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source: trunk/src/gfx/mesh_creator.cc @ 411

Last change on this file since 411 was 411, checked in by epyon, 10 years ago
mesh_raw_channel and key_raw_channel merged into raw_data_channel
File size: 14.9 KB

Rev	Line
[395]	1	// Copyright (C) 2012-2015 ChaosForge Ltd
[293]	2	// http://chaosforge.org/
	3	//
[395]	4	// This file is part of Nova libraries.
	5	// For conditions of distribution and use, see copying.txt file in root folder.
[293]	6
	7	#include "nv/gfx/mesh_creator.hh"
	8
	9	struct nv_key_transform { nv::transform tform; };
	10
	11	void nv::mesh_nodes_creator::pre_transform_keys()
	12	{
	13	if ( m_data->m_flat ) return;
	14	merge_keys();
	15	uint32 max_frames = 0;
	16	for ( size_t i = 0; i < m_data->get_count(); ++i )
	17	{
	18	sint16 parent_id = m_data->m_nodes[i].parent_id;
	19	key_data* keys = m_data->m_nodes[i].data;
	20	key_data* pkeys = ( parent_id != -1 ? m_data->m_nodes[parent_id].data : nullptr );
[411]	21	size_t count = ( keys ? keys->get_channel(0)->element_count() : 0 );
	22	size_t pcount = ( pkeys ? pkeys->get_channel(0)->element_count() : 0 );
[398]	23	max_frames = nv::max<uint32>( count, max_frames );
[293]	24	if ( pkeys && pkeys->get_channel_count() > 0 && keys && keys->get_channel_count() > 0 )
	25	{
[406]	26	nv_key_transform* channel = reinterpret_cast<nv_key_transform*>(keys->get_channel(0)->data);
	27	nv_key_transform* pchannel = reinterpret_cast<nv_key_transform*>(pkeys->get_channel(0)->data);
[293]	28	for ( unsigned n = 0; n < count; ++n )
	29	{
[398]	30	channel[n].tform = pchannel[ nv::min( n, pcount-1 ) ].tform * channel[n].tform;
[293]	31	}
	32	}
	33	}
	34
	35	// DAE pre_transform hack
	36	if ( m_data->m_frame_rate == 1 )
	37	{
	38	m_data->m_frame_rate = 32;
[406]	39	m_data->m_duration = static_cast<float>( max_frames );
[293]	40	}
	41
	42	m_data->m_flat = true;
	43	}
	44
	45	// TODO: DELETE
	46	struct assimp_key_p { float time; nv::vec3 position; };
	47	struct assimp_key_r { float time; nv::quat rotation; };
	48
	49
	50	void nv::mesh_nodes_creator::merge_keys()
	51	{
	52	for ( size_t i = 0; i < m_data->get_count(); ++i )
	53	{
	54	key_data* old_keys = m_data->m_nodes[i].data;
	55	if ( old_keys && old_keys->get_channel_count() > 0 )
	56	{
	57	size_t chan_count = old_keys->get_channel_count();
	58	if ( chan_count == 1
[410]	59	&& old_keys->get_channel(0)->desc.slot_count() == 1
	60	&& old_keys->get_channel(0)->desc[0].etype == TRANSFORM ) continue;
[293]	61
	62	size_t max_keys = 0;
	63	for ( size_t c = 0; c < chan_count; ++c )
	64	{
[398]	65	max_keys = nv::max( max_keys, old_keys->get_channel(c)->count );
[293]	66	}
	67
[411]	68	raw_data_channel* raw_channel = raw_data_channel::create<nv_key_transform>( max_keys );
[293]	69	key_data* new_keys = new key_data;
	70	new_keys->add_channel( raw_channel );
[406]	71	nv_key_transform* channel = reinterpret_cast<nv_key_transform*>(raw_channel->data);
[410]	72	data_descriptor final_key = old_keys->get_final_key();
[293]	73
	74	for ( unsigned n = 0; n < max_keys; ++n )
	75	{
	76	float key[ 16 ];
	77	float* pkey = key;
	78
	79	for ( uint16 c = 0; c < chan_count; ++c )
	80	{
[398]	81	size_t idx = nv::min( old_keys->get_channel(c)->count - 1, n );
[411]	82	pkey += old_keys->get_raw( old_keys->get_channel(c), idx, pkey );
[293]	83	}
	84	channel[n].tform = extract_transform_raw( final_key, key );
	85	}
	86
	87	delete old_keys;
	88	m_data->m_nodes[i].data = new_keys;
	89	}
	90	}
	91	}
	92
	93	void nv::mesh_nodes_creator::transform( float scale, const mat3& r33 )
	94	{
	95	mat3 ri33 = glm::inverse( r33 );
	96	mat4 pre_transform ( scale * r33 );
	97	mat4 post_transform( 1.f/scale * ri33 );
	98
	99	for ( size_t i = 0; i < m_data->get_count(); ++i )
	100	{
	101	mesh_node_data& node = m_data->m_nodes[i];
	102	node.transform = pre_transform * node.transform * post_transform;
	103	if ( node.data )
	104	{
	105	key_data* kdata = node.data;
	106	for ( size_t c = 0; c < kdata->get_channel_count(); ++c )
	107	{
[411]	108	const raw_data_channel* channel = kdata->get_channel(c);
[410]	109	size_t key_size = channel->desc.element_size();
[293]	110	for ( size_t n = 0; n < channel->count; ++n )
	111	{
[406]	112	transform_key_raw( channel->desc, channel->data + n * key_size, scale, r33, ri33 );
[293]	113	}
	114	}
	115	}
	116	}
	117	}
	118
	119	void nv::mesh_data_creator::transform( float scale, const mat3& r33 )
	120	{
[398]	121	vec3 vertex_offset = vec3();
[293]	122	mat3 vertex_transform = scale * r33;
	123	mat3 normal_transform = r33;
	124
	125	for ( uint32 c = 0; c < m_data->get_channel_count(); ++c )
	126	{
[411]	127	const raw_data_channel* channel = m_data->get_channel(c);
[410]	128	const data_descriptor& desc = channel->desc;
[293]	129	uint8* raw_data = channel->data;
[410]	130	uint32 vtx_size = desc.element_size();
[293]	131	int p_offset = -1;
	132	int n_offset = -1;
	133	int t_offset = -1;
[410]	134	for ( const auto& cslot : desc )
	135	switch ( cslot.vslot )
[293]	136	{
[410]	137	case slot::POSITION : if ( cslot.etype == FLOAT_VECTOR_3 ) p_offset = int( cslot.offset ); break;
	138	case slot::NORMAL : if ( cslot.etype == FLOAT_VECTOR_3 ) n_offset = int( cslot.offset ); break;
	139	case slot::TANGENT : if ( cslot.etype == FLOAT_VECTOR_4 ) t_offset = int( cslot.offset ); break;
[293]	140	default : break;
	141	}
	142
	143	if ( p_offset != -1 )
	144	for ( uint32 i = 0; i < channel->count; i++)
	145	{
[406]	146	vec3& p = reinterpret_cast<vec3>( raw_data + vtx_size*i + p_offset );
[293]	147	p = vertex_transform * p + vertex_offset;
	148	}
	149
	150	if ( n_offset != -1 )
	151	for ( uint32 i = 0; i < channel->count; i++)
	152	{
[406]	153	vec3& n = reinterpret_cast<vec3>( raw_data + vtx_size*i + n_offset );
[293]	154	n = glm::normalize( normal_transform * n );
	155	}
	156	if ( t_offset != -1 )
	157	for ( uint32 i = 0; i < channel->count; i++)
	158	{
[406]	159	vec4& t = reinterpret_cast<vec4>(raw_data + vtx_size*i + t_offset );
[293]	160	t = vec4( glm::normalize( normal_transform * vec3(t) ), t[3] );
	161	}
	162	}
	163	}
[294]	164
	165	struct vertex_g
	166	{
	167	nv::vec4 tangent;
	168	};
	169
[295]	170	void nv::mesh_data_creator::flip_normals()
	171	{
	172	int ch_n = m_data->get_channel_index( slot::NORMAL );
	173	size_t n_offset = 0;
	174	if ( ch_n == -1 ) return;
[411]	175	raw_data_channel* channel = m_data->m_channels[ unsigned( ch_n ) ];
[410]	176	for ( const auto& cslot : channel->desc )
	177	if ( cslot.vslot == slot::NORMAL )
[295]	178	{
[410]	179	n_offset = cslot.offset;
[295]	180	}
	181
	182	for ( uint32 i = 0; i < channel->count; ++i )
	183	{
[410]	184	vec3& normal = reinterpret_cast<vec3>( channel->data + channel->desc.element_size() * i + n_offset );
[295]	185	normal = -normal;
	186	}
	187	}
	188
	189
[294]	190	void nv::mesh_data_creator::generate_tangents()
	191	{
	192	int p_offset = -1;
	193	int n_offset = -1;
	194	int t_offset = -1;
	195	datatype i_type = NONE;
	196	uint32 n_channel_index = 0;
	197
[411]	198	const raw_data_channel* p_channel = nullptr;
	199	raw_data_channel* n_channel = nullptr;
	200	const raw_data_channel* t_channel = nullptr;
	201	const raw_data_channel* i_channel = nullptr;
[294]	202
	203	for ( uint32 c = 0; c < m_data->get_channel_count(); ++c )
	204	{
[411]	205	const raw_data_channel* channel = m_data->get_channel(c);
[410]	206
	207	for ( const auto& cslot : channel->desc )
	208	switch ( cslot.vslot )
[294]	209	{
	210	case slot::POSITION :
[410]	211	if ( cslot.etype == FLOAT_VECTOR_3 )
[294]	212	{
[410]	213	p_offset = int( cslot.offset );
[294]	214	p_channel = channel;
	215	}
	216	break;
[410]	217	case slot::NORMAL :
	218	if ( cslot.etype == FLOAT_VECTOR_3 )
[294]	219	{
[410]	220	n_offset = int( cslot.offset );
[294]	221	n_channel = m_data->m_channels[ c ];
	222	n_channel_index = c;
	223	}
	224	break;
[410]	225	case slot::TEXCOORD :
	226	if ( cslot.etype == FLOAT_VECTOR_2 )
[294]	227	{
[410]	228	t_offset = int( cslot.offset );
[294]	229	t_channel = channel;
	230	}
	231	break;
	232	case slot::INDEX :
	233	{
[410]	234	i_type = cslot.etype;
[294]	235	i_channel = channel;
	236	}
	237	break;
	238	case slot::TANGENT : return;
	239	default : break;
	240	}
	241	}
	242	if ( !p_channel \|\| !n_channel \|\| !t_channel ) return;
	243
	244	if ( p_channel->count != n_channel->count \|\| p_channel->count % t_channel->count != 0 \|\| ( i_type != UINT && i_type != USHORT && i_type != NONE ) )
	245	{
	246	return;
	247	}
	248
[411]	249	raw_data_channel* g_channel = raw_data_channel::create<vertex_g>( p_channel->count );
[406]	250	vec4* tangents = reinterpret_cast<vec4*>( g_channel->data );
[294]	251	vec3* tangents2 = new vec3[ p_channel->count ];
	252	uint32 tri_count = i_channel ? i_channel->count / 3 : t_channel->count / 3;
	253	uint32 vtx_count = p_channel->count;
	254	uint32 sets = p_channel->count / t_channel->count;
	255
	256	for ( unsigned int i = 0; i < tri_count; ++i )
	257	{
	258	uint32 ti0 = 0;
	259	uint32 ti1 = 0;
	260	uint32 ti2 = 0;
	261	if ( i_type == UINT )
	262	{
[406]	263	const uint32* idata = reinterpret_cast<const uint32*>( i_channel->data );
[294]	264	ti0 = idata[ i * 3 ];
	265	ti1 = idata[ i * 3 + 1 ];
	266	ti2 = idata[ i * 3 + 2 ];
	267	}
	268	else if ( i_type == USHORT )
	269	{
[406]	270	const uint16* idata = reinterpret_cast<const uint16*>( i_channel->data );
[294]	271	ti0 = idata[ i * 3 ];
	272	ti1 = idata[ i * 3 + 1 ];
	273	ti2 = idata[ i * 3 + 2 ];
	274	}
	275	else // if ( i_type == NONE )
	276	{
	277	ti0 = i * 3;
	278	ti1 = i * 3 + 1;
	279	ti2 = i * 3 + 2;
	280	}
	281
[410]	282	const vec2& w1 = reinterpret_cast<vec2>(t_channel->data + t_channel->desc.element_size()*ti0 + t_offset );
	283	const vec2& w2 = reinterpret_cast<vec2>(t_channel->data + t_channel->desc.element_size()*ti1 + t_offset );
	284	const vec2& w3 = reinterpret_cast<vec2>(t_channel->data + t_channel->desc.element_size()*ti2 + t_offset );
[294]	285	vec2 st1 = w3 - w1;
	286	vec2 st2 = w2 - w1;
	287	float stst = (st1.x * st2.y - st2.x * st1.y);
	288	float coef = ( stst != 0.0f ? 1.0f / stst : 0.0f );
	289
	290	for ( uint32 set = 0; set < sets; ++set )
	291	{
	292	uint32 nti0 = t_channel->count * set + ti0;
	293	uint32 nti1 = t_channel->count * set + ti1;
	294	uint32 nti2 = t_channel->count * set + ti2;
[410]	295	vec3 v1 = reinterpret_cast<vec3>(p_channel->data + p_channel->desc.element_size()*nti0 + p_offset );
	296	vec3 v2 = reinterpret_cast<vec3>(p_channel->data + p_channel->desc.element_size()*nti1 + p_offset );
	297	vec3 v3 = reinterpret_cast<vec3>(p_channel->data + p_channel->desc.element_size()*nti2 + p_offset );
[294]	298	vec3 xyz1 = v3 - v1;
	299	vec3 xyz2 = v2 - v1;
	300
[398]	301	//vec3 normal = glm::cross( xyz1, xyz2 );
[294]	302	//
	303	//vtcs[ ti0 ].normal += normal;
	304	//vtcs[ ti1 ].normal += normal;
	305	//vtcs[ ti2 ].normal += normal;
	306	vec3 tangent = (( xyz1 * st2.y ) - ( xyz2 * st1.y )) * coef;
	307	vec3 tangent2 = (( xyz2 * st1.x ) - ( xyz1 * st2.x )) * coef;
	308
	309	tangents[nti0] = vec4( vec3( tangents[nti0] ) + tangent, 0 );
	310	tangents[nti1] = vec4( vec3( tangents[nti1] ) + tangent, 0 );
	311	tangents[nti2] = vec4( vec3( tangents[nti2] ) + tangent, 0 );
	312
	313	tangents2[nti0] += tangent2;
	314	tangents2[nti1] += tangent2;
	315	tangents2[nti2] += tangent2;
	316	}
	317	}
	318
	319	for ( unsigned int i = 0; i < vtx_count; ++i )
	320	{
[410]	321	const vec3 n = reinterpret_cast<vec3>( n_channel->data + n_channel->desc.element_size()*i + n_offset );
[294]	322	const vec3 t = vec3(tangents[i]);
	323	if ( ! ( t.x == 0.0f && t.y == 0.0f && t.z == 0.0f ) )
	324	{
	325	tangents[i] = vec4( glm::normalize(t - n * glm::dot( n, t )), 0.0f );
	326	tangents[i][3] = (glm::dot(glm::cross(n, t), tangents2[i]) < 0.0f) ? -1.0f : 1.0f;
	327	}
	328	}
	329	delete tangents2;
	330
	331	m_data->m_channels[ n_channel_index ] = merge_channels( n_channel, g_channel );
	332	delete n_channel;
	333	delete g_channel;
	334	}
	335
[411]	336	nv::raw_data_channel* nv::mesh_data_creator::merge_channels( raw_data_channel* a, raw_data_channel* b )
[294]	337	{
	338	NV_ASSERT( a->count == b->count, "merge_channel - bad channels!" );
[410]	339	data_descriptor adesc = a->desc;
	340	data_descriptor bdesc = b->desc;
	341	uint32 count = a->count;
[294]	342
[410]	343	data_descriptor desc = a->desc;
	344	for ( auto bslot : bdesc )
[294]	345	{
[410]	346	desc.push_slot( bslot.etype, bslot.vslot );
[294]	347	}
[410]	348	uint8* data = new uint8[ count * desc.element_size() ];
[294]	349	for ( uint32 i = 0; i < count; ++i )
	350	{
[410]	351	raw_copy_n( a->data + i * adesc.element_size(), adesc.element_size(), data + i*desc.element_size() );
	352	raw_copy_n( b->data + i * bdesc.element_size(), bdesc.element_size(), data + i*desc.element_size() + adesc.element_size() );
[294]	353	}
[411]	354	raw_data_channel* result = new raw_data_channel;
[294]	355	result->count = count;
	356	result->desc = desc;
	357	result->data = data;
	358	return result;
	359	}
[295]	360
[411]	361	nv::raw_data_channel* nv::mesh_data_creator::append_channels( raw_data_channel* a, raw_data_channel* b, uint32 frame_count )
[295]	362	{
	363	if ( a->desc != b->desc ) return nullptr;
	364	if ( a->count % frame_count != 0 ) return nullptr;
	365	if ( b->count % frame_count != 0 ) return nullptr;
[410]	366	size_t vtx_size = a->desc.element_size();
[295]	367
	368	uint8* data = new uint8[ ( a->count + b->count ) * vtx_size ];
	369
	370
	371	if ( frame_count == 1 )
	372	{
	373	size_t a_size = vtx_size * a->count;
[383]	374	raw_copy_n( a->data, a_size, data );
	375	raw_copy_n( b->data, vtx_size * b->count, data + a_size );
[295]	376	}
	377	else
	378	{
	379	size_t frame_size_a = ( a->count / frame_count ) * vtx_size;
	380	size_t frame_size_b = ( b->count / frame_count ) * vtx_size;
	381	size_t pos_a = 0;
	382	size_t pos_b = 0;
	383	size_t pos = 0;
	384	for ( size_t i = 0; i < frame_count; ++i )
	385	{
[383]	386	raw_copy_n( a->data + pos_a, frame_size_a, data + pos );
	387	raw_copy_n( b->data + pos_b, frame_size_b, data + pos + frame_size_a ); pos_a += frame_size_a;
[295]	388	pos_b += frame_size_b;
	389	pos += frame_size_a + frame_size_b;
	390	}
	391	}
	392
[411]	393	raw_data_channel* result = new raw_data_channel;
	394	result->count = a->element_count() + b->element_count();
	395	result->desc = a->descriptor();
[295]	396	result->data = data;
	397	return result;
	398	}
	399
	400
	401
	402	bool nv::mesh_data_creator::is_same_format( mesh_data* other )
	403	{
	404	if ( m_data->get_channel_count() != other->get_channel_count() ) return false;
	405	for ( uint32 c = 0; c < m_data->get_channel_count(); ++c )
	406	{
[411]	407	if ( m_data->get_channel(c)->descriptor() != other->get_channel(c)->descriptor() )
[295]	408	return false;
	409	}
	410	return true;
	411	}
	412
	413	void nv::mesh_data_creator::merge( mesh_data* other )
	414	{
	415	if ( !is_same_format( other ) ) return;
	416	int ch_pi = m_data->get_channel_index( slot::POSITION );
	417	int ch_ti = m_data->get_channel_index( slot::TEXCOORD );
	418	int och_pi = other->get_channel_index( slot::POSITION );
	419	int och_ti = other->get_channel_index( slot::TEXCOORD );
	420	if ( ch_pi == -1 \|\| ch_ti == -1 ) return;
[411]	421	size_t size = m_data->m_channels[ unsigned(ch_ti) ]->element_count();
	422	size_t osize = other->m_channels[ unsigned(och_ti) ]->element_count();
	423	size_t count = m_data->m_channels[ unsigned(ch_pi) ]->element_count();
	424	size_t ocount = other->m_channels[ unsigned(och_pi) ]->element_count();
[295]	425	if ( count % size != 0 \|\| ocount % osize != 0 ) return;
	426	if ( count / size != ocount / osize ) return;
	427
	428	for ( uint32 c = 0; c < m_data->get_channel_count(); ++c )
	429	{
[411]	430	raw_data_channel* old = m_data->m_channels[c];
	431	size_t frame_count = ( old->get_buffer_type() == INDEX_BUFFER ? 1 : old->element_count() / size );
[295]	432	m_data->m_channels[c] = append_channels( old, other->m_channels[c], frame_count );
	433	NV_ASSERT( m_data->m_channels[c], "Merge problem!" );
[302]	434	if ( old->get_buffer_type() == INDEX_BUFFER )
[295]	435	{
[410]	436	switch ( old->desc[0].etype )
[295]	437	{
	438	case USHORT :
	439	{
	440	NV_ASSERT( size + osize < uint16(-1), "Index out of range!" );
[406]	441	uint16* indexes = reinterpret_cast<uint16*>( m_data->m_channels[c]->data );
[411]	442	for ( uint16 i = uint16( old->element_count() ); i < m_data->m_channels[c]->element_count(); ++i )
[406]	443	indexes[i] += uint16( size );
[295]	444
	445	}
	446	break;
	447	case UINT :
	448	{
[406]	449	uint32* indexes = reinterpret_cast<uint32*>( m_data->m_channels[c]->data );
[411]	450	for ( uint32 i = old->element_count(); i < m_data->m_channels[c]->element_count(); ++i )
[295]	451	indexes[i] += size;
	452	}
	453	break;
	454	default : NV_ASSERT( false, "Unsupported index type!" ); break;
	455	}
	456	m_data->m_index_channel = m_data->m_channels[c];
	457	}
	458	delete old;
	459	}
	460	}

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