godot/drivers/gles2/shader_compiler_gles2.cpp

743 lines
24 KiB
C++

/*************************************************************************/
/* shader_compiler_gles2.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* http://www.godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */
/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
#include "shader_compiler_gles2.h"
#include "print_string.h"
#include "stdio.h"
//#define DEBUG_SHADER_ENABLED
typedef ShaderLanguage SL;
struct CodeGLSL2 {
String code;
};
static String _mktab(int p_level) {
String tb;
for(int i=0;i<p_level;i++) {
tb+="\t";
}
return tb;
}
static String _typestr(SL::DataType p_type) {
switch(p_type) {
case SL::TYPE_VOID: return "void";
case SL::TYPE_BOOL: return "bool";
case SL::TYPE_FLOAT: return "float";
case SL::TYPE_VEC2: return "vec2";
case SL::TYPE_VEC3: return "vec3";
case SL::TYPE_VEC4: return "vec4";
case SL::TYPE_MAT3: return "mat3";
case SL::TYPE_MAT4: return "mat4";
case SL::TYPE_TEXTURE: return "sampler2D";
case SL::TYPE_CUBEMAP: return "samplerCube";
}
return "";
}
static String _mknum(float p_num) {
return String::num_real(p_num);
}
static String _opstr(SL::Operator p_op) {
switch(p_op) {
case SL::OP_ASSIGN: return "=";
case SL::OP_ADD: return "+";
case SL::OP_SUB: return "-";
case SL::OP_MUL: return "*";
case SL::OP_DIV: return "/";
case SL::OP_ASSIGN_ADD: return "+=";
case SL::OP_ASSIGN_SUB: return "-=";
case SL::OP_ASSIGN_MUL: return "*=";
case SL::OP_ASSIGN_DIV: return "/=";
case SL::OP_NEG: return "-";
case SL::OP_NOT: return "!";
case SL::OP_CMP_EQ: return "==";
case SL::OP_CMP_NEQ: return "!=";
case SL::OP_CMP_LEQ: return "<=";
case SL::OP_CMP_GEQ: return ">=";
case SL::OP_CMP_LESS: return "<";
case SL::OP_CMP_GREATER: return ">";
case SL::OP_CMP_OR: return "||";
case SL::OP_CMP_AND: return "&&";
default: return "";
}
return "";
}
//#ifdef DEBUG_SHADER_ENABLED
#if 1
#define ENDL "\n"
#else
#define ENDL ""
#endif
String ShaderCompilerGLES2::dump_node_code(SL::Node *p_node,int p_level,bool p_assign_left) {
String code;
switch(p_node->type) {
case SL::Node::TYPE_PROGRAM: {
SL::ProgramNode *pnode=(SL::ProgramNode*)p_node;
code+=dump_node_code(pnode->body,p_level);
} break;
case SL::Node::TYPE_FUNCTION: {
} break;
case SL::Node::TYPE_BLOCK: {
SL::BlockNode *bnode=(SL::BlockNode*)p_node;
//variables
for(Map<StringName,SL::DataType>::Element *E=bnode->variables.front();E;E=E->next()) {
code+=_mktab(p_level)+_typestr(E->value())+" "+replace_string(E->key())+";"ENDL;
}
for(int i=0;i<bnode->statements.size();i++) {
code+=_mktab(p_level)+dump_node_code(bnode->statements[i],p_level)+";"ENDL;
}
} break;
case SL::Node::TYPE_VARIABLE: {
SL::VariableNode *vnode=(SL::VariableNode*)p_node;
if (type==ShaderLanguage::SHADER_MATERIAL_VERTEX) {
if (vnode->name==vname_vertex && p_assign_left) {
vertex_code_writes_vertex=true;
}
if (vnode->name==vname_color_interp) {
flags->use_color_interp=true;
}
if (vnode->name==vname_uv_interp) {
flags->use_uv_interp=true;
}
if (vnode->name==vname_uv2_interp) {
flags->use_uv2_interp=true;
}
if (vnode->name==vname_var1_interp) {
flags->use_var1_interp=true;
}
if (vnode->name==vname_var2_interp) {
flags->use_var2_interp=true;
}
if (vnode->name==vname_tangent_interp || vnode->name==vname_binormal_interp) {
flags->use_tangent_interp=true;
}
}
if (type==ShaderLanguage::SHADER_MATERIAL_FRAGMENT) {
if (vnode->name==vname_discard) {
uses_discard=true;
}
if (vnode->name==vname_normalmap) {
uses_normalmap=true;
}
if (vnode->name==vname_screen_uv) {
uses_screen_uv=true;
}
if (vnode->name==vname_diffuse_alpha && p_assign_left) {
uses_alpha=true;
}
if (vnode->name==vname_color_interp) {
flags->use_color_interp=true;
}
if (vnode->name==vname_uv_interp) {
flags->use_uv_interp=true;
}
if (vnode->name==vname_uv2_interp) {
flags->use_uv2_interp=true;
}
if (vnode->name==vname_var1_interp) {
flags->use_var1_interp=true;
}
if (vnode->name==vname_var2_interp) {
flags->use_var2_interp=true;
}
if (vnode->name==vname_tangent_interp || vnode->name==vname_binormal_interp) {
flags->use_tangent_interp=true;
}
}
if (type==ShaderLanguage::SHADER_MATERIAL_LIGHT) {
if (vnode->name==vname_light) {
uses_light=true;
}
}
if (vnode->name==vname_time) {
uses_time=true;
}
code=replace_string(vnode->name);
} break;
case SL::Node::TYPE_CONSTANT: {
SL::ConstantNode *cnode=(SL::ConstantNode*)p_node;
switch(cnode->datatype) {
case SL::TYPE_BOOL: code=cnode->value.operator bool()?"true":"false"; break;
case SL::TYPE_FLOAT: code=_mknum(cnode->value); break; //force zeros, so GLSL doesn't confuse with integer.
case SL::TYPE_VEC2: { Vector2 v = cnode->value; code="vec2("+_mknum(v.x)+", "+_mknum(v.y)+")"; } break;
case SL::TYPE_VEC3: { Vector3 v = cnode->value; code="vec3("+_mknum(v.x)+", "+_mknum(v.y)+", "+_mknum(v.z)+")"; } break;
case SL::TYPE_VEC4: { Plane v = cnode->value; code="vec4("+_mknum(v.normal.x)+", "+_mknum(v.normal.y)+", "+_mknum(v.normal.z)+", "+_mknum(v.d)+")"; } break;
case SL::TYPE_MAT3: { Matrix3 x = cnode->value; code="mat3( vec3("+_mknum(x.get_axis(0).x)+", "+_mknum(x.get_axis(0).y)+", "+_mknum(x.get_axis(0).z)+"), vec3("+_mknum(x.get_axis(1).x)+", "+_mknum(x.get_axis(1).y)+", "+_mknum(x.get_axis(1).z)+"), vec3("+_mknum(x.get_axis(2).x)+", "+_mknum(x.get_axis(2).y)+", "+_mknum(x.get_axis(2).z)+"))"; } break;
case SL::TYPE_MAT4: { Transform x = cnode->value; code="mat4( vec4("+_mknum(x.basis.get_axis(0).x)+", "+_mknum(x.basis.get_axis(0).y)+", "+_mknum(x.basis.get_axis(0).z)+",0.0), vec4("+_mknum(x.basis.get_axis(1).x)+", "+_mknum(x.basis.get_axis(1).y)+", "+_mknum(x.basis.get_axis(1).z)+",0.0), vec4("+_mknum(x.basis.get_axis(2).x)+", "+_mknum(x.basis.get_axis(2).y)+", "+_mknum(x.basis.get_axis(2).z)+",0.0), vec4("+_mknum(x.origin.x)+", "+_mknum(x.origin.y)+", "+_mknum(x.origin.z)+",1.0))"; } break;
default: code="<error: "+Variant::get_type_name(cnode->value.get_type())+" ("+itos(cnode->datatype)+">";
}
} break;
case SL::Node::TYPE_OPERATOR: {
SL::OperatorNode *onode=(SL::OperatorNode*)p_node;
switch(onode->op) {
case SL::OP_ASSIGN_MUL: {
if (onode->arguments[0]->get_datatype()==SL::TYPE_VEC3 && onode->arguments[1]->get_datatype()==SL::TYPE_MAT4) {
String mul_l=dump_node_code(onode->arguments[0],p_level,true);
String mul_r=dump_node_code(onode->arguments[1],p_level);
code=mul_l+"=(vec4("+mul_l+",1.0)*("+mul_r+")).xyz";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_MAT4 && onode->arguments[1]->get_datatype()==SL::TYPE_VEC3) {
String mul_l=dump_node_code(onode->arguments[0],p_level,true);
String mul_r=dump_node_code(onode->arguments[1],p_level);
code=mul_l+"=(("+mul_l+")*vec4("+mul_r+",1.0)).xyz";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_VEC2 && onode->arguments[1]->get_datatype()==SL::TYPE_MAT4) {
String mul_l=dump_node_code(onode->arguments[0],p_level,true);
String mul_r=dump_node_code(onode->arguments[1],p_level);
code=mul_l+"=(vec4("+mul_l+",1.0,1.0)*("+mul_r+")).xy";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_MAT4 && onode->arguments[1]->get_datatype()==SL::TYPE_VEC2) {
String mul_l=dump_node_code(onode->arguments[0],p_level,true);
String mul_r=dump_node_code(onode->arguments[1],p_level);
code=mul_l+"=(("+mul_l+")*vec4("+mul_r+",1.0,1.0)).xy";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_VEC2 && onode->arguments[1]->get_datatype()==SL::TYPE_MAT3) {
String mul_l=dump_node_code(onode->arguments[0],p_level,true);
String mul_r=dump_node_code(onode->arguments[1],p_level);
code=mul_l+"=(("+mul_l+")*vec3("+mul_r+",1.0)).xy";
break;
}
};
case SL::OP_ASSIGN:
case SL::OP_ASSIGN_ADD:
case SL::OP_ASSIGN_SUB:
case SL::OP_ASSIGN_DIV:
code="("+dump_node_code(onode->arguments[0],p_level,true)+_opstr(onode->op)+dump_node_code(onode->arguments[1],p_level)+")";
break;
case SL::OP_MUL:
if (onode->arguments[0]->get_datatype()==SL::TYPE_MAT4 && onode->arguments[1]->get_datatype()==SL::TYPE_VEC3) {
code="("+dump_node_code(onode->arguments[0],p_level)+"*vec4("+dump_node_code(onode->arguments[1],p_level)+",1.0)).xyz";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_VEC3 && onode->arguments[1]->get_datatype()==SL::TYPE_MAT4) {
code="(vec4("+dump_node_code(onode->arguments[0],p_level)+",1.0)*"+dump_node_code(onode->arguments[1],p_level)+").xyz";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_MAT4 && onode->arguments[1]->get_datatype()==SL::TYPE_VEC2) {
code="("+dump_node_code(onode->arguments[0],p_level)+"*vec4("+dump_node_code(onode->arguments[1],p_level)+",1.0,1.0)).xyz";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_VEC2 && onode->arguments[1]->get_datatype()==SL::TYPE_MAT4) {
code="(vec4("+dump_node_code(onode->arguments[0],p_level)+",1.0,1.0)*"+dump_node_code(onode->arguments[1],p_level)+").xyz";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_MAT3 && onode->arguments[1]->get_datatype()==SL::TYPE_VEC2) {
code="("+dump_node_code(onode->arguments[0],p_level)+"*vec3("+dump_node_code(onode->arguments[1],p_level)+",1.0)).xy";
break;
} else if (onode->arguments[0]->get_datatype()==SL::TYPE_VEC2 && onode->arguments[1]->get_datatype()==SL::TYPE_MAT3) {
code="(vec3("+dump_node_code(onode->arguments[0],p_level)+",1.0)*"+dump_node_code(onode->arguments[1],p_level)+").xy";
break;
}
case SL::OP_ADD:
case SL::OP_SUB:
case SL::OP_DIV:
case SL::OP_CMP_EQ:
case SL::OP_CMP_NEQ:
case SL::OP_CMP_LEQ:
case SL::OP_CMP_GEQ:
case SL::OP_CMP_LESS:
case SL::OP_CMP_GREATER:
case SL::OP_CMP_OR:
case SL::OP_CMP_AND:
//handle binary
code="("+dump_node_code(onode->arguments[0],p_level)+_opstr(onode->op)+dump_node_code(onode->arguments[1],p_level)+")";
break;
case SL::OP_NEG:
case SL::OP_NOT:
//handle unary
code=_opstr(onode->op)+dump_node_code(onode->arguments[0],p_level);
break;
case SL::OP_CONSTRUCT:
case SL::OP_CALL: {
String callfunc=dump_node_code(onode->arguments[0],p_level);
code=callfunc+"(";
/*if (callfunc=="mat4") {
//fix constructor for mat4
for(int i=1;i<onode->arguments.size();i++) {
if (i>1)
code+=", ";
//transform
code+="vec4( "+dump_node_code(onode->arguments[i],p_level)+(i==4?",1.0)":",0.0)");
}
} else*/ if (callfunc=="tex") {
code="texture2D( "+dump_node_code(onode->arguments[1],p_level)+","+dump_node_code(onode->arguments[2],p_level)+")";
break;
} else if (callfunc=="texcube") {
code="(textureCube( "+dump_node_code(onode->arguments[1],p_level)+",("+dump_node_code(onode->arguments[2],p_level)+")).xyz";
break;
} else if (callfunc=="texscreen") {
//create the call to sample the screen, and clamp it
uses_texscreen=true;
code="(texture2D( texscreen_tex, min(("+dump_node_code(onode->arguments[1],p_level)+").xy*texscreen_screen_mult,texscreen_screen_mult))).rgb";
//code="(texture2D( screen_texture, ("+dump_node_code(onode->arguments[1],p_level)+").xy).rgb";
break;
} else if (callfunc=="texpos") {
//create the call to sample the screen, and clamp it
uses_texpos=true;
code="get_texpos("+dump_node_code(onode->arguments[1],p_level)+"";
// code="get_texpos(gl_ProjectionMatrixInverse * texture2D( depth_texture, clamp(("+dump_node_code(onode->arguments[1],p_level)+").xy,vec2(0.0),vec2(1.0))*gl_LightSource[5].specular.zw+gl_LightSource[5].specular.xy)";
//code="(texture2D( screen_texture, ("+dump_node_code(onode->arguments[1],p_level)+").xy).rgb";
break;
} else {
for(int i=1;i<onode->arguments.size();i++) {
if (i>1)
code+=", ";
//transform
code+=dump_node_code(onode->arguments[i],p_level);
}
}
code+=")";
break;
} break;
default: {}
}
} break;
case SL::Node::TYPE_CONTROL_FLOW: {
SL::ControlFlowNode *cfnode=(SL::ControlFlowNode*)p_node;
if (cfnode->flow_op==SL::FLOW_OP_IF) {
code+="if ("+dump_node_code(cfnode->statements[0],p_level)+") {"ENDL;
code+=dump_node_code(cfnode->statements[1],p_level+1);
if (cfnode->statements.size()==3) {
code+="} else {"ENDL;
code+=dump_node_code(cfnode->statements[2],p_level+1);
}
code+="}"ENDL;
} else if (cfnode->flow_op==SL::FLOW_OP_RETURN) {
if (cfnode->statements.size()) {
code="return "+dump_node_code(cfnode->statements[0],p_level);
} else {
code="return";
}
}
} break;
case SL::Node::TYPE_MEMBER: {
SL::MemberNode *mnode=(SL::MemberNode*)p_node;
String m;
if (mnode->basetype==SL::TYPE_MAT4) {
if (mnode->name=="x")
m="[0]";
else if (mnode->name=="y")
m="[1]";
else if (mnode->name=="z")
m="[2]";
else if (mnode->name=="w")
m="[3]";
} else if (mnode->basetype==SL::TYPE_MAT3) {
if (mnode->name=="x")
m="[0]";
else if (mnode->name=="y")
m="[1]";
else if (mnode->name=="z")
m="[2]";
} else {
m="."+mnode->name;
}
code=dump_node_code(mnode->owner,p_level)+m;
} break;
}
return code;
}
Error ShaderCompilerGLES2::compile_node(SL::ProgramNode *p_program) {
// feed the local replace table and global code
global_code="";
// uniforms first!
int ubase=0;
if (uniforms)
ubase=uniforms->size();
for(Map<StringName,SL::Uniform>::Element *E=p_program->uniforms.front();E;E=E->next()) {
String uline="uniform "+_typestr(E->get().type)+" _"+E->key().operator String()+";"ENDL;
global_code+=uline;
if (uniforms) {
//if (uniforms->has(E->key())) {
// //repeated uniform, error
// ERR_EXPLAIN("Uniform already exists from other shader: "+String(E->key()));
// ERR_FAIL_COND_V(uniforms->has(E->key()),ERR_ALREADY_EXISTS);
//
// }
SL::Uniform u = E->get();
u.order+=ubase;
uniforms->insert(E->key(),u);
}
}
for(int i=0;i<p_program->functions.size();i++) {
SL::FunctionNode *fnode=p_program->functions[i].function;
StringName funcname=fnode->name;
String newfuncname=replace_string(funcname);
String header;
header=_typestr(fnode->return_type)+" "+newfuncname+"(";
for(int i=0;i<fnode->arguments.size();i++) {
if (i>0)
header+=", ";
header+=_typestr(fnode->arguments[i].type)+" "+replace_string(fnode->arguments[i].name);
}
header+=") {"ENDL;
String fcode=header;
fcode+=dump_node_code(fnode->body,1);
fcode+="}"ENDL;
global_code+=fcode;
}
/* for(Map<StringName,SL::DataType>::Element *E=p_program->preexisting_variables.front();E;E=E->next()) {
StringName varname=E->key();
String newvarname=replace_string(varname);
global_code+="uniform "+_typestr(E->get())+" "+newvarname+";"ENDL;
}*/
code=dump_node_code(p_program,0);
#ifdef DEBUG_SHADER_ENABLED
print_line("GLOBAL CODE:\n\n");
print_line(global_code);
global_code=global_code.replace("\n","");
print_line("CODE:\n\n");
print_line(code);
code=code.replace("\n","");
#endif
return OK;
}
Error ShaderCompilerGLES2::create_glsl_120_code(void *p_str,SL::ProgramNode *p_program) {
ShaderCompilerGLES2 *compiler=(ShaderCompilerGLES2*)p_str;
return compiler->compile_node(p_program);
}
String ShaderCompilerGLES2::replace_string(const StringName& p_string) {
Map<StringName,StringName>::Element *E=NULL;
E=replace_table.find(p_string);
if (E)
return E->get();
E=mode_replace_table[type].find(p_string);
if (E)
return E->get();
return "_"+p_string.operator String();
}
Error ShaderCompilerGLES2::compile(const String& p_code, ShaderLanguage::ShaderType p_type, String& r_code_line, String& r_globals_line, Flags& r_flags, Map<StringName,ShaderLanguage::Uniform> *r_uniforms) {
uses_texscreen=false;
uses_texpos=false;
uses_alpha=false;
uses_discard=false;
uses_screen_uv=false;
uses_light=false;
uses_time=false;
uses_normalmap=false;
vertex_code_writes_vertex=false;
uniforms=r_uniforms;
flags=&r_flags;
r_flags.use_color_interp=false;
r_flags.use_uv_interp=false;
r_flags.use_uv2_interp=false;
r_flags.use_tangent_interp=false;
r_flags.use_var1_interp=false;
r_flags.use_var2_interp=false;
r_flags.uses_normalmap=false;
String error;
int errline,errcol;
type=p_type;
Error err = SL::compile(p_code,p_type,create_glsl_120_code,this,&error,&errline,&errcol);
if (err) {
print_line("***Error precompiling shader: "+error);
print_line("error "+itos(errline)+":"+itos(errcol));
return err;
}
r_flags.uses_alpha=uses_alpha;
r_flags.uses_texscreen=uses_texscreen;
r_flags.uses_texpos=uses_texpos;
r_flags.vertex_code_writes_vertex=vertex_code_writes_vertex;
r_flags.uses_discard=uses_discard;
r_flags.uses_screen_uv=uses_screen_uv;
r_flags.uses_light=uses_light;
r_flags.uses_time=uses_time;
r_flags.uses_normalmap=uses_normalmap;
r_code_line=code;
r_globals_line=global_code;
return OK;
}
ShaderCompilerGLES2::ShaderCompilerGLES2() {
replace_table["bool"]= "bool";
replace_table["float" ]= "float";
replace_table["vec2" ]= "vec2";
replace_table["vec3" ]= "vec3";
replace_table["vec4" ]= "vec4";
replace_table["mat3" ]= "mat3";
replace_table["mat4" ]= "mat4";
replace_table["texture" ]= "sampler2D";
replace_table["cubemap" ]= "samplerCube";
replace_table["sin"]= "sin";
replace_table["cos" ]= "cos";
replace_table["tan" ]= "tan";
replace_table["asin" ]= "asin";
replace_table["acos" ]= "acos";
replace_table["atan" ]= "atan";
replace_table["atan2"]= "atan";
replace_table["sinh" ]= "sinh";
replace_table["cosh" ]= "cosh";
replace_table["tanh" ]= "tanh";
replace_table["pow" ]= "pow";
replace_table["exp" ]= "exp";
replace_table["log" ]= "log";
replace_table["sqrt"]= "sqrt";
replace_table["abs" ]= "abs";
replace_table["sign"]= "sign";
replace_table["floor"]= "floor";
replace_table["trunc"]= "trunc";
#ifdef GLEW_ENABLED
replace_table["round"]= "roundfix";
#else
replace_table["round"]= "round";
#endif
replace_table["ceil" ]= "ceil";
replace_table["fract"]= "fract";
replace_table["mod" ]= "mod";
replace_table["min" ]= "min";
replace_table["max"]= "max";
replace_table["clamp"]= "clamp";
replace_table["mix" ]= "mix";
replace_table["step" ]= "step";
replace_table["smoothstep" ]= "smoothstep";
replace_table["length"]= "length";
replace_table["distance"]= "distance";
replace_table["dot" ]= "dot";
replace_table["cross" ]="cross";
replace_table["normalize"]= "normalize";
replace_table["reflect"]= "reflect";
replace_table["tex"]= "tex";
replace_table["texa"]= "texa";
replace_table["tex2"]= "tex2";
replace_table["texcube"]= "textureCube";
replace_table["texscreen"]= "texscreen";
replace_table["texpos"]= "texpos";
mode_replace_table[0]["SRC_VERTEX"]="vertex_in.xyz";
mode_replace_table[0]["SRC_NORMAL"]="normal_in";
mode_replace_table[0]["SRC_TANGENT"]="tangent_in";
mode_replace_table[0]["SRC_BINORMALF"]="binormalf";
mode_replace_table[0]["VERTEX"]="vertex_interp";
mode_replace_table[0]["NORMAL"]="normal_interp";
mode_replace_table[0]["TANGENT"]="tangent_interp";
mode_replace_table[0]["BINORMAL"]="binormal_interp";
mode_replace_table[0]["UV"]="uv_interp.xy";
mode_replace_table[0]["UV2"]="uv_interp.zw";
mode_replace_table[0]["COLOR"]="color_interp";
//@TODO convert to glsl stuff
mode_replace_table[0]["SPEC_EXP"]="vertex_specular_exp";
mode_replace_table[0]["WORLD_MATRIX"]="world_transform";
mode_replace_table[0]["INV_CAMERA_MATRIX"]="camera_inverse_transform";
mode_replace_table[0]["PROJECTION_MATRIX"]="projection_transform";
mode_replace_table[0]["MODELVIEW_MATRIX"]="modelview";
mode_replace_table[0]["POINT_SIZE"]="gl_PointSize";
mode_replace_table[0]["VAR1"]="var1_interp";
mode_replace_table[0]["VAR2"]="var2_interp";
// mode_replace_table[0]["SCREEN_POS"]="SCREEN_POS";
// mode_replace_table[0]["SCREEN_SIZE"]="SCREEN_SIZE";
mode_replace_table[0]["INSTANCE_ID"]="instance_id";
mode_replace_table[0]["TIME"]="time";
mode_replace_table[1]["VERTEX"]="vertex";
//mode_replace_table[1]["POSITION"]="IN_POSITION";
mode_replace_table[1]["NORMAL"]="normal";
mode_replace_table[1]["TANGENT"]="tangent";
mode_replace_table[1]["BINORMAL"]="binormal";
mode_replace_table[1]["NORMALMAP"]="normalmap";
mode_replace_table[1]["NORMALMAP_DEPTH"]="normaldepth";
mode_replace_table[1]["VAR1"]="var1_interp";
mode_replace_table[1]["VAR2"]="var2_interp";
mode_replace_table[1]["UV"]="uv";
mode_replace_table[1]["UV2"]="uv2";
mode_replace_table[1]["SCREEN_UV"]="screen_uv";
mode_replace_table[1]["VAR1"]="var1_interp";
mode_replace_table[1]["VAR2"]="var2_interp";
mode_replace_table[1]["COLOR"]="color";
mode_replace_table[1]["DIFFUSE"]="diffuse.rgb";
mode_replace_table[1]["DIFFUSE_ALPHA"]="diffuse";
mode_replace_table[1]["SPECULAR"]="specular";
mode_replace_table[1]["EMISSION"]="emission";
mode_replace_table[1]["SHADE_PARAM"]="shade_param";
mode_replace_table[1]["SPEC_EXP"]="specular_exp";
mode_replace_table[1]["GLOW"]="glow";
mode_replace_table[1]["DISCARD"]="discard_";
mode_replace_table[1]["POINT_COORD"]="gl_PointCoord";
mode_replace_table[1]["INV_CAMERA_MATRIX"]="camera_inverse_transform";
//mode_replace_table[1]["SCREEN_POS"]="SCREEN_POS";
//mode_replace_table[1]["SCREEN_TEXEL_SIZE"]="SCREEN_TEXEL_SIZE";
mode_replace_table[1]["TIME"]="time";
//////////////
mode_replace_table[2]["NORMAL"]="normal";
//mode_replace_table[2]["POSITION"]="IN_POSITION";
mode_replace_table[2]["LIGHT_DIR"]="light_dir";
mode_replace_table[2]["LIGHT_DIFFUSE"]="light_diffuse";
mode_replace_table[2]["LIGHT_SPECULAR"]="light_specular";
mode_replace_table[2]["EYE_VEC"]="eye_vec";
mode_replace_table[2]["DIFFUSE"]="mdiffuse";
mode_replace_table[2]["SPECULAR"]="specular";
mode_replace_table[2]["SPECULAR_EXP"]="specular_exp";
mode_replace_table[2]["SHADE_PARAM"]="shade_param";
mode_replace_table[2]["LIGHT"]="light";
mode_replace_table[2]["POINT_COORD"]="gl_PointCoord";
mode_replace_table[2]["TIME"]="time";
//mode_replace_table[2]["SCREEN_POS"]="SCREEN_POS";
//mode_replace_table[2]["SCREEN_TEXEL_SIZE"]="SCREEN_TEXEL_SIZE";
out_vertex_name="VERTEX";
vname_discard="DISCARD";
vname_screen_uv="SCREEN_UV";
vname_diffuse_alpha="DIFFUSE_ALPHA";
vname_color_interp="COLOR";
vname_uv_interp="UV";
vname_uv2_interp="UV2";
vname_tangent_interp="TANGENT";
vname_binormal_interp="BINORMAL";
vname_var1_interp="VAR1";
vname_var2_interp="VAR2";
vname_vertex="VERTEX";
vname_light="LIGHT";
vname_time="TIME";
vname_normalmap="NORMALMAP";
}