blender-archive/source/blender/draw/intern/draw_manager_data.c

/*
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
 *
 * Copyright 2016, Blender Foundation.
 */

/** \file
 * \ingroup draw
 */

#include "draw_manager.h"

#include "BKE_anim.h"
#include "BKE_curve.h"
#include "BKE_global.h"
#include "BKE_mesh.h"
#include "BKE_object.h"
#include "BKE_paint.h"
#include "BKE_pbvh.h"

#include "DNA_curve_types.h"
#include "DNA_mesh_types.h"
#include "DNA_meta_types.h"

#include "BLI_hash.h"
#include "BLI_link_utils.h"
#include "BLI_mempool.h"

#include "intern/gpu_codegen.h"

struct GPUVertFormat *g_pos_format = NULL;

/* -------------------------------------------------------------------- */
/** \name Uniform Buffer Object (DRW_uniformbuffer)
 * \{ */

GPUUniformBuffer *DRW_uniformbuffer_create(int size, const void *data)
{
	return GPU_uniformbuffer_create(size, data, NULL);
}

void DRW_uniformbuffer_update(GPUUniformBuffer *ubo, const void *data)
{
	GPU_uniformbuffer_update(ubo, data);
}

void DRW_uniformbuffer_free(GPUUniformBuffer *ubo)
{
	GPU_uniformbuffer_free(ubo);
}

/** \} */

/* -------------------------------------------------------------------- */
/** \name Uniforms (DRW_shgroup_uniform)
 * \{ */

static void drw_shgroup_uniform_create_ex(DRWShadingGroup *shgroup, int loc,
                                            DRWUniformType type, const void *value, int length, int arraysize)
{
	DRWUniform *uni = BLI_mempool_alloc(DST.vmempool->uniforms);
	uni->location = loc;
	uni->type = type;
	uni->length = length;
	uni->arraysize = arraysize;

	switch (type) {
		case DRW_UNIFORM_INT_COPY:
			uni->ivalue = *((int *)value);
			break;
		case DRW_UNIFORM_BOOL_COPY:
			uni->ivalue = (int)*((bool *)value);
			break;
		case DRW_UNIFORM_FLOAT_COPY:
			uni->fvalue = *((float *)value);
			break;
		default:
			uni->pvalue = value;
			break;
	}

	BLI_LINKS_PREPEND(shgroup->uniforms, uni);
}

static void drw_shgroup_builtin_uniform(
        DRWShadingGroup *shgroup, int builtin, const void *value, int length, int arraysize)
{
	int loc = GPU_shader_get_builtin_uniform(shgroup->shader, builtin);

	if (loc != -1) {
		drw_shgroup_uniform_create_ex(shgroup, loc, DRW_UNIFORM_FLOAT, value, length, arraysize);
	}
}

static void drw_shgroup_uniform(DRWShadingGroup *shgroup, const char *name,
                                  DRWUniformType type, const void *value, int length, int arraysize)
{
	int location;
	if (ELEM(type, DRW_UNIFORM_BLOCK, DRW_UNIFORM_BLOCK_PERSIST)) {
		location = GPU_shader_get_uniform_block(shgroup->shader, name);
	}
	else {
		location = GPU_shader_get_uniform(shgroup->shader, name);
	}

	if (location == -1) {
		/* Nice to enable eventually, for now eevee uses uniforms that might not exist. */
		// BLI_assert(0);
		return;
	}

	BLI_assert(arraysize > 0 && arraysize <= 16);
	BLI_assert(length >= 0 && length <= 16);

	drw_shgroup_uniform_create_ex(shgroup, location, type, value, length, arraysize);

	/* If location is -2, the uniform has not yet been queried.
	 * We save the name for query just before drawing. */
	if (location == -2 || DRW_DEBUG_USE_UNIFORM_NAME) {
		int ofs = DST.uniform_names.buffer_ofs;
		int max_len = DST.uniform_names.buffer_len - ofs;
		size_t len = strlen(name) + 1;

		if (len >= max_len) {
			DST.uniform_names.buffer_len += DRW_UNIFORM_BUFFER_NAME_INC;
			DST.uniform_names.buffer = MEM_reallocN(DST.uniform_names.buffer, DST.uniform_names.buffer_len);
		}

		char *dst = DST.uniform_names.buffer + ofs;
		memcpy(dst, name, len); /* Copies NULL terminator. */

		DST.uniform_names.buffer_ofs += len;
		shgroup->uniforms->name_ofs = ofs;
	}
}

void DRW_shgroup_uniform_texture(DRWShadingGroup *shgroup, const char *name, const GPUTexture *tex)
{
	BLI_assert(tex != NULL);
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_TEXTURE, tex, 0, 1);
}

/* Same as DRW_shgroup_uniform_texture but is guaranteed to be bound if shader does not change between shgrp. */
void DRW_shgroup_uniform_texture_persistent(DRWShadingGroup *shgroup, const char *name, const GPUTexture *tex)
{
	BLI_assert(tex != NULL);
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_TEXTURE_PERSIST, tex, 0, 1);
}

void DRW_shgroup_uniform_block(DRWShadingGroup *shgroup, const char *name, const GPUUniformBuffer *ubo)
{
	BLI_assert(ubo != NULL);
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_BLOCK, ubo, 0, 1);
}

/* Same as DRW_shgroup_uniform_block but is guaranteed to be bound if shader does not change between shgrp. */
void DRW_shgroup_uniform_block_persistent(DRWShadingGroup *shgroup, const char *name, const GPUUniformBuffer *ubo)
{
	BLI_assert(ubo != NULL);
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_BLOCK_PERSIST, ubo, 0, 1);
}

void DRW_shgroup_uniform_texture_ref(DRWShadingGroup *shgroup, const char *name, GPUTexture **tex)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_TEXTURE_REF, tex, 0, 1);
}

void DRW_shgroup_uniform_bool(DRWShadingGroup *shgroup, const char *name, const int *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_BOOL, value, 1, arraysize);
}

void DRW_shgroup_uniform_float(DRWShadingGroup *shgroup, const char *name, const float *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT, value, 1, arraysize);
}

void DRW_shgroup_uniform_vec2(DRWShadingGroup *shgroup, const char *name, const float *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT, value, 2, arraysize);
}

void DRW_shgroup_uniform_vec3(DRWShadingGroup *shgroup, const char *name, const float *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT, value, 3, arraysize);
}

void DRW_shgroup_uniform_vec4(DRWShadingGroup *shgroup, const char *name, const float *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT, value, 4, arraysize);
}

void DRW_shgroup_uniform_short_to_int(DRWShadingGroup *shgroup, const char *name, const short *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_SHORT_TO_INT, value, 1, arraysize);
}

void DRW_shgroup_uniform_short_to_float(DRWShadingGroup *shgroup, const char *name, const short *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_SHORT_TO_FLOAT, value, 1, arraysize);
}

void DRW_shgroup_uniform_int(DRWShadingGroup *shgroup, const char *name, const int *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_INT, value, 1, arraysize);
}

void DRW_shgroup_uniform_ivec2(DRWShadingGroup *shgroup, const char *name, const int *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_INT, value, 2, arraysize);
}

void DRW_shgroup_uniform_ivec3(DRWShadingGroup *shgroup, const char *name, const int *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_INT, value, 3, arraysize);
}

void DRW_shgroup_uniform_ivec4(DRWShadingGroup *shgroup, const char *name, const int *value, int arraysize)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_INT, value, 4, arraysize);
}

void DRW_shgroup_uniform_mat3(DRWShadingGroup *shgroup, const char *name, const float (*value)[3])
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT, (float *)value, 9, 1);
}

void DRW_shgroup_uniform_mat4(DRWShadingGroup *shgroup, const char *name, const float (*value)[4])
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT, (float *)value, 16, 1);
}

/* Stores the int instead of a pointer. */
void DRW_shgroup_uniform_int_copy(DRWShadingGroup *shgroup, const char *name, const int value)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_INT_COPY, &value, 1, 1);
}

void DRW_shgroup_uniform_bool_copy(DRWShadingGroup *shgroup, const char *name, const bool value)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_BOOL_COPY, &value, 1, 1);
}

void DRW_shgroup_uniform_float_copy(DRWShadingGroup *shgroup, const char *name, const float value)
{
	drw_shgroup_uniform(shgroup, name, DRW_UNIFORM_FLOAT_COPY, &value, 1, 1);
}


/** \} */

/* -------------------------------------------------------------------- */
/** \name Draw Call (DRW_calls)
 * \{ */

static void drw_call_calc_orco(Object *ob, float (*r_orcofacs)[3])
{
	ID *ob_data = (ob) ? ob->data : NULL;
	float *texcoloc = NULL;
	float *texcosize = NULL;
	if (ob_data != NULL) {
		switch (GS(ob_data->name)) {
			case ID_ME:
				BKE_mesh_texspace_get_reference((Mesh *)ob_data, NULL, &texcoloc, NULL, &texcosize);
				break;
			case ID_CU:
			{
				Curve *cu = (Curve *)ob_data;
				if (cu->bb == NULL || (cu->bb->flag & BOUNDBOX_DIRTY)) {
					BKE_curve_texspace_calc(cu);
				}
				texcoloc = cu->loc;
				texcosize = cu->size;
				break;
			}
			case ID_MB:
			{
				MetaBall *mb = (MetaBall *)ob_data;
				texcoloc = mb->loc;
				texcosize = mb->size;
				break;
			}
			default:
				break;
		}
	}

	if ((texcoloc != NULL) && (texcosize != NULL)) {
		mul_v3_v3fl(r_orcofacs[1], texcosize, 2.0f);
		invert_v3(r_orcofacs[1]);
		sub_v3_v3v3(r_orcofacs[0], texcoloc, texcosize);
		negate_v3(r_orcofacs[0]);
		mul_v3_v3(r_orcofacs[0], r_orcofacs[1]); /* result in a nice MADD in the shader */
	}
	else {
		copy_v3_fl(r_orcofacs[0], 0.0f);
		copy_v3_fl(r_orcofacs[1], 1.0f);
	}
}

static void drw_call_state_update_matflag(DRWCallState *state, DRWShadingGroup *shgroup, Object *ob)
{
	uint16_t new_flags = ((state->matflag ^ shgroup->matflag) & shgroup->matflag);

	/* HACK: Here we set the matflags bit to 1 when computing the value
	 * so that it's not recomputed for other drawcalls.
	 * This is the opposite of what draw_matrices_model_prepare() does. */
	state->matflag |= shgroup->matflag;

	/* Orco factors: We compute this at creation to not have to save the *ob_data */
	if ((new_flags & DRW_CALL_ORCOTEXFAC) != 0) {
		drw_call_calc_orco(ob, state->orcotexfac);
	}

	if ((new_flags & DRW_CALL_OBJECTINFO) != 0) {
		state->objectinfo[0] = ob ? ob->index : 0;
		uint random;
		if (DST.dupli_source) {
			random = DST.dupli_source->random_id;
		}
		else {
			random = BLI_hash_int_2d(BLI_hash_string(ob->id.name + 2), 0);
		}
		state->objectinfo[1] = random * (1.0f / (float)0xFFFFFFFF);
	}
}

static DRWCallState *drw_call_state_create(DRWShadingGroup *shgroup, float (*obmat)[4], Object *ob)
{
	DRWCallState *state = BLI_mempool_alloc(DST.vmempool->states);
	state->flag = 0;
	state->cache_id = 0;
	state->visibility_cb = NULL;
	state->matflag = 0;

	/* Matrices */
	if (obmat != NULL) {
		copy_m4_m4(state->model, obmat);

		if (is_negative_m4(state->model)) {
			state->flag |= DRW_CALL_NEGSCALE;
		}
	}
	else {
		unit_m4(state->model);
	}

	if (ob != NULL) {
		float corner[3];
		BoundBox *bbox = BKE_object_boundbox_get(ob);
		/* Get BoundSphere center and radius from the BoundBox. */
		mid_v3_v3v3(state->bsphere.center, bbox->vec[0], bbox->vec[6]);
		mul_v3_m4v3(corner, obmat, bbox->vec[0]);
		mul_m4_v3(obmat, state->bsphere.center);
		state->bsphere.radius = len_v3v3(state->bsphere.center, corner);
	}
	else {
		/* Bypass test. */
		state->bsphere.radius = -1.0f;
	}

	drw_call_state_update_matflag(state, shgroup, ob);

	return state;
}

static DRWCallState *drw_call_state_object(DRWShadingGroup *shgroup, float (*obmat)[4], Object *ob)
{
	if (DST.ob_state == NULL) {
		DST.ob_state = drw_call_state_create(shgroup, obmat, ob);
	}
	else {
		/* If the DRWCallState is reused, add necessary matrices. */
		drw_call_state_update_matflag(DST.ob_state, shgroup, ob);
	}

	return DST.ob_state;
}

void DRW_shgroup_call_add(DRWShadingGroup *shgroup, GPUBatch *geom, float (*obmat)[4])
{
	BLI_assert(geom != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_create(shgroup, obmat, NULL);
	call->type = DRW_CALL_SINGLE;
	call->single.geometry = geom;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

void DRW_shgroup_call_range_add(DRWShadingGroup *shgroup, GPUBatch *geom, float (*obmat)[4], uint v_sta, uint v_count)
{
	BLI_assert(geom != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));
	BLI_assert(v_count);

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_create(shgroup, obmat, NULL);
	call->type = DRW_CALL_RANGE;
	call->range.geometry = geom;
	call->range.start = v_sta;
	call->range.count = v_count;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

static void drw_shgroup_call_procedural_add_ex(
        DRWShadingGroup *shgroup, GPUPrimType prim_type, uint vert_count, float (*obmat)[4], Object *ob)
{
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	if (ob) {
		call->state = drw_call_state_object(shgroup, ob->obmat, ob);
	}
	else {
		call->state = drw_call_state_create(shgroup, obmat, NULL);
	}
	call->type = DRW_CALL_PROCEDURAL;
	call->procedural.prim_type = prim_type;
	call->procedural.vert_count = vert_count;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

void DRW_shgroup_call_procedural_points_add(DRWShadingGroup *shgroup, uint point_len, float (*obmat)[4])
{
	drw_shgroup_call_procedural_add_ex(shgroup, GPU_PRIM_POINTS, point_len, obmat, NULL);
}

void DRW_shgroup_call_procedural_lines_add(DRWShadingGroup *shgroup, uint line_count, float (*obmat)[4])
{
	drw_shgroup_call_procedural_add_ex(shgroup, GPU_PRIM_LINES, line_count * 2, obmat, NULL);
}

void DRW_shgroup_call_procedural_triangles_add(DRWShadingGroup *shgroup, uint tria_count, float (*obmat)[4])
{
	drw_shgroup_call_procedural_add_ex(shgroup, GPU_PRIM_TRIS, tria_count * 3, obmat, NULL);
}

/* TODO (fclem): this is a sign that the api is starting to be limiting.
 * Maybe add special function that general purpose for special cases. */
void DRW_shgroup_call_object_procedural_triangles_culled_add(DRWShadingGroup *shgroup, uint tria_count, Object *ob)
{
	drw_shgroup_call_procedural_add_ex(shgroup, GPU_PRIM_TRIS, tria_count * 3, NULL, ob);
}

/* These calls can be culled and are optimized for redraw */
void DRW_shgroup_call_object_add_ex(DRWShadingGroup *shgroup, GPUBatch *geom, Object *ob, Material *ma, bool bypass_culling)
{
	BLI_assert(geom != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_object(shgroup, ob->obmat, ob);
	call->type = DRW_CALL_SINGLE;
	call->single.geometry = geom;
	call->single.ma_index = ma ? ma->index : 0;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	/* NOTE this will disable culling for the whole object. */
	call->state->flag |= (bypass_culling) ? DRW_CALL_BYPASS_CULLING : 0;

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

void DRW_shgroup_call_object_add_with_callback(
        DRWShadingGroup *shgroup, GPUBatch *geom, Object *ob, Material *ma,
        DRWCallVisibilityFn *callback, void *user_data)
{
	BLI_assert(geom != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_object(shgroup, ob->obmat, ob);
	call->state->visibility_cb = callback;
	call->state->user_data = user_data;
	call->type = DRW_CALL_SINGLE;
	call->single.geometry = geom;
	call->single.ma_index = ma ? ma->index : 0;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

void DRW_shgroup_call_instances_add(DRWShadingGroup *shgroup, GPUBatch *geom, float (*obmat)[4], uint *count)
{
	BLI_assert(geom != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_create(shgroup, obmat, NULL);
	call->type = DRW_CALL_INSTANCES;
	call->instances.geometry = geom;
	call->instances.count = count;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

/* These calls can be culled and are optimized for redraw */
void DRW_shgroup_call_object_instances_add(DRWShadingGroup *shgroup, GPUBatch *geom, Object *ob, uint *count)
{
	BLI_assert(geom != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_object(shgroup, ob->obmat, ob);
	call->type = DRW_CALL_INSTANCES;
	call->instances.geometry = geom;
	call->instances.count = count;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

void DRW_shgroup_call_generate_add(
        DRWShadingGroup *shgroup,
        DRWCallGenerateFn *geometry_fn, void *user_data,
        float (*obmat)[4])
{
	BLI_assert(geometry_fn != NULL);
	BLI_assert(ELEM(shgroup->type, DRW_SHG_NORMAL, DRW_SHG_FEEDBACK_TRANSFORM));

	DRWCall *call = BLI_mempool_alloc(DST.vmempool->calls);
	call->state = drw_call_state_create(shgroup, obmat, NULL);
	call->type = DRW_CALL_GENERATE;
	call->generate.geometry_fn = geometry_fn;
	call->generate.user_data = user_data;
#ifdef USE_GPU_SELECT
	call->select_id = DST.select_id;
#endif

	BLI_LINKS_APPEND(&shgroup->calls, call);
}

static void sculpt_draw_cb(
        DRWShadingGroup *shgroup,
        void (*draw_fn)(DRWShadingGroup *shgroup, GPUBatch *geom),
        void *user_data)
{
	Object *ob = user_data;

	/* XXX should be ensured before but sometime it's not... go figure (see T57040). */
	PBVH *pbvh = BKE_sculpt_object_pbvh_ensure(DST.draw_ctx.depsgraph, ob);

	const DRWContextState *drwctx = DRW_context_state_get();
	int fast_mode = 0;

	if (drwctx->evil_C != NULL) {
		Paint *p = BKE_paint_get_active_from_context(drwctx->evil_C);
		if (p && (p->flags & PAINT_FAST_NAVIGATE)) {
			fast_mode = drwctx->rv3d->rflag & RV3D_NAVIGATING;
		}
	}

	if (pbvh) {
		BKE_pbvh_draw_cb(
		        pbvh, NULL, NULL, fast_mode, false, false,
		        (void (*)(void *, GPUBatch *))draw_fn, shgroup);
	}
}

static void sculpt_draw_wires_cb(
        DRWShadingGroup *shgroup,
        void (*draw_fn)(DRWShadingGroup *shgroup, GPUBatch *geom),
        void *user_data)
{
	Object *ob = user_data;

	/* XXX should be ensured before but sometime it's not... go figure (see T57040). */
	PBVH *pbvh = BKE_sculpt_object_pbvh_ensure(DST.draw_ctx.depsgraph, ob);

	const DRWContextState *drwctx = DRW_context_state_get();
	int fast_mode = 0;

	if (drwctx->evil_C != NULL) {
		Paint *p = BKE_paint_get_active_from_context(drwctx->evil_C);
		if (p && (p->flags & PAINT_FAST_NAVIGATE)) {
			fast_mode = drwctx->rv3d->rflag & RV3D_NAVIGATING;
		}
	}

	if (pbvh) {
		BKE_pbvh_draw_cb(
		        pbvh, NULL, NULL, fast_mode, true, false,
		        (void (*)(void *, GPUBatch *))draw_fn, shgroup);
	}
}

void DRW_shgroup_call_sculpt_add(DRWShadingGroup *shgroup, Object *ob, float (*obmat)[4])
{
	DRW_shgroup_call_generate_add(shgroup, sculpt_draw_cb, ob, obmat);
}

void DRW_shgroup_call_sculpt_wires_add(DRWShadingGroup *shgroup, Object *ob, float (*obmat)[4])
{
	DRW_shgroup_call_generate_add(shgroup, sculpt_draw_wires_cb, ob, obmat);
}

void DRW_shgroup_call_dynamic_add_array(DRWShadingGroup *shgroup, const void *attr[], uint attr_len)
{
#ifdef USE_GPU_SELECT
	if (G.f & G_FLAG_PICKSEL) {
		if (shgroup->instance_count == shgroup->inst_selectid->vertex_len) {
			GPU_vertbuf_data_resize(shgroup->inst_selectid, shgroup->instance_count + 32);
		}
		GPU_vertbuf_attr_set(shgroup->inst_selectid, 0, shgroup->instance_count, &DST.select_id);
	}
#endif

	BLI_assert(attr_len == shgroup->attrs_count);
	UNUSED_VARS_NDEBUG(attr_len);

	for (int i = 0; i < attr_len; ++i) {
		if (shgroup->instance_count == shgroup->instance_vbo->vertex_len) {
			GPU_vertbuf_data_resize(shgroup->instance_vbo, shgroup->instance_count + 32);
		}
		GPU_vertbuf_attr_set(shgroup->instance_vbo, i, shgroup->instance_count, attr[i]);
	}

	shgroup->instance_count += 1;
}

/** \} */

/* -------------------------------------------------------------------- */
/** \name Shading Groups (DRW_shgroup)
 * \{ */

static void drw_shgroup_init(DRWShadingGroup *shgroup, GPUShader *shader)
{
	shgroup->instance_geom = NULL;
	shgroup->instance_vbo = NULL;
	shgroup->instance_count = 0;
	shgroup->uniforms = NULL;
#ifdef USE_GPU_SELECT
	shgroup->inst_selectid = NULL;
	shgroup->override_selectid = -1;
#endif
#ifndef NDEBUG
	shgroup->attrs_count = 0;
#endif

	int view_ubo_location = GPU_shader_get_uniform_block(shader, "viewBlock");

	if (view_ubo_location != -1) {
		drw_shgroup_uniform_create_ex(shgroup, view_ubo_location, DRW_UNIFORM_BLOCK_PERSIST, G_draw.view_ubo, 0, 1);
	}
	else {
		/* Only here to support builtin shaders. This should not be used by engines. */
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_VIEW, DST.view_data.matstate.mat[DRW_MAT_VIEW], 16, 1);
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_VIEW_INV, DST.view_data.matstate.mat[DRW_MAT_VIEWINV], 16, 1);
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_VIEWPROJECTION, DST.view_data.matstate.mat[DRW_MAT_PERS], 16, 1);
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_VIEWPROJECTION_INV, DST.view_data.matstate.mat[DRW_MAT_PERSINV], 16, 1);
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_PROJECTION, DST.view_data.matstate.mat[DRW_MAT_WIN], 16, 1);
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_PROJECTION_INV, DST.view_data.matstate.mat[DRW_MAT_WININV], 16, 1);
		drw_shgroup_builtin_uniform(shgroup, GPU_UNIFORM_CAMERATEXCO, DST.view_data.viewcamtexcofac, 3, 2);
	}

	shgroup->model = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_MODEL);
	shgroup->modelinverse = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_MODEL_INV);
	shgroup->modelview = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_MODELVIEW);
	shgroup->modelviewinverse = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_MODELVIEW_INV);
	shgroup->modelviewprojection = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_MVP);
	shgroup->normalview = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_NORMAL);
	shgroup->normalviewinverse = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_NORMAL_INV);
	shgroup->normalworld = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_WORLDNORMAL);
	shgroup->orcotexfac = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_ORCO);
	shgroup->objectinfo = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_OBJECT_INFO);
	shgroup->eye = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_EYE);
	shgroup->callid = GPU_shader_get_builtin_uniform(shader, GPU_UNIFORM_CALLID);

	shgroup->matflag = 0;
	if (shgroup->modelinverse > -1) {
		shgroup->matflag |= DRW_CALL_MODELINVERSE;
	}
	if (shgroup->modelview > -1) {
		shgroup->matflag |= DRW_CALL_MODELVIEW;
	}
	if (shgroup->modelviewinverse > -1) {
		shgroup->matflag |= DRW_CALL_MODELVIEWINVERSE;
	}
	if (shgroup->modelviewprojection > -1) {
		shgroup->matflag |= DRW_CALL_MODELVIEWPROJECTION;
	}
	if (shgroup->normalview > -1) {
		shgroup->matflag |= DRW_CALL_NORMALVIEW;
	}
	if (shgroup->normalviewinverse > -1) {
		shgroup->matflag |= DRW_CALL_NORMALVIEWINVERSE;
	}
	if (shgroup->normalworld > -1) {
		shgroup->matflag |= DRW_CALL_NORMALWORLD;
	}
	if (shgroup->orcotexfac > -1) {
		shgroup->matflag |= DRW_CALL_ORCOTEXFAC;
	}
	if (shgroup->objectinfo > -1) {
		shgroup->matflag |= DRW_CALL_OBJECTINFO;
	}
	if (shgroup->eye > -1) {
		shgroup->matflag |= DRW_CALL_EYEVEC;
	}
}

static void drw_shgroup_instance_init(
        DRWShadingGroup *shgroup, GPUShader *shader, GPUBatch *batch, GPUVertFormat *format)
{
	BLI_assert(shgroup->type == DRW_SHG_INSTANCE);
	BLI_assert(batch != NULL);
	BLI_assert(format != NULL);

	drw_shgroup_init(shgroup, shader);

	shgroup->instance_geom = batch;
#ifndef NDEBUG
	shgroup->attrs_count = format->attr_len;
#endif

	DRW_instancing_buffer_request(DST.idatalist, format, batch, shgroup,
	                              &shgroup->instance_geom, &shgroup->instance_vbo);

#ifdef USE_GPU_SELECT
	if (G.f & G_FLAG_PICKSEL) {
		/* Not actually used for rendering but alloced in one chunk.
		 * Plus we don't have to care about ownership. */
		static GPUVertFormat inst_select_format = {0};
		if (inst_select_format.attr_len == 0) {
			GPU_vertformat_attr_add(&inst_select_format, "selectId", GPU_COMP_I32, 1, GPU_FETCH_INT);
		}
		GPUBatch *batch_dummy; /* Not used */
		DRW_batching_buffer_request(DST.idatalist, &inst_select_format,
		                            GPU_PRIM_POINTS, shgroup,
		                            &batch_dummy, &shgroup->inst_selectid);
	}
#endif
}

static void drw_shgroup_batching_init(
        DRWShadingGroup *shgroup, GPUShader *shader, GPUVertFormat *format)
{
	drw_shgroup_init(shgroup, shader);

#ifndef NDEBUG
	shgroup->attrs_count = (format != NULL) ? format->attr_len : 0;
#endif
	BLI_assert(format != NULL);

	GPUPrimType type;
	switch (shgroup->type) {
		case DRW_SHG_POINT_BATCH: type = GPU_PRIM_POINTS; break;
		case DRW_SHG_LINE_BATCH: type = GPU_PRIM_LINES; break;
		case DRW_SHG_TRIANGLE_BATCH: type = GPU_PRIM_TRIS; break;
		default: type = GPU_PRIM_NONE; BLI_assert(0); break;
	}

	DRW_batching_buffer_request(DST.idatalist, format, type, shgroup,
	                            &shgroup->batch_geom, &shgroup->batch_vbo);

#ifdef USE_GPU_SELECT
	if (G.f & G_FLAG_PICKSEL) {
		/* Not actually used for rendering but alloced in one chunk. */
		static GPUVertFormat inst_select_format = {0};
		if (inst_select_format.attr_len == 0) {
			GPU_vertformat_attr_add(&inst_select_format, "selectId", GPU_COMP_I32, 1, GPU_FETCH_INT);
		}
		GPUBatch *batch; /* Not used */
		DRW_batching_buffer_request(DST.idatalist, &inst_select_format,
		                            GPU_PRIM_POINTS, shgroup,
		                            &batch, &shgroup->inst_selectid);
	}
#endif
}

static DRWShadingGroup *drw_shgroup_create_ex(struct GPUShader *shader, DRWPass *pass)
{
	DRWShadingGroup *shgroup = BLI_mempool_alloc(DST.vmempool->shgroups);

	BLI_LINKS_APPEND(&pass->shgroups, shgroup);

	shgroup->type = DRW_SHG_NORMAL;
	shgroup->shader = shader;
	shgroup->state_extra = 0;
	shgroup->state_extra_disable = ~0x0;
	shgroup->stencil_mask = 0;
	shgroup->calls.first = NULL;
	shgroup->calls.last = NULL;
#if 0 /* All the same in the union! */
	shgroup->batch_geom = NULL;
	shgroup->batch_vbo = NULL;

	shgroup->instance_geom = NULL;
	shgroup->instance_vbo = NULL;
#endif
	shgroup->pass_parent = pass;

	return shgroup;
}

static DRWShadingGroup *drw_shgroup_material_create_ex(GPUPass *gpupass, DRWPass *pass)
{
	if (!gpupass) {
		/* Shader compilation error */
		return NULL;
	}

	GPUShader *sh = GPU_pass_shader_get(gpupass);

	if (!sh) {
		/* Shader not yet compiled */
		return NULL;
	}

	DRWShadingGroup *grp = drw_shgroup_create_ex(sh, pass);
	return grp;
}

static DRWShadingGroup *drw_shgroup_material_inputs(DRWShadingGroup *grp, struct GPUMaterial *material)
{
	ListBase *inputs = GPU_material_get_inputs(material);

	/* Converting dynamic GPUInput to DRWUniform */
	for (GPUInput *input = inputs->first; input; input = input->next) {
		/* Textures */
		if (input->source == GPU_SOURCE_TEX) {
			GPUTexture *tex = NULL;

			if (input->ima) {
				tex = GPU_texture_from_blender(input->ima, input->iuser, GL_TEXTURE_2D, input->image_isdata);
			}
			else {
				/* Color Ramps */
				tex = *input->coba;
			}

			if (input->bindtex) {
				drw_shgroup_uniform_create_ex(grp, input->shaderloc, DRW_UNIFORM_TEXTURE, tex, 0, 1);
			}
		}
	}

	GPUUniformBuffer *ubo = GPU_material_uniform_buffer_get(material);
	if (ubo != NULL) {
		DRW_shgroup_uniform_block(grp, GPU_UBO_BLOCK_NAME, ubo);
	}

	return grp;
}

GPUVertFormat *DRW_shgroup_instance_format_array(const DRWInstanceAttrFormat attrs[], int arraysize)
{
	GPUVertFormat *format = MEM_callocN(sizeof(GPUVertFormat), "GPUVertFormat");

	for (int i = 0; i < arraysize; ++i) {
		GPU_vertformat_attr_add(
		        format, attrs[i].name,
		        (attrs[i].type == DRW_ATTR_INT) ? GPU_COMP_I32 : GPU_COMP_F32,
		        attrs[i].components,
		        (attrs[i].type == DRW_ATTR_INT) ? GPU_FETCH_INT : GPU_FETCH_FLOAT);
	}
	return format;
}

DRWShadingGroup *DRW_shgroup_material_create(
        struct GPUMaterial *material, DRWPass *pass)
{
	GPUPass *gpupass = GPU_material_get_pass(material);
	DRWShadingGroup *shgroup = drw_shgroup_material_create_ex(gpupass, pass);

	if (shgroup) {
		drw_shgroup_init(shgroup, GPU_pass_shader_get(gpupass));
		drw_shgroup_material_inputs(shgroup, material);
	}

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_material_instance_create(
        struct GPUMaterial *material, DRWPass *pass, GPUBatch *geom, Object *ob, GPUVertFormat *format)
{
	GPUPass *gpupass = GPU_material_get_pass(material);
	DRWShadingGroup *shgroup = drw_shgroup_material_create_ex(gpupass, pass);

	if (shgroup) {
		shgroup->type = DRW_SHG_INSTANCE;
		shgroup->instance_geom = geom;
		drw_call_calc_orco(ob, shgroup->instance_orcofac);
		drw_shgroup_instance_init(shgroup, GPU_pass_shader_get(gpupass), geom, format);
		drw_shgroup_material_inputs(shgroup, material);
	}

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_material_empty_tri_batch_create(
        struct GPUMaterial *material, DRWPass *pass, int tri_count)
{
#ifdef USE_GPU_SELECT
	BLI_assert((G.f & G_FLAG_PICKSEL) == 0);
#endif
	GPUPass *gpupass = GPU_material_get_pass(material);
	DRWShadingGroup *shgroup = drw_shgroup_material_create_ex(gpupass, pass);

	if (shgroup) {
		/* Calling drw_shgroup_init will cause it to call GPU_draw_primitive(). */
		drw_shgroup_init(shgroup, GPU_pass_shader_get(gpupass));
		shgroup->type = DRW_SHG_TRIANGLE_BATCH;
		shgroup->instance_count = tri_count * 3;
		drw_shgroup_material_inputs(shgroup, material);
	}

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_create(struct GPUShader *shader, DRWPass *pass)
{
	DRWShadingGroup *shgroup = drw_shgroup_create_ex(shader, pass);
	drw_shgroup_init(shgroup, shader);
	return shgroup;
}

DRWShadingGroup *DRW_shgroup_instance_create(
        struct GPUShader *shader, DRWPass *pass, GPUBatch *geom, GPUVertFormat *format)
{
	DRWShadingGroup *shgroup = drw_shgroup_create_ex(shader, pass);
	shgroup->type = DRW_SHG_INSTANCE;
	shgroup->instance_geom = geom;
	drw_call_calc_orco(NULL, shgroup->instance_orcofac);
	drw_shgroup_instance_init(shgroup, shader, geom, format);

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_point_batch_create(struct GPUShader *shader, DRWPass *pass)
{
	DRW_shgroup_instance_format(g_pos_format, {{"pos", DRW_ATTR_FLOAT, 3}});

	DRWShadingGroup *shgroup = drw_shgroup_create_ex(shader, pass);
	shgroup->type = DRW_SHG_POINT_BATCH;

	drw_shgroup_batching_init(shgroup, shader, g_pos_format);

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_line_batch_create_with_format(
        struct GPUShader *shader, DRWPass *pass, GPUVertFormat *format)
{
	DRWShadingGroup *shgroup = drw_shgroup_create_ex(shader, pass);
	shgroup->type = DRW_SHG_LINE_BATCH;

	drw_shgroup_batching_init(shgroup, shader, format);

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_line_batch_create(struct GPUShader *shader, DRWPass *pass)
{
	DRW_shgroup_instance_format(g_pos_format, {{"pos", DRW_ATTR_FLOAT, 3}});

	return DRW_shgroup_line_batch_create_with_format(shader, pass, g_pos_format);
}

/**
 * Very special batch. Use this if you position
 * your vertices with the vertex shader
 * and dont need any VBO attribute.
 */
DRWShadingGroup *DRW_shgroup_empty_tri_batch_create(struct GPUShader *shader, DRWPass *pass, int tri_count)
{
#ifdef USE_GPU_SELECT
	BLI_assert((G.f & G_FLAG_PICKSEL) == 0);
#endif
	DRWShadingGroup *shgroup = drw_shgroup_create_ex(shader, pass);

	/* Calling drw_shgroup_init will cause it to call GPU_draw_primitive(). */
	drw_shgroup_init(shgroup, shader);

	shgroup->type = DRW_SHG_TRIANGLE_BATCH;
	shgroup->instance_count = tri_count * 3;

	return shgroup;
}

DRWShadingGroup *DRW_shgroup_transform_feedback_create(struct GPUShader *shader, DRWPass *pass, GPUVertBuf *tf_target)
{
	BLI_assert(tf_target != NULL);
	DRWShadingGroup *shgroup = drw_shgroup_create_ex(shader, pass);
	shgroup->type = DRW_SHG_FEEDBACK_TRANSFORM;

	drw_shgroup_init(shgroup, shader);

	shgroup->tfeedback_target = tf_target;

	return shgroup;
}

/**
 * Specify an external batch instead of adding each attribute one by one.
 */
void DRW_shgroup_instance_batch(DRWShadingGroup *shgroup, struct GPUBatch *batch)
{
	BLI_assert(shgroup->type == DRW_SHG_INSTANCE);
	BLI_assert(shgroup->instance_count == 0);
	/* You cannot use external instancing batch without a dummy format. */
	BLI_assert(shgroup->attrs_count != 0);

	shgroup->type = DRW_SHG_INSTANCE_EXTERNAL;
	drw_call_calc_orco(NULL, shgroup->instance_orcofac);
	/* PERF : This destroys the vaos cache so better check if it's necessary. */
	/* Note: This WILL break if batch->verts[0] is destroyed and reallocated
	 * at the same address. Bindings/VAOs would remain obsolete. */
	//if (shgroup->instancing_geom->inst != batch->verts[0])
	GPU_batch_instbuf_set(shgroup->instance_geom, batch->verts[0], false);

#ifdef USE_GPU_SELECT
	shgroup->override_selectid = DST.select_id;
#endif
}

uint DRW_shgroup_get_instance_count(const DRWShadingGroup *shgroup)
{
	return shgroup->instance_count;
}

/**
 * State is added to #Pass.state while drawing.
 * Use to temporarily enable draw options.
 */
void DRW_shgroup_state_enable(DRWShadingGroup *shgroup, DRWState state)
{
	shgroup->state_extra |= state;
}

void DRW_shgroup_state_disable(DRWShadingGroup *shgroup, DRWState state)
{
	shgroup->state_extra_disable &= ~state;
}

void DRW_shgroup_stencil_mask(DRWShadingGroup *shgroup, uint mask)
{
	BLI_assert(mask <= 255);
	shgroup->stencil_mask = mask;
}

bool DRW_shgroup_is_empty(DRWShadingGroup *shgroup)
{
	switch (shgroup->type) {
		case DRW_SHG_NORMAL:
		case DRW_SHG_FEEDBACK_TRANSFORM:
			return shgroup->calls.first == NULL;
		case DRW_SHG_POINT_BATCH:
		case DRW_SHG_LINE_BATCH:
		case DRW_SHG_TRIANGLE_BATCH:
		case DRW_SHG_INSTANCE:
		case DRW_SHG_INSTANCE_EXTERNAL:
			return shgroup->instance_count == 0;
	}
	BLI_assert(!"Shading Group type not supported");
	return true;
}

DRWShadingGroup *DRW_shgroup_create_sub(DRWShadingGroup *shgroup)
{
	/* Remove this assertion if needed but implement the other cases first! */
	BLI_assert(shgroup->type == DRW_SHG_NORMAL);

	DRWShadingGroup *shgroup_new = BLI_mempool_alloc(DST.vmempool->shgroups);

	*shgroup_new = *shgroup;
	shgroup_new->uniforms = NULL;
	shgroup_new->calls.first = NULL;
	shgroup_new->calls.last = NULL;

	BLI_LINKS_INSERT_AFTER(&shgroup->pass_parent->shgroups, shgroup, shgroup_new);

	return shgroup_new;
}

/** \} */

/* -------------------------------------------------------------------- */
/** \name Passes (DRW_pass)
 * \{ */

DRWPass *DRW_pass_create(const char *name, DRWState state)
{
	DRWPass *pass = BLI_mempool_alloc(DST.vmempool->passes);
	pass->state = state;
	if (((G.debug_value > 20) && (G.debug_value < 30)) ||
	     (G.debug & G_DEBUG))
	{
		BLI_strncpy(pass->name, name, MAX_PASS_NAME);
	}

	pass->shgroups.first = NULL;
	pass->shgroups.last = NULL;

	return pass;
}

bool DRW_pass_is_empty(DRWPass *pass)
{
	for (DRWShadingGroup *shgroup = pass->shgroups.first; shgroup; shgroup = shgroup->next) {
		if (!DRW_shgroup_is_empty(shgroup)) {
			return false;
		}
	}
	return true;
}

void DRW_pass_state_set(DRWPass *pass, DRWState state)
{
	pass->state = state;
}

void DRW_pass_state_add(DRWPass *pass, DRWState state)
{
	pass->state |= state;
}

void DRW_pass_state_remove(DRWPass *pass, DRWState state)
{
	pass->state &= ~state;
}

void DRW_pass_free(DRWPass *pass)
{
	pass->shgroups.first = NULL;
	pass->shgroups.last = NULL;
}

void DRW_pass_foreach_shgroup(DRWPass *pass, void (*callback)(void *userData, DRWShadingGroup *shgrp), void *userData)
{
	for (DRWShadingGroup *shgroup = pass->shgroups.first; shgroup; shgroup = shgroup->next) {
		callback(userData, shgroup);
	}
}

typedef struct ZSortData {
	float *axis;
	float *origin;
} ZSortData;

static int pass_shgroup_dist_sort(void *thunk, const void *a, const void *b)
{
	const ZSortData *zsortdata = (ZSortData *)thunk;
	const DRWShadingGroup *shgrp_a = (const DRWShadingGroup *)a;
	const DRWShadingGroup *shgrp_b = (const DRWShadingGroup *)b;

	const DRWCall *call_a = (DRWCall *)shgrp_a->calls.first;
	const DRWCall *call_b = (DRWCall *)shgrp_b->calls.first;

	if (call_a == NULL) { return -1; }
	if (call_b == NULL) { return -1; }

	float tmp[3];
	sub_v3_v3v3(tmp, zsortdata->origin, call_a->state->model[3]);
	const float a_sq = dot_v3v3(zsortdata->axis, tmp);
	sub_v3_v3v3(tmp, zsortdata->origin, call_b->state->model[3]);
	const float b_sq = dot_v3v3(zsortdata->axis, tmp);

	if      (a_sq < b_sq) { return  1; }
	else if (a_sq > b_sq) { return -1; }
	else {
		/* If there is a depth prepass put it before */
		if ((shgrp_a->state_extra & DRW_STATE_WRITE_DEPTH) != 0) {
			return -1;
		}
		else if ((shgrp_b->state_extra & DRW_STATE_WRITE_DEPTH) != 0) {
			return  1;
		}
		else {
			return  0;
		}
	}
}

/* ------------------ Shading group sorting --------------------- */

#define SORT_IMPL_LINKTYPE DRWShadingGroup

#define SORT_IMPL_USE_THUNK
#define SORT_IMPL_FUNC shgroup_sort_fn_r
#include "../../blenlib/intern/list_sort_impl.h"
#undef SORT_IMPL_FUNC
#undef SORT_IMPL_USE_THUNK

#undef SORT_IMPL_LINKTYPE

/**
 * Sort Shading groups by decreasing Z of their first draw call.
 * This is useful for order dependent effect such as transparency.
 */
void DRW_pass_sort_shgroup_z(DRWPass *pass)
{
	float (*viewinv)[4];
	viewinv = DST.view_data.matstate.mat[DRW_MAT_VIEWINV];

	ZSortData zsortdata = {viewinv[2], viewinv[3]};

	if (pass->shgroups.first && pass->shgroups.first->next) {
		pass->shgroups.first = shgroup_sort_fn_r(pass->shgroups.first, pass_shgroup_dist_sort, &zsortdata);

		/* Find the next last */
		DRWShadingGroup *last = pass->shgroups.first;
		while ((last = last->next)) {
			/* Do nothing */
		}
		pass->shgroups.last = last;
	}
}

/** \} */