },
{}
};
static exprsym_t data_array_symbols[] = {
{ "array", &cexpr_function, data_array_func },
{}
};
static exprtab_t data_array_symtab = {
data_array_symbols,
};
static int
parse_specialization_data (const plitem_t *item, void **data,
plitem_t *messages, parsectx_t *pctx)
{
size_t *size_ptr = (size_t *) data[0];
void **data_ptr = (void **) data[1];
if (PL_Type (item) == QFBinary) {
const void *bindata = PL_BinaryData (item);
size_t binsize = PL_BinarySize (item);
*data_ptr = vkparse_alloc (pctx, binsize);
memcpy (*data_ptr, bindata, binsize);
*size_ptr = binsize;
return 1;
}
data_array_t *da= 0;
exprctx_t ectx = *pctx->ectx;
exprval_t result = { &data_array_type, &da };
ectx.parent = pctx->ectx;
ectx.symtab = &data_array_symtab;
ectx.result = &result;
ectx.item = item;
const char *valstr = PL_String (item);
//Sys_MaskPrintf (SYS_vulkan_parse,
// "parse_specialization_data: %s %zd %d %p %p %s\n",
// field->name, field->offset, field->type, field->parser,
// field->data, valstr);
int ret = !cexpr_eval_string (valstr, &ectx);
if (!ret) {
PL_Message (messages, item, "error parsing specialization data: %s",
valstr);
} else {
*size_ptr = da->size;
*data_ptr = da->a;
//for (size_t i = 0; i < da->size; i++) {
// Sys_Printf (" %02x", da->a[i]);
//}
//Sys_Printf ("\n");
}
return ret;
}
static int
parse_task_function (const plitem_t *item, void **data,
plitem_t *messages, parsectx_t *pctx)
{
qfv_renderctx_t *rctx = pctx->data;
const char *fname = PL_String (item);
exprsym_t *fsym = Hash_Find (rctx->task_functions.tab, fname);
if (!fsym) {
PL_Message (messages, item, "undefined task function %s", fname);
return 0;
}
if (fsym->type != &cexpr_function) {
PL_Message (messages, item, "not a function type %s", fname);
return 0;
}
exprfunc_t *func;
for (func = fsym->value; func->func; func++) {
if (!func->result) {
break;
}
}
if (!func->func) {
PL_Message (messages, item, "%s does not have a void implementation",
fname);
return 0;
}
size_t size = func->num_params * sizeof (exprval_t);
size += func->num_params * sizeof (exprval_t *);
size_t base = size;
for (int i = 0; i < func->num_params; i++) {
exprtype_t *type = func->param_types[i];
size = ((size + type->size - 1) & ~(type->size - 1));
if (i == 0) {
base = size;
}
}
exprval_t **param_ptrs = vkparse_alloc (pctx, size);
exprval_t *params = (exprval_t *) ¶m_ptrs[func->num_params];
byte *param_data = (byte *) param_ptrs + base;
memset (params, 0, size);
size_t offs = 0;
for (int i = 0; i < func->num_params; i++) {
exprtype_t *type = func->param_types[i];
param_ptrs[i] = ¶ms[i];
params[i] = (exprval_t) {
.type = type,
.value = param_data + offs,
};
offs = ((offs + type->size - 1) & ~(type->size - 1));
offs += type->size;
}
*(exprfunc_t **) data[0] = func;
*(exprval_t ***) data[1] = param_ptrs;
*(void **) data[2] = param_data;
return 1;
}
static int
parse_task_params (const plitem_t *item, void **data,
plitem_t *messages, parsectx_t *pctx)
{
exprfunc_t *func = *(exprfunc_t **) data[0];
exprval_t **params = *(exprval_t ***) data[1];
if (!func) {
PL_Message (messages, item, "task function not set");
return 0;
}
if (PL_A_NumObjects (item) != func->num_params) {
PL_Message (messages, item, "incorrect number of parameters");
return 0;
}
for (int i = 0; i < func->num_params; i++) {
const char *paramstr = PL_String (PL_ObjectAtIndex (item, i));
exprval_t *param = params[func->num_params - i - 1];
exprctx_t ectx = *pctx->ectx;
if (param->type->data) {
ectx.parent = pctx->ectx;
ectx.symtab = ((exprenum_t *) param->type->data)->symtab;
}
// cexpr params are in reverse order
ectx.result = param;
if (cexpr_eval_string (paramstr, &ectx)) {
PL_Message (messages, item, "error parsing param %d", i);
return 0;
}
}
return 1;
}
#include "libs/video/renderer/vulkan/vkparse.cinc"
static exprsym_t qfv_renderframeset_t_symbols[] = {
{"size", &cexpr_size_t, (void *)field_offset (qfv_renderframeset_t, size)},
{ }
};
static exprtab_t qfv_renderframeset_t_symtab = {
qfv_renderframeset_t_symbols,
};
exprtype_t qfv_renderframeset_t_type = {
.name = "frameset",
.size = sizeof (qfv_renderframeset_t *),
.binops = cexpr_struct_binops,
.unops = 0,
.data = &qfv_renderframeset_t_symtab,
};
static hashtab_t *
handlref_symtab (void (*free_func)(void*,void*), scriptctx_t *sctx)
{
return Hash_NewTable (23, handleref_getkey, free_func, sctx,
&sctx->hashctx);
}
static const char *
enum_symtab_getkey (const void *e, void *unused)
{
__auto_type enm = (const exprenum_t *) e;
return enm->type->name;
}
static const char *
parser_getkey (const void *e, void *unused)
{
__auto_type parser = (const parserref_t *) e;
return parser->name;
}
static exprtab_t root_symtab = {
.symbols = cexpr_lib_symbols,
};
static void
root_symtab_shutdown (void *data)
{
Hash_DelTable (root_symtab.tab);
}
static void __attribute__((constructor))
root_symtab_init (void)
{
// using a null hashctx here is safe because this function is run before
// main and thus before any possibility of threading.
exprctx_t root_context = { .symtab = &root_symtab };
cexpr_init_symtab (&root_symtab, &root_context);
Sys_RegisterShutdown (root_symtab_shutdown, 0);
}
exprenum_t *
QFV_GetEnum (const char *name)
{
return Hash_Find (enum_symtab, name);
}
static int
parse_object (vulkan_ctx_t *ctx, memsuper_t *memsuper, plitem_t *plist,
plparser_t parser, void *object, plitem_t *properties)
{
scriptctx_t *sctx = ctx->script_context;
plitem_t *messages = PL_NewArray ();
exprctx_t exprctx = { .symtab = &root_symtab };
parsectx_t parsectx = { &exprctx, ctx, properties };
auto rctx = ctx->render_context;
exprsym_t var_syms[] = {
{"output", &qfv_output_t_type, &sctx->output},
{"frames", &qfv_renderframeset_t_type, &rctx->frames},
{"msaaSamples", &VkSampleCountFlagBits_type, &ctx->msaaSamples},
{"physDevLimits", &VkPhysicalDeviceLimits_type,
&ctx->device->physDev->properties->limits },
{QFV_PROPERTIES, &cexpr_plitem, &parsectx.properties},
{}
};
exprtab_t vars_tab = { var_syms, 0 };
exprctx.external_variables = &vars_tab;
exprctx.messages = messages;
exprctx.hashctx = &sctx->hashctx;
exprctx.memsuper = memsuper;
cexpr_init_symtab (&vars_tab, &exprctx);
if (!parser (0, plist, object, messages, &parsectx)) {
for (int i = 0; i < PL_A_NumObjects (messages); i++) {
Sys_Printf ("%s\n", PL_String (PL_ObjectAtIndex (messages, i)));
}
return 0;
}
Hash_DelTable (vars_tab.tab);
PL_Release (messages);
return 1;
}
typedef struct {
uint32_t count;
VkImageCreateInfo *info;
} imagecreate_t;
typedef struct {
uint32_t count;
VkImageViewCreateInfo *info;
} imageviewcreate_t;
int
QFV_ParseOutput (vulkan_ctx_t *ctx, qfv_output_t *output, plitem_t *plist,
plitem_t *properties)
{
memsuper_t *memsuper = new_memsuper ();
int ret = 0;
qfv_output_t op = {};
if (parse_object (ctx, memsuper, plist, parse_qfv_output_t, &op,
properties)) {
memcpy (output, &op, sizeof (*output));
ret = 1;
}
delete_memsuper (memsuper);
return ret;
}
int vulkan_frame_count;
static cvar_t vulkan_frame_count_cvar = {
.name = "vulkan_frame_count",
.description =
"Number of frames to render in the background. More frames can "
"increase performance, but at the cost of latency. The default of 2 is"
" recommended.",
.default_value = "2",
.flags = CVAR_NONE,
.value = { .type = &cexpr_int, .value = &vulkan_frame_count },
};
int vulkan_presentation_mode;
static cvar_t vulkan_presentation_mode_cvar = {
.name = "vulkan_presentation_mode",
.description =
"desired presentation mode (may fall back to fifo).",
.default_value = "mailbox",
.flags = CVAR_NONE,
.value = {
.type = &VkPresentModeKHR_type,
.value = &vulkan_presentation_mode,
},
};
int msaaSamples;
static cvar_t msaaSamples_cvar = {
.name = "msaaSamples",
.description =
"desired MSAA sample size.",
.default_value = "VK_SAMPLE_COUNT_1_BIT",
.flags = CVAR_NONE,
.value = { .type = &VkSampleCountFlagBits_type, .value = &msaaSamples },
};
static exprenum_t validation_enum;
static exprtype_t validation_type = {
.name = "vulkan_use_validation",
.size = sizeof (int),
.binops = cexpr_flag_binops,
.unops = cexpr_flag_unops,
.data = &validation_enum,
.get_string = cexpr_flags_get_string,
};
static int validation_values[] = {
0,
VK_DEBUG_UTILS_MESSAGE_SEVERITY_FLAG_BITS_MAX_ENUM_EXT,
};
static exprsym_t validation_symbols[] = {
{"none", &validation_type, validation_values + 0},
{"all", &validation_type, validation_values + 1},
{}
};
static exprtab_t validation_symtab = {
validation_symbols,
};
static exprenum_t validation_enum = {
&validation_type,
&validation_symtab,
};
static cvar_t vulkan_use_validation_cvar = {
.name = "vulkan_use_validation",
.description =
"enable KRONOS Validation Layer if available (requires instance "
"restart).",
.default_value = "error|warning",
.flags = CVAR_NONE,
.value = { .type = &validation_type, .value = &vulkan_use_validation },
};
static void
vulkan_frame_count_f (void *data, const cvar_t *cvar)
{
if (vulkan_frame_count < 1) {
Sys_Printf ("Invalid frame count: %d. Setting to 1\n",
vulkan_frame_count);
vulkan_frame_count = 1;
}
}
void
Vulkan_Init_Cvars (void)
{
int num_syms = 0;
for (exprsym_t *sym = VkDebugUtilsMessageSeverityFlagBitsEXT_symbols;
sym->name; sym++, num_syms++) {
}
for (exprsym_t *sym = validation_symbols; sym->name; sym++, num_syms++) {
}
validation_symtab.symbols = calloc (num_syms + 1, sizeof (exprsym_t));
num_syms = 0;
for (exprsym_t *sym = VkDebugUtilsMessageSeverityFlagBitsEXT_symbols;
sym->name; sym++, num_syms++) {
validation_symtab.symbols[num_syms] = *sym;
validation_symtab.symbols[num_syms].type = &validation_type;
}
for (exprsym_t *sym = validation_symbols; sym->name; sym++, num_syms++) {
validation_symtab.symbols[num_syms] = *sym;
}
Cvar_Register (&vulkan_use_validation_cvar, 0, 0);
// FIXME implement fallback choices (instead of just fifo)
Cvar_Register (&vulkan_presentation_mode_cvar, 0, 0);
Cvar_Register (&vulkan_frame_count_cvar, vulkan_frame_count_f, 0);
Cvar_Register (&msaaSamples_cvar, 0, 0);
}
static exprsym_t builtin_plist_syms[] = {
{ .name = "main_def",
.value = (void *)
#include "libs/video/renderer/vulkan/rp_main_def.plc"
},
{ .name = "main_fwd",
.value = (void *)
#include "libs/video/renderer/vulkan/rp_main_fwd.plc"
},
{ .name = "smp_quake",
.value = (void *)
#include "libs/video/renderer/vulkan/smp_quake.plc"
},
{}
};
static plitem_t **builtin_plists;
static exprtab_t builtin_configs = { .symbols = builtin_plist_syms };
static void
build_configs (scriptctx_t *sctx)
{
int num_plists = 0;
for (exprsym_t *sym = builtin_plist_syms; sym->name; sym++) {
num_plists++;
}
builtin_plists = malloc (num_plists * sizeof (plitem_t *));
num_plists = 0;
for (exprsym_t *sym = builtin_plist_syms; sym->name; sym++) {
plitem_t *item = PL_GetDictionary (sym->value, &sctx->hashctx);
if (!item) {
// Syntax errors in the compiled-in plists are unrecoverable
Sys_Error ("Error parsing plist for %s", sym->name);
}
builtin_plists[num_plists] = item;
sym->value = &builtin_plists[num_plists];
sym->type = &cexpr_plitem;
num_plists++;
}
exprctx_t ectx = { .hashctx = &sctx->hashctx };
cexpr_init_symtab (&builtin_configs, &ectx);
}
static void
delete_configs (void)
{
int num_plists = 0;
for (exprsym_t *sym = builtin_plist_syms; sym->name; sym++) {
PL_Release (builtin_plists[num_plists]);
num_plists++;
}
free (builtin_plists);
}
plitem_t *
Vulkan_GetConfig (vulkan_ctx_t *ctx, const char *name)
{
scriptctx_t *sctx = ctx->script_context;
if (!builtin_configs.tab) {
build_configs (sctx);
}
plitem_t *config = 0;
exprval_t result = { .type = &cexpr_plitem, .value = &config };
exprctx_t ectx = {
.result = &result,
.symtab = &builtin_configs,
.memsuper = new_memsuper (),
.hashctx = &sctx->hashctx,
.messages = PL_NewArray (),
};
if (cexpr_eval_string (name, &ectx)) {
dstring_t *msg = dstring_newstr ();
for (int i = 0; i < PL_A_NumObjects (ectx.messages); i++) {
dasprintf (msg, "%s\n",
PL_String (PL_ObjectAtIndex (ectx.messages, i)));
}
Sys_Printf ("%s", msg->str);
dstring_delete (msg);
config = 0;
}
PL_Release (ectx.messages);
delete_memsuper (ectx.memsuper);
return config;
}
void Vulkan_Script_Init (vulkan_ctx_t *ctx)
{
scriptctx_t *sctx = calloc (1, sizeof (scriptctx_t));
sctx->vctx = ctx;
ctx->script_context = sctx;
exprctx_t ectx = {};
enum_symtab = Hash_NewTable (61, enum_symtab_getkey, 0, 0, &sctx->hashctx);
parser_table = Hash_NewTable (61, parser_getkey, 0, 0, &sctx->hashctx);
//FIXME using the script context's hashctx causes the cvar system to access
//freed hash links due to shutdown order issues. The proper fix would be to
//create a symtabs shutdown (for thread safety), but this works for now.
ectx.hashctx = 0;//&sctx->hashctx;
vkgen_init_symtabs (&ectx);
cexpr_init_symtab (&qfv_output_t_symtab, &ectx);
cexpr_init_symtab (&qfv_renderframeset_t_symtab, &ectx);
cexpr_init_symtab (&data_array_symtab, &ectx);
sctx->shaderModules = handlref_symtab (shaderModule_free, sctx);
sctx->setLayouts = handlref_symtab (setLayout_free, sctx);
sctx->pipelineLayouts = handlref_symtab (pipelineLayout_free, sctx);
sctx->descriptorPools = handlref_symtab (descriptorPool_free, sctx);
sctx->samplers = handlref_symtab (sampler_free, sctx);
sctx->images = handlref_symtab (image_free, sctx);
sctx->imageViews = handlref_symtab (imageView_free, sctx);
sctx->renderpasses = handlref_symtab (renderpass_free, sctx);
}
static void
clear_table (hashtab_t **table)
{
if (*table) {
hashtab_t *tab = *table;
*table = 0;
Hash_DelTable (tab);
}
}
void Vulkan_Script_Shutdown (vulkan_ctx_t *ctx)
{
scriptctx_t *sctx = ctx->script_context;
clear_table (&sctx->pipelineLayouts);
clear_table (&sctx->setLayouts);
clear_table (&sctx->shaderModules);
clear_table (&sctx->descriptorPools);
clear_table (&sctx->samplers);
delete_configs ();
Hash_DelContext (sctx->hashctx);
free (sctx);
}
void Vulkan_Script_SetOutput (vulkan_ctx_t *ctx, qfv_output_t *output)
{
scriptctx_t *sctx = ctx->script_context;
sctx->output = *output;
}
exprtab_t *
QFV_CreateSymtab (plitem_t *dict, const char *properties,
const char **extra_items, exprsym_t *extra_syms,
exprctx_t *ectx)
{
plitem_t *props = PL_ObjectForKey (dict, properties);
int num_keys = PL_D_NumKeys (props);
int num_extra = 0;
int num_syms = 0;
if (extra_items) {
for (const char **e = extra_items; *e; e++) {
if (PL_ObjectForKey (dict, *e)) {
num_extra++;
}
}
}
if (extra_syms) {
for (exprsym_t *sym = extra_syms; sym->name; sym++, num_syms++) { }
}
int total_items = num_keys + num_extra;
int total_syms = total_items + num_syms;
size_t size = (sizeof (exprtab_t)
+ (total_syms + 1) * sizeof (exprsym_t)
+ total_items * sizeof (plitem_t *));
exprtab_t *symtab = malloc (size);
*symtab = (exprtab_t) {
.symbols = (exprsym_t *) &symtab[1],
};
plitem_t **items = (plitem_t **) &symtab->symbols[total_syms + 1];
for (int i = 0; i < num_keys; i++) {
symtab->symbols[i] = (exprsym_t) {
.name = PL_KeyAtIndex (props, i),
.type = &cexpr_plitem,
.value = items + i,
};
items[i] = PL_ObjectForKey (props, symtab->symbols[i].name);
}
for (int i = 0, j = 0; num_extra && extra_items[i]; i++) {
plitem_t *val = PL_ObjectForKey (dict, extra_items[i]);
if (val) {
symtab->symbols[num_keys + j] = (exprsym_t) {
.name = extra_items[i],
.type = &cexpr_plitem,
.value = items + num_keys + j,
};
items[num_keys + j] = val;
j++;
}
}
for (int i = 0; i < num_syms; i++) {
symtab->symbols[total_items + i] = extra_syms[i];
}
symtab->symbols[total_syms] = (exprsym_t) { };
cexpr_init_symtab (symtab, ectx);
return symtab;
}
void
QFV_DestroySymtab (exprtab_t *tab)
{
Hash_DelTable (tab->tab);
free (tab);
}
struct qfv_jobinfo_s *
QFV_ParseJobInfo (vulkan_ctx_t *ctx, plitem_t *item, qfv_renderctx_t *rctx)
{
memsuper_t *memsuper = new_memsuper ();
qfv_jobinfo_t *ji = cmemalloc (memsuper, sizeof (qfv_jobinfo_t));
*ji = (qfv_jobinfo_t) { .memsuper = memsuper };
scriptctx_t *sctx = ctx->script_context;
plitem_t *messages = PL_NewArray ();
exprctx_t exprctx = {
.symtab = &root_symtab,
.messages = messages,
.hashctx = &sctx->hashctx,
.memsuper = memsuper,
};
parsectx_t parsectx = {
.ectx = &exprctx,
.vctx = ctx,
.data = rctx,
};
static const char *extra_items[] = {
"images",
"imageviews",
"renderpasses",
0
};
exprsym_t var_syms[] = {
{"render_output", &qfv_output_t_type, &sctx->output},
{"frames", &qfv_renderframeset_t_type, &rctx->frames},
{"msaaSamples", &VkSampleCountFlagBits_type, &ctx->msaaSamples},
{"physDevLimits", &VkPhysicalDeviceLimits_type,
&ctx->device->physDev->properties->limits },
{}
};
exprctx.external_variables = QFV_CreateSymtab (item, "properties",
extra_items, var_syms,
&exprctx);
int ret;
if (!(ret = parse_qfv_jobinfo_t (0, item, ji, messages, &parsectx))) {
for (int i = 0; i < PL_A_NumObjects (messages); i++) {
Sys_Printf ("%s\n", PL_String (PL_ObjectAtIndex (messages, i)));
}
}
QFV_DestroySymtab (exprctx.external_variables);
PL_Release (messages);
if (!ret) {
delete_memsuper (memsuper);
ji = 0;
}
return ji;
}
struct qfv_samplerinfo_s *
QFV_ParseSamplerInfo (vulkan_ctx_t *ctx, plitem_t *item, qfv_renderctx_t *rctx)
{
memsuper_t *memsuper = new_memsuper ();
qfv_samplerinfo_t *si = cmemalloc (memsuper, sizeof (qfv_samplerinfo_t));
*si = (qfv_samplerinfo_t) { .memsuper = memsuper };
scriptctx_t *sctx = ctx->script_context;
plitem_t *messages = PL_NewArray ();
exprctx_t exprctx = {
.symtab = &root_symtab,
.messages = messages,
.hashctx = &sctx->hashctx,
.memsuper = memsuper,
};
parsectx_t parsectx = {
.ectx = &exprctx,
.vctx = ctx,
.data = rctx,
};
exprsym_t var_syms[] = {
{"physDevLimits", &VkPhysicalDeviceLimits_type,
&ctx->device->physDev->properties->limits },
{}
};
exprctx.external_variables = QFV_CreateSymtab (item, "properties",
0, var_syms, &exprctx);
int ret;
if (!(ret = parse_qfv_samplerinfo_t (0, item, si, messages, &parsectx))) {
for (int i = 0; i < PL_A_NumObjects (messages); i++) {
Sys_Printf ("%s\n", PL_String (PL_ObjectAtIndex (messages, i)));
}
}
QFV_DestroySymtab (exprctx.external_variables);
PL_Release (messages);
if (!ret) {
delete_memsuper (memsuper);
si = 0;
}
return si;
}
int
QFV_ParseLayoutInfo (vulkan_ctx_t *ctx, memsuper_t *memsuper,
exprtab_t *symtab, const char *ref,
qfv_layoutinfo_t *layout)
{
*layout = (qfv_layoutinfo_t) {};
scriptctx_t *sctx = ctx->script_context;
plitem_t *messages = PL_NewArray ();
exprctx_t exprctx = {
.symtab = &root_symtab,
.messages = messages,
.hashctx = &sctx->hashctx,
.memsuper = memsuper,
.external_variables = symtab,
};
parsectx_t parsectx = {
.ectx = &exprctx,
.vctx = ctx,
};
plitem_t *item = PL_NewString (ref);
int ret;
if (!(ret = parse_qfv_layoutinfo_t (0, item, layout, messages,
&parsectx))) {
for (int i = 0; i < PL_A_NumObjects (messages); i++) {
Sys_Printf ("%s\n", PL_String (PL_ObjectAtIndex (messages, i)));
}
}
PL_Release (messages);
PL_Release (item);
return ret;
}