Resolve and validate the parameters of constructors in GLSL

[libs/gl.git] / source / glsl / generate.cpp

#include <algorithm>
#include <msp/core/hash.h>
#include <msp/core/raii.h>
#include <msp/strings/lexicalcast.h>
#include <msp/strings/utils.h>
#include "builtin.h"
#include "generate.h"

using namespace std;

namespace Msp {
namespace GL {
namespace SL {

ConstantSpecializer::ConstantSpecializer():
        values(0)
{ }

void ConstantSpecializer::apply(Stage &stage, const map<string, int> *v)
{
        values = v;
        stage.content.visit(*this);
}

void ConstantSpecializer::visit(VariableDeclaration &var)
{
        bool specializable = false;
        if(var.layout)
        {
                vector<Layout::Qualifier> &qualifiers = var.layout->qualifiers;
                for(vector<Layout::Qualifier>::iterator i=qualifiers.begin(); i!=qualifiers.end(); ++i)
                        if(i->name=="constant_id")
                        {
                                specializable = true;
                                if(values)
                                        qualifiers.erase(i);
                                else if(i->value==-1)
                                        i->value = hash32(var.name)&0x7FFFFFFF;
                                break;
                        }

                if(qualifiers.empty())
                        var.layout = 0;
        }

        if(specializable && values)
        {
                map<string, int>::const_iterator i = values->find(var.name);
                if(i!=values->end())
                {
                        RefPtr<Literal> literal = new Literal;
                        if(var.type=="bool")
                        {
                                literal->token = (i->second ? "true" : "false");
                                literal->value = static_cast<bool>(i->second);
                        }
                        else if(var.type=="int")
                        {
                                literal->token = lexical_cast<string>(i->second);
                                literal->value = i->second;
                        }
                        var.init_expression = literal;
                }
        }
}


void BlockHierarchyResolver::enter(Block &block)
{
        r_any_resolved |= (current_block!=block.parent);
        block.parent = current_block;
}


TypeResolver::TypeResolver():
        stage(0),
        iface_block(0),
        r_any_resolved(false)
{ }

bool TypeResolver::apply(Stage &s)
{
        stage = &s;
        s.types.clear();
        r_any_resolved = false;
        s.content.visit(*this);
        return r_any_resolved;
}

TypeDeclaration *TypeResolver::get_or_create_array_type(TypeDeclaration &type)
{
        map<TypeDeclaration *, TypeDeclaration *>::iterator i = array_types.find(&type);
        if(i!=array_types.end())
                return i->second;

        BasicTypeDeclaration *array = new BasicTypeDeclaration;
        array->source = BUILTIN_SOURCE;
        array->name = type.name+"[]";
        array->kind = BasicTypeDeclaration::ARRAY;
        array->base = type.name;
        array->base_type = &type;
        stage->content.body.insert(type_insert_point, array);
        array_types[&type] = array;
        return array;
}

void TypeResolver::resolve_type(TypeDeclaration *&type, const string &name, bool array)
{
        TypeDeclaration *resolved = 0;
        map<string, TypeDeclaration *>::iterator i = stage->types.find(name);
        if(i!=stage->types.end())
        {
                map<TypeDeclaration *, TypeDeclaration *>::iterator j = alias_map.find(i->second);
                resolved = (j!=alias_map.end() ? j->second : i->second);
        }

        if(resolved && array)
                resolved = get_or_create_array_type(*resolved);

        r_any_resolved |= (resolved!=type);
        type=resolved;
}

void TypeResolver::visit(Block &block)
{
        for(NodeList<Statement>::iterator i=block.body.begin(); i!=block.body.end(); ++i)
        {
                if(!block.parent)
                        type_insert_point = i;
                (*i)->visit(*this);
        }
}

void TypeResolver::visit(BasicTypeDeclaration &type)
{
        resolve_type(type.base_type, type.base, false);

        if(type.kind==BasicTypeDeclaration::VECTOR && type.base_type)
                if(BasicTypeDeclaration *basic_base = dynamic_cast<BasicTypeDeclaration *>(type.base_type))
                        if(basic_base->kind==BasicTypeDeclaration::VECTOR)
                        {
                                type.kind = BasicTypeDeclaration::MATRIX;
                                /* A matrix's base type is its column vector type.  This will put
                                the column vector's size, i.e. the matrix's row count, in the high
                                half of the size. */
                                type.size |= basic_base->size<<16;
                        }

        if(type.kind==BasicTypeDeclaration::ALIAS && type.base_type)
                alias_map[&type] = type.base_type;
        else if(type.kind==BasicTypeDeclaration::ARRAY && type.base_type)
                array_types[type.base_type] = &type;

        stage->types.insert(make_pair(type.name, &type));
}

void TypeResolver::visit(ImageTypeDeclaration &type)
{
        resolve_type(type.base_type, type.base, false);
        stage->types.insert(make_pair(type.name, &type));
}

void TypeResolver::visit(StructDeclaration &strct)
{
        stage->types.insert(make_pair(strct.name, &strct));
        TraversingVisitor::visit(strct);
}

void TypeResolver::visit(VariableDeclaration &var)
{
        resolve_type(var.type_declaration, var.type, var.array);
        if(iface_block && var.interface==iface_block->interface)
                var.interface.clear();
}

void TypeResolver::visit(InterfaceBlock &iface)
{
        if(iface.members)
        {
                SetForScope<InterfaceBlock *> set_iface(iface_block, &iface);
                iface.members->visit(*this);

                StructDeclaration *strct = new StructDeclaration;
                strct->source = INTERNAL_SOURCE;
                strct->name = format("_%s_%s", iface.interface, iface.name);
                strct->members.body.splice(strct->members.body.begin(), iface.members->body);
                stage->content.body.insert(type_insert_point, strct);
                stage->types.insert(make_pair(strct->name, strct));

                iface.members = 0;
                strct->interface_block = &iface;
                iface.struct_declaration = strct;
        }

        TypeDeclaration *type = iface.struct_declaration;
        if(type && iface.array)
                type = get_or_create_array_type(*type);
        r_any_resolved = (type!=iface.type_declaration);
        iface.type_declaration = type;
}

void TypeResolver::visit(FunctionDeclaration &func)
{
        resolve_type(func.return_type_declaration, func.return_type, false);
        TraversingVisitor::visit(func);
}


VariableResolver::VariableResolver():
        stage(0),
        r_any_resolved(false),
        record_target(false),
        r_self_referencing(false)
{ }

bool VariableResolver::apply(Stage &s)
{
        stage = &s;
        s.interface_blocks.clear();
        r_any_resolved = false;
        s.content.visit(*this);
        for(vector<VariableDeclaration *>::const_iterator i=redeclared_builtins.begin(); i!=redeclared_builtins.end(); ++i)
                (*i)->source = GENERATED_SOURCE;
        NodeRemover().apply(s, nodes_to_remove);
        return r_any_resolved;
}

void VariableResolver::enter(Block &block)
{
        block.variables.clear();
}

void VariableResolver::visit(RefPtr<Expression> &expr)
{
        r_replacement_expr = 0;
        expr->visit(*this);
        if(r_replacement_expr)
        {
                expr = r_replacement_expr;
                /* Don't record assignment target when doing a replacement, because chain
                information won't be correct. */
                r_assignment_target.declaration = 0;
                r_any_resolved = true;
        }
        r_replacement_expr = 0;
}

void VariableResolver::check_assignment_target(Statement *declaration)
{
        if(record_target)
        {
                if(r_assignment_target.declaration)
                {
                        /* More than one reference found in assignment target.  Unable to
                        determine what the primary target is. */
                        record_target = false;
                        r_assignment_target.declaration = 0;
                }
                else
                        r_assignment_target.declaration = declaration;
        }
        // TODO This check is overly broad and may prevent some optimizations.
        else if(declaration && declaration==r_assignment_target.declaration)
                r_self_referencing = true;
}

void VariableResolver::visit(VariableReference &var)
{
        VariableDeclaration *declaration = 0;

        /* Look for variable declarations in the block hierarchy first.  Interface
        blocks are always defined in the top level so we can't accidentally skip
        one. */
        for(Block *block=current_block; (!declaration && block); block=block->parent)
        {
                map<string, VariableDeclaration *>::iterator i = block->variables.find(var.name);
                if(i!=block->variables.end())
                        declaration = i->second;
        }

        if(!declaration)
        {
                const map<string, InterfaceBlock *> &blocks = stage->interface_blocks;
                map<string, InterfaceBlock *>::const_iterator i = blocks.find("_"+var.name);
                if(i!=blocks.end())
                {
                        /* The name refers to an interface block with an instance name rather
                        than a variable.  Prepare a new syntax tree node accordingly. */
                        InterfaceBlockReference *iface_ref = new InterfaceBlockReference;
                        iface_ref->source = var.source;
                        iface_ref->line = var.line;
                        iface_ref->name = var.name;
                        iface_ref->declaration = i->second;
                        r_replacement_expr = iface_ref;
                }
                else
                {
                        // Look for the variable in anonymous interface blocks.
                        for(i=blocks.begin(); (!declaration && i!=blocks.end()); ++i)
                                if(i->second->instance_name.empty() && i->second->struct_declaration)
                                {
                                        const map<string, VariableDeclaration *> &iface_vars = i->second->struct_declaration->members.variables;
                                        map<string, VariableDeclaration *>::const_iterator j = iface_vars.find(var.name);
                                        if(j!=iface_vars.end())
                                                declaration = j->second;
                                }
                }
        }

        r_any_resolved |= (declaration!=var.declaration);
        var.declaration = declaration;

        check_assignment_target(var.declaration);
}

void VariableResolver::visit(InterfaceBlockReference &iface)
{
        map<string, InterfaceBlock *>::iterator i = stage->interface_blocks.find("_"+iface.name);
        InterfaceBlock *declaration = (i!=stage->interface_blocks.end() ? i->second : 0);
        r_any_resolved |= (declaration!=iface.declaration);
        iface.declaration = declaration;

        check_assignment_target(iface.declaration);
}

void VariableResolver::add_to_chain(Assignment::Target::ChainType type, unsigned index)
{
        if(r_assignment_target.chain_len<7)
                r_assignment_target.chain[r_assignment_target.chain_len] = type | min<unsigned>(index, 0x3F);
        ++r_assignment_target.chain_len;
}

void VariableResolver::visit(MemberAccess &memacc)
{
        TraversingVisitor::visit(memacc);

        VariableDeclaration *declaration = 0;
        if(StructDeclaration *strct = dynamic_cast<StructDeclaration *>(memacc.left->type))
        {
                map<string, VariableDeclaration *>::iterator i = strct->members.variables.find(memacc.member);
                if(i!=strct->members.variables.end())
                {
                        declaration = i->second;

                        if(record_target)
                        {
                                unsigned index = 0;
                                for(NodeList<Statement>::const_iterator j=strct->members.body.begin(); (j!=strct->members.body.end() && j->get()!=i->second); ++j)
                                        ++index;

                                add_to_chain(Assignment::Target::MEMBER, index);
                        }
                }
        }
        else if(BasicTypeDeclaration *basic = dynamic_cast<BasicTypeDeclaration *>(memacc.left->type))
        {
                bool scalar_swizzle = ((basic->kind==BasicTypeDeclaration::INT || basic->kind==BasicTypeDeclaration::FLOAT) && memacc.member.size()==1);
                bool vector_swizzle = (basic->kind==BasicTypeDeclaration::VECTOR && memacc.member.size()<=4);
                if(scalar_swizzle || vector_swizzle)
                {
                        static const char component_names[] = { 'x', 'r', 's', 'y', 'g', 't', 'z', 'b', 'p', 'w', 'a', 'q' };

                        bool ok = true;
                        UInt8 components[4] = { };
                        for(unsigned i=0; (ok && i<memacc.member.size()); ++i)
                                ok = ((components[i] = (find(component_names, component_names+12, memacc.member[i])-component_names)/3) < 4);

                        if(ok)
                        {
                                Swizzle *swizzle = new Swizzle;
                                swizzle->source = memacc.source;
                                swizzle->line = memacc.line;
                                swizzle->oper = memacc.oper;
                                swizzle->left = memacc.left;
                                swizzle->component_group = memacc.member;
                                swizzle->count = memacc.member.size();
                                copy(components, components+memacc.member.size(), swizzle->components);
                                r_replacement_expr = swizzle;
                        }
                }
        }

        r_any_resolved |= (declaration!=memacc.declaration);
        memacc.declaration = declaration;
}

void VariableResolver::visit(Swizzle &swizzle)
{
        TraversingVisitor::visit(swizzle);

        if(record_target)
        {
                unsigned mask = 0;
                for(unsigned i=0; i<swizzle.count; ++i)
                        mask |= 1<<swizzle.components[i];
                add_to_chain(Assignment::Target::SWIZZLE, mask);
        }
}

void VariableResolver::visit(BinaryExpression &binary)
{
        if(binary.oper->token[0]=='[')
        {
                {
                        /* The subscript expression is not a part of the primary assignment
                        target. */
                        SetFlag set(record_target, false);
                        visit(binary.right);
                }
                visit(binary.left);

                if(record_target)
                {
                        unsigned index = 0x3F;
                        if(Literal *literal_subscript = dynamic_cast<Literal *>(binary.right.get()))
                                if(literal_subscript->value.check_type<int>())
                                        index = literal_subscript->value.value<int>();
                        add_to_chain(Assignment::Target::ARRAY, index);
                }
        }
        else
                TraversingVisitor::visit(binary);
}

void VariableResolver::visit(Assignment &assign)
{
        {
                SetFlag set(record_target);
                r_assignment_target = Assignment::Target();
                visit(assign.left);
                r_any_resolved |= (r_assignment_target<assign.target || assign.target<r_assignment_target);
                assign.target = r_assignment_target;
        }

        r_self_referencing = false;
        visit(assign.right);
        assign.self_referencing = (r_self_referencing || assign.oper->token[0]!='=');
}

void VariableResolver::merge_layouts(Layout &to_layout, const Layout &from_layout)
{
        for(vector<Layout::Qualifier>::const_iterator i=from_layout.qualifiers.begin(); i!=from_layout.qualifiers.end(); ++i)
        {
                bool found = false;
                for(vector<Layout::Qualifier>::iterator j=to_layout.qualifiers.begin(); (!found && j!=to_layout.qualifiers.end()); ++j)
                        if(j->name==i->name)
                        {
                                j->has_value = i->value;
                                j->value = i->value;
                                found = true;
                        }

                if(!found)
                        to_layout.qualifiers.push_back(*i);
        }
}

void VariableResolver::visit(VariableDeclaration &var)
{
        TraversingVisitor::visit(var);
        VariableDeclaration *&ptr = current_block->variables[var.name];
        if(!ptr)
                ptr = &var;
        else if(!current_block->parent && ptr->interface==var.interface && ptr->type==var.type)
        {
                if(ptr->source==BUILTIN_SOURCE)
                        redeclared_builtins.push_back(&var);
                else
                        stage->diagnostics.push_back(Diagnostic(Diagnostic::WARN, var.source, var.line,
                                format("Redeclaring non-builtin variable '%s' is deprecated", var.name)));

                if(var.init_expression)
                        ptr->init_expression = var.init_expression;
                if(var.layout)
                {
                        if(ptr->layout)
                                merge_layouts(*ptr->layout, *var.layout);
                        else
                                ptr->layout = var.layout;
                }
                nodes_to_remove.insert(&var);

                r_any_resolved = true;
        }
}

void VariableResolver::visit(InterfaceBlock &iface)
{
        /* Block names can be reused in different interfaces.  Prefix the name with
        the first character of the interface to avoid conflicts. */
        stage->interface_blocks.insert(make_pair(iface.interface+iface.name, &iface));
        if(!iface.instance_name.empty())
                stage->interface_blocks.insert(make_pair("_"+iface.instance_name, &iface));

        TraversingVisitor::visit(iface);
}


ExpressionResolver::ExpressionResolver():
        stage(0),
        r_any_resolved(false)
{ }

bool ExpressionResolver::apply(Stage &s)
{
        stage = &s;
        r_any_resolved = false;
        s.content.visit(*this);
        return r_any_resolved;
}

bool ExpressionResolver::is_scalar(BasicTypeDeclaration &type)
{
        return (type.kind==BasicTypeDeclaration::INT || type.kind==BasicTypeDeclaration::FLOAT);
}

bool ExpressionResolver::is_vector_or_matrix(BasicTypeDeclaration &type)
{
        return (type.kind==BasicTypeDeclaration::VECTOR || type.kind==BasicTypeDeclaration::MATRIX);
}

BasicTypeDeclaration *ExpressionResolver::get_element_type(BasicTypeDeclaration &type)
{
        if(is_vector_or_matrix(type) || type.kind==BasicTypeDeclaration::ARRAY)
        {
                BasicTypeDeclaration *basic_base = dynamic_cast<BasicTypeDeclaration *>(type.base_type);
                return (basic_base ? get_element_type(*basic_base) : 0);
        }
        else
                return &type;
}

bool ExpressionResolver::can_convert(BasicTypeDeclaration &from, BasicTypeDeclaration &to)
{
        if(from.kind==BasicTypeDeclaration::INT && to.kind==BasicTypeDeclaration::FLOAT)
                return from.size<=to.size;
        else if(from.kind!=to.kind)
                return false;
        else if((from.kind==BasicTypeDeclaration::VECTOR || from.kind==BasicTypeDeclaration::MATRIX) && from.size==to.size)
        {
                BasicTypeDeclaration *from_base = dynamic_cast<BasicTypeDeclaration *>(from.base_type);
                BasicTypeDeclaration *to_base = dynamic_cast<BasicTypeDeclaration *>(to.base_type);
                return (from_base && to_base && can_convert(*from_base, *to_base));
        }
        else
                return false;
}

ExpressionResolver::Compatibility ExpressionResolver::get_compatibility(BasicTypeDeclaration &left, BasicTypeDeclaration &right)
{
        if(&left==&right)
                return SAME_TYPE;
        else if(can_convert(left, right))
                return LEFT_CONVERTIBLE;
        else if(can_convert(right, left))
                return RIGHT_CONVERTIBLE;
        else
                return NOT_COMPATIBLE;
}

BasicTypeDeclaration *ExpressionResolver::find_type(BasicTypeDeclaration::Kind kind, unsigned size)
{
        for(vector<BasicTypeDeclaration *>::const_iterator i=basic_types.begin(); i!=basic_types.end(); ++i)
                if((*i)->kind==kind && (*i)->size==size)
                        return *i;
        return 0;
}

BasicTypeDeclaration *ExpressionResolver::find_type(BasicTypeDeclaration &elem_type, BasicTypeDeclaration::Kind kind, unsigned size)
{
        for(vector<BasicTypeDeclaration *>::const_iterator i=basic_types.begin(); i!=basic_types.end(); ++i)
                if(get_element_type(**i)==&elem_type && (*i)->kind==kind && (*i)->size==size)
                        return *i;
        return 0;
}

void ExpressionResolver::convert_to(RefPtr<Expression> &expr, BasicTypeDeclaration &type)
{
        RefPtr<FunctionCall> call = new FunctionCall;
        call->name = type.name;
        call->constructor = true;
        call->arguments.push_back(0);
        call->arguments.back() = expr;
        call->type = &type;
        expr = call;
}

bool ExpressionResolver::convert_to_element(RefPtr<Expression> &expr, BasicTypeDeclaration &elem_type)
{
        if(BasicTypeDeclaration *expr_basic = dynamic_cast<BasicTypeDeclaration *>(expr->type))
        {
                BasicTypeDeclaration *to_type = &elem_type;
                if(is_vector_or_matrix(*expr_basic))
                        to_type = find_type(elem_type, expr_basic->kind, expr_basic->size);
                if(to_type)
                {
                        convert_to(expr, *to_type);
                        return true;
                }
        }

        return false;
}

bool ExpressionResolver::truncate_vector(RefPtr<Expression> &expr, unsigned size)
{
        if(BasicTypeDeclaration *expr_basic = dynamic_cast<BasicTypeDeclaration *>(expr->type))
                if(BasicTypeDeclaration *expr_elem = get_element_type(*expr_basic))
                {
                        RefPtr<Swizzle> swizzle = new Swizzle;
                        swizzle->left = expr;
                        swizzle->oper = &Operator::get_operator(".", Operator::POSTFIX);
                        swizzle->component_group = string("xyzw", size);
                        swizzle->count = size;
                        for(unsigned i=0; i<size; ++i)
                                swizzle->components[i] = i;
                        if(size==1)
                                swizzle->type = expr_elem;
                        else
                                swizzle->type = find_type(*expr_elem, BasicTypeDeclaration::VECTOR, size);
                        expr = swizzle;

                        return true;
                }

        return false;
}

void ExpressionResolver::resolve(Expression &expr, TypeDeclaration *type, bool lvalue)
{
        r_any_resolved |= (type!=expr.type || lvalue!=expr.lvalue);
        expr.type = type;
        expr.lvalue = lvalue;
}

void ExpressionResolver::visit(Block &block)
{
        SetForScope<Block *> set_block(current_block, &block);
        for(NodeList<Statement>::iterator i=block.body.begin(); i!=block.body.end(); ++i)
        {
                insert_point = i;
                (*i)->visit(*this);
        }
}

void ExpressionResolver::visit(Literal &literal)
{
        if(literal.value.check_type<bool>())
                resolve(literal, find_type(BasicTypeDeclaration::BOOL, 1), false);
        else if(literal.value.check_type<int>())
                resolve(literal, find_type(BasicTypeDeclaration::INT, 32), false);
        else if(literal.value.check_type<float>())
                resolve(literal, find_type(BasicTypeDeclaration::FLOAT, 32), false);
}

void ExpressionResolver::visit(VariableReference &var)
{
        if(var.declaration)
                resolve(var, var.declaration->type_declaration, true);
}

void ExpressionResolver::visit(InterfaceBlockReference &iface)
{
        if(iface.declaration)
                resolve(iface, iface.declaration->type_declaration, true);
}

void ExpressionResolver::visit(MemberAccess &memacc)
{
        TraversingVisitor::visit(memacc);

        if(memacc.declaration)
                resolve(memacc, memacc.declaration->type_declaration, memacc.left->lvalue);
}

void ExpressionResolver::visit(Swizzle &swizzle)
{
        TraversingVisitor::visit(swizzle);

        if(BasicTypeDeclaration *left_basic = dynamic_cast<BasicTypeDeclaration *>(swizzle.left->type))
        {
                BasicTypeDeclaration *left_elem = get_element_type(*left_basic);
                if(swizzle.count==1)
                        resolve(swizzle, left_elem, swizzle.left->lvalue);
                else if(left_basic->kind==BasicTypeDeclaration::VECTOR && left_elem)
                        resolve(swizzle, find_type(*left_elem, left_basic->kind, swizzle.count), swizzle.left->lvalue);
        }
}

void ExpressionResolver::visit(UnaryExpression &unary)
{
        TraversingVisitor::visit(unary);

        BasicTypeDeclaration *basic = dynamic_cast<BasicTypeDeclaration *>(unary.expression->type);
        if(!basic)
                return;

        char oper = unary.oper->token[0];
        if(oper=='!')
        {
                if(basic->kind!=BasicTypeDeclaration::BOOL)
                        return;
        }
        else if(oper=='~')
        {
                if(basic->kind!=BasicTypeDeclaration::INT)
                        return;
        }
        else if(oper=='+' || oper=='-')
        {
                BasicTypeDeclaration *elem = get_element_type(*basic);
                if(!elem || !is_scalar(*elem))
                        return;
        }
        resolve(unary, basic, unary.expression->lvalue);
}

void ExpressionResolver::visit(BinaryExpression &binary, bool assign)
{
        /* Binary operators are only defined for basic types (not for image or
        structure types). */
        BasicTypeDeclaration *basic_left = dynamic_cast<BasicTypeDeclaration *>(binary.left->type);
        BasicTypeDeclaration *basic_right = dynamic_cast<BasicTypeDeclaration *>(binary.right->type);
        if(!basic_left || !basic_right)
                return;

        char oper = binary.oper->token[0];
        if(oper=='[')
        {
                /* Subscripting operates on vectors, matrices and arrays, and the right
                operand must be an integer. */
                if((!is_vector_or_matrix(*basic_left) && basic_left->kind!=BasicTypeDeclaration::ARRAY) || basic_right->kind!=BasicTypeDeclaration::INT)
                        return;

                resolve(binary, basic_left->base_type, binary.left->lvalue);
                return;
        }
        else if(basic_left->kind==BasicTypeDeclaration::ARRAY || basic_right->kind==BasicTypeDeclaration::ARRAY)
                // No other binary operator can be used with arrays.
                return;

        BasicTypeDeclaration *elem_left = get_element_type(*basic_left);
        BasicTypeDeclaration *elem_right = get_element_type(*basic_right);
        if(!elem_left || !elem_right)
                return;

        Compatibility compat = get_compatibility(*basic_left, *basic_right);
        Compatibility elem_compat = get_compatibility(*elem_left, *elem_right);
        if(elem_compat==NOT_COMPATIBLE)
                return;
        if(assign && (compat==LEFT_CONVERTIBLE || elem_compat==LEFT_CONVERTIBLE))
                return;

        TypeDeclaration *type = 0;
        char oper2 = binary.oper->token[1];
        if((oper=='<' && oper2!='<') || (oper=='>' && oper2!='>'))
        {
                /* Relational operators compare two scalar integer or floating-point
                values. */
                if(!is_scalar(*elem_left) || !is_scalar(*elem_right) || compat==NOT_COMPATIBLE)
                        return;

                type = find_type(BasicTypeDeclaration::BOOL, 1);
        }
        else if((oper=='=' || oper=='!') && oper2=='=')
        {
                // Equality comparison can be done on any compatible types.
                if(compat==NOT_COMPATIBLE)
                        return;

                type = find_type(BasicTypeDeclaration::BOOL, 1);
        }
        else if(oper2=='&' || oper2=='|' || oper2=='^')
        {
                // Logical operators can only be applied to booleans.
                if(basic_left->kind!=BasicTypeDeclaration::BOOL || basic_right->kind!=BasicTypeDeclaration::BOOL)
                        return;

                type = basic_left;
        }
        else if((oper=='&' || oper=='|' || oper=='^' || oper=='%') && !oper2)
        {
                // Bitwise operators and modulo can only be applied to integers.
                if(basic_left->kind!=BasicTypeDeclaration::INT || basic_right->kind!=BasicTypeDeclaration::INT)
                        return;

                type = (compat==LEFT_CONVERTIBLE ? basic_right : basic_left);
        }
        else if((oper=='<' || oper=='>') && oper2==oper)
        {
                // Shifts apply to integer scalars and vectors, with some restrictions.
                if(elem_left->kind!=BasicTypeDeclaration::INT || elem_right->kind!=BasicTypeDeclaration::INT)
                        return;
                unsigned left_size = (basic_left->kind==BasicTypeDeclaration::INT ? 1 : basic_left->kind==BasicTypeDeclaration::VECTOR ? basic_left->size : 0);
                unsigned right_size = (basic_right->kind==BasicTypeDeclaration::INT ? 1 : basic_right->kind==BasicTypeDeclaration::VECTOR ? basic_right->size : 0);
                if(!left_size || (left_size==1 && right_size!=1) || (left_size>1 && right_size!=1 && right_size!=left_size))
                        return;

                type = basic_left;
                // Don't perform conversion even if the operands are of different sizes.
                compat = SAME_TYPE;
        }
        else if(oper=='+' || oper=='-' || oper=='*' || oper=='/')
        {
                // Arithmetic operators require scalar elements.
                if(!is_scalar(*elem_left) || !is_scalar(*elem_right))
                        return;

                if(oper=='*' && is_vector_or_matrix(*basic_left) && is_vector_or_matrix(*basic_right) &&
                        (basic_left->kind==BasicTypeDeclaration::MATRIX || basic_right->kind==BasicTypeDeclaration::MATRIX))
                {
                        /* Multiplication has special rules when at least one operand is a
                        matrix and the other is a vector or a matrix. */
                        unsigned left_columns = basic_left->size&0xFFFF;
                        unsigned right_rows = basic_right->size;
                        if(basic_right->kind==BasicTypeDeclaration::MATRIX)
                                right_rows >>= 16;
                        if(left_columns!=right_rows)
                                return;

                        BasicTypeDeclaration *elem_result = (elem_compat==LEFT_CONVERTIBLE ? elem_right : elem_left);

                        if(basic_left->kind==BasicTypeDeclaration::VECTOR)
                                type = find_type(*elem_result, BasicTypeDeclaration::VECTOR, basic_right->size&0xFFFF);
                        else if(basic_right->kind==BasicTypeDeclaration::VECTOR)
                                type = find_type(*elem_result, BasicTypeDeclaration::VECTOR, basic_left->size>>16);
                        else
                                type = find_type(*elem_result, BasicTypeDeclaration::MATRIX, (basic_left->size&0xFFFF0000)|(basic_right->size&0xFFFF));
                }
                else if(compat==NOT_COMPATIBLE)
                {
                        // Arithmetic between scalars and matrices or vectors is supported.
                        if(is_scalar(*basic_left) && is_vector_or_matrix(*basic_right))
                                type = (elem_compat==RIGHT_CONVERTIBLE ? find_type(*elem_left, basic_right->kind, basic_right->size) : basic_right);
                        else if(is_vector_or_matrix(*basic_left) && is_scalar(*basic_right))
                                type = (elem_compat==LEFT_CONVERTIBLE ? find_type(*elem_right, basic_left->kind, basic_left->size) : basic_left);
                        else
                                return;
                }
                else if(compat==LEFT_CONVERTIBLE)
                        type = basic_right;
                else
                        type = basic_left;
        }
        else
                return;

        if(assign && type!=basic_left)
                return;

        bool converted = true;
        if(compat==LEFT_CONVERTIBLE)
                convert_to(binary.left, *basic_right);
        else if(compat==RIGHT_CONVERTIBLE)
                convert_to(binary.right, *basic_left);
        else if(elem_compat==LEFT_CONVERTIBLE)
                converted = convert_to_element(binary.left, *elem_right);
        else if(elem_compat==RIGHT_CONVERTIBLE)
                converted = convert_to_element(binary.right, *elem_left);

        if(!converted)
                type = 0;

        resolve(binary, type, assign);
}

void ExpressionResolver::visit(BinaryExpression &binary)
{
        TraversingVisitor::visit(binary);
        visit(binary, false);
}

void ExpressionResolver::visit(Assignment &assign)
{
        TraversingVisitor::visit(assign);

        if(assign.oper->token[0]!='=')
                return visit(assign, true);
        else if(assign.left->type!=assign.right->type)
        {
                BasicTypeDeclaration *basic_left = dynamic_cast<BasicTypeDeclaration *>(assign.left->type);
                BasicTypeDeclaration *basic_right = dynamic_cast<BasicTypeDeclaration *>(assign.right->type);
                if(!basic_left || !basic_right)
                        return;

                Compatibility compat = get_compatibility(*basic_left, *basic_right);
                if(compat==RIGHT_CONVERTIBLE)
                        convert_to(assign.right, *basic_left);
                else if(compat!=SAME_TYPE)
                        return;
        }

        resolve(assign, assign.left->type, true);
}

void ExpressionResolver::visit(TernaryExpression &ternary)
{
        TraversingVisitor::visit(ternary);

        BasicTypeDeclaration *basic_cond = dynamic_cast<BasicTypeDeclaration *>(ternary.condition->type);
        if(!basic_cond || basic_cond->kind!=BasicTypeDeclaration::BOOL)
                return;

        TypeDeclaration *type = 0;
        if(ternary.true_expr->type==ternary.false_expr->type)
                type = ternary.true_expr->type;
        else
        {
                BasicTypeDeclaration *basic_true = dynamic_cast<BasicTypeDeclaration *>(ternary.true_expr->type);
                BasicTypeDeclaration *basic_false = dynamic_cast<BasicTypeDeclaration *>(ternary.false_expr->type);
                Compatibility compat = get_compatibility(*basic_true, *basic_false);
                if(compat==NOT_COMPATIBLE)
                        return;

                type = (compat==LEFT_CONVERTIBLE ? basic_true : basic_false);

                if(compat==LEFT_CONVERTIBLE)
                        convert_to(ternary.true_expr, *basic_false);
                else if(compat==RIGHT_CONVERTIBLE)
                        convert_to(ternary.false_expr, *basic_true);
        }

        resolve(ternary, type, false);
}

void ExpressionResolver::visit_constructor(FunctionCall &call)
{
        if(call.arguments.empty())
                return;

        map<string, TypeDeclaration *>::const_iterator i = stage->types.find(call.name);
        if(i==stage->types.end())
                return;
        else if(BasicTypeDeclaration *basic = dynamic_cast<BasicTypeDeclaration *>(i->second))
        {
                BasicTypeDeclaration *elem = get_element_type(*basic);
                if(!elem)
                        return;

                vector<ArgumentInfo> args;
                args.reserve(call.arguments.size());
                unsigned arg_component_total = 0;
                bool has_matrices = false;
                for(NodeArray<Expression>::const_iterator j=call.arguments.begin(); j!=call.arguments.end(); ++j)
                {
                        ArgumentInfo info;
                        if(!(info.type=dynamic_cast<BasicTypeDeclaration *>((*j)->type)))
                                return;
                        if(is_scalar(*info.type) || info.type->kind==BasicTypeDeclaration::BOOL)
                                info.component_count = 1;
                        else if(info.type->kind==BasicTypeDeclaration::VECTOR)
                                info.component_count = info.type->size;
                        else if(info.type->kind==BasicTypeDeclaration::MATRIX)
                        {
                                info.component_count = (info.type->size>>16)*(info.type->size&0xFFFF);
                                has_matrices = true;
                        }
                        else
                                return;
                        arg_component_total += info.component_count;
                        args.push_back(info);
                }

                bool convert_args = false;
                if((is_scalar(*basic) || basic->kind==BasicTypeDeclaration::BOOL) && call.arguments.size()==1 && !has_matrices)
                {
                        if(arg_component_total>1)
                                truncate_vector(call.arguments.front(), 1);

                        /* Single-element type constructors never need to convert their
                        arguments because the constructor *is* the conversion. */
                }
                else if(basic->kind==BasicTypeDeclaration::VECTOR && !has_matrices)
                {
                        /* Vector constructors need either a single scalar argument or
                        enough components to fill out the vector. */
                        if(arg_component_total!=1 && arg_component_total<basic->size)
                                return;

                        /* A vector of same size can be converted directly.  For other
                        combinations the individual arguments need to be converted. */
                        if(call.arguments.size()==1)
                        {
                                if(arg_component_total==1)
                                        convert_args = true;
                                else if(arg_component_total>basic->size)
                                        truncate_vector(call.arguments.front(), basic->size);
                        }
                        else if(arg_component_total==basic->size)
                                convert_args = true;
                        else
                                return;
                }
                else if(basic->kind==BasicTypeDeclaration::MATRIX)
                {
                        unsigned column_count = basic->size&0xFFFF;
                        unsigned row_count = basic->size>>16;
                        if(call.arguments.size()==1)
                        {
                                /* A matrix can be constructed from a single element or another
                                matrix of sufficient size. */
                                if(arg_component_total==1)
                                        convert_args = true;
                                else if(args.front().type->kind==BasicTypeDeclaration::MATRIX)
                                {
                                        unsigned arg_columns = args.front().type->size&0xFFFF;
                                        unsigned arg_rows = args.front().type->size>>16;
                                        if(arg_columns<column_count || arg_rows<row_count)
                                                return;

                                        /* Always generate a temporary here and let the optimization
                                        stage inline it if that's reasonable. */
                                        RefPtr<VariableDeclaration> temporary = new VariableDeclaration;
                                        temporary->type = args.front().type->name;
                                        temporary->name = get_unused_variable_name(*current_block, "_temp", string());
                                        temporary->init_expression = call.arguments.front();
                                        current_block->body.insert(insert_point, temporary);

                                        // Create expressions to build each column.
                                        vector<RefPtr<Expression> > columns;
                                        columns.reserve(column_count);
                                        for(unsigned j=0; j<column_count; ++j)
                                        {
                                                RefPtr<VariableReference> ref = new VariableReference;
                                                ref->name = temporary->name;

                                                RefPtr<Literal> index = new Literal;
                                                index->token = lexical_cast<string>(j);
                                                index->value = static_cast<int>(j);

                                                RefPtr<BinaryExpression> subscript = new BinaryExpression;
                                                subscript->left = ref;
                                                subscript->oper = &Operator::get_operator("[", Operator::BINARY);
                                                subscript->right = index;
                                                subscript->type = args.front().type->base_type;

                                                columns.push_back(subscript);
                                                if(arg_rows>row_count)
                                                        truncate_vector(columns.back(), row_count);
                                        }

                                        call.arguments.resize(column_count);
                                        copy(columns.begin(), columns.end(), call.arguments.begin());

                                        /* Let VariableResolver process the new nodes and finish
                                        resolving the constructor on the next pass. */
                                        r_any_resolved = true;
                                        return;
                                }
                                else
                                        return;
                        }
                        else if(arg_component_total==column_count*row_count && !has_matrices)
                        {
                                /* Construct a matrix from individual components in column-major
                                order.  Arguments must align at column boundaries. */
                                vector<RefPtr<Expression> > columns;
                                columns.reserve(column_count);

                                vector<RefPtr<Expression> > column_args;
                                column_args.reserve(row_count);
                                unsigned column_component_count = 0;

                                for(unsigned j=0; j<call.arguments.size(); ++j)
                                {
                                        const ArgumentInfo &info = args[j];
                                        if(!column_component_count && info.type->kind==BasicTypeDeclaration::VECTOR && info.component_count==row_count)
                                                // A vector filling the entire column can be used as is.
                                                columns.push_back(call.arguments[j]);
                                        else
                                        {
                                                column_args.push_back(call.arguments[j]);
                                                column_component_count += info.component_count;
                                                if(column_component_count==row_count)
                                                {
                                                        /* The column has filled up.  Create a vector constructor
                                                        for it.*/
                                                        RefPtr<FunctionCall> column_call = new FunctionCall;
                                                        column_call->name = basic->base_type->name;
                                                        column_call->constructor = true;
                                                        column_call->arguments.resize(column_args.size());
                                                        copy(column_args.begin(), column_args.end(), column_call->arguments.begin());
                                                        column_call->type = basic->base_type;
                                                        visit_constructor(*column_call);
                                                        columns.push_back(column_call);

                                                        column_args.clear();
                                                        column_component_count = 0;
                                                }
                                                else if(column_component_count>row_count)
                                                        // Argument alignment mismatch.
                                                        return;
                                        }
                                }
                        }
                        else
                                return;
                }
                else
                        return;

                if(convert_args)
                {
                        // The argument list may have changed so can't rely on args.
                        for(NodeArray<Expression>::iterator j=call.arguments.begin(); j!=call.arguments.end(); ++j)
                                if(BasicTypeDeclaration *basic_arg = dynamic_cast<BasicTypeDeclaration *>((*j)->type))
                                {
                                        BasicTypeDeclaration *elem_arg = get_element_type(*basic_arg);
                                        if(elem_arg!=elem)
                                                convert_to_element(*j, *elem);
                                }
                }
        }
        else if(StructDeclaration *strct = dynamic_cast<StructDeclaration *>(i->second))
        {
                if(call.arguments.size()!=strct->members.body.size())
                        return;

                unsigned k = 0;
                for(NodeList<Statement>::const_iterator j=strct->members.body.begin(); j!=strct->members.body.end(); ++j, ++k)
                {
                        if(VariableDeclaration *var = dynamic_cast<VariableDeclaration *>(j->get()))
                        {
                                if(!call.arguments[k]->type || call.arguments[k]->type!=var->type_declaration)
                                        return;
                        }
                        else
                                return;
                }
        }

        resolve(call, i->second, false);
}

void ExpressionResolver::visit(FunctionCall &call)
{
        TraversingVisitor::visit(call);

        if(call.declaration)
                resolve(call, call.declaration->return_type_declaration, false);
        else if(call.constructor)
                visit_constructor(call);
}

void ExpressionResolver::visit(BasicTypeDeclaration &type)
{
        basic_types.push_back(&type);
}

void ExpressionResolver::visit(VariableDeclaration &var)
{
        TraversingVisitor::visit(var);
        if(!var.init_expression)
                return;

        BasicTypeDeclaration *var_basic = dynamic_cast<BasicTypeDeclaration *>(var.type_declaration);
        BasicTypeDeclaration *init_basic = dynamic_cast<BasicTypeDeclaration *>(var.init_expression->type);
        if(!var_basic || !init_basic)
                return;

        Compatibility compat = get_compatibility(*var_basic, *init_basic);
        if(compat==RIGHT_CONVERTIBLE)
                convert_to(var.init_expression, *var_basic);
}


bool FunctionResolver::apply(Stage &s)
{
        stage = &s;
        s.functions.clear();
        r_any_resolved = false;
        s.content.visit(*this);
        return r_any_resolved;
}

void FunctionResolver::visit(FunctionCall &call)
{
        FunctionDeclaration *declaration = 0;
        if(stage->types.count(call.name))
                call.constructor = true;
        else
        {
                string arg_types;
                bool has_signature = true;
                for(NodeArray<Expression>::const_iterator i=call.arguments.begin(); (has_signature && i!=call.arguments.end()); ++i)
                {
                        if((*i)->type)
                                append(arg_types, ",", (*i)->type->name);
                        else
                                has_signature = false;
                }

                if(has_signature)
                {
                        map<string, FunctionDeclaration *>::iterator i = stage->functions.find(format("%s(%s)", call.name, arg_types));
                        declaration = (i!=stage->functions.end() ? i->second : 0);
                }
        }

        r_any_resolved |= (declaration!=call.declaration);
        call.declaration = declaration;

        TraversingVisitor::visit(call);
}

void FunctionResolver::visit(FunctionDeclaration &func)
{
        if(func.signature.empty())
        {
                string param_types;
                for(NodeArray<VariableDeclaration>::const_iterator i=func.parameters.begin(); i!=func.parameters.end(); ++i)
                {
                        if((*i)->type_declaration)
                                append(param_types, ",", (*i)->type_declaration->name);
                        else
                                return;
                }
                func.signature = format("(%s)", param_types);
                r_any_resolved = true;
        }

        string key = func.name+func.signature;
        FunctionDeclaration *&stage_decl = stage->functions[key];
        vector<FunctionDeclaration *> &decls = declarations[key];
        if(func.definition==&func)
        {
                if(stage_decl && stage_decl->definition)
                {
                        if(!func.overrd)
                                stage->diagnostics.push_back(Diagnostic(Diagnostic::WARN, func.source, func.line,
                                        format("Overriding function '%s' without the override keyword is deprecated", key)));
                        if(!stage_decl->definition->virtua)
                                stage->diagnostics.push_back(Diagnostic(Diagnostic::WARN, func.source, func.line,
                                        format("Overriding function '%s' not declared as virtual is deprecated", key)));
                }
                stage_decl = &func;

                // Set all previous declarations to use this definition.
                for(vector<FunctionDeclaration *>::iterator i=decls.begin(); i!=decls.end(); ++i)
                {
                        r_any_resolved |= (func.definition!=(*i)->definition);
                        (*i)->definition = func.definition;
                        (*i)->body.body.clear();
                }
        }
        else
        {
                FunctionDeclaration *definition = (stage_decl ? stage_decl->definition : 0);
                r_any_resolved |= (definition!=func.definition);
                func.definition = definition;

                if(!stage_decl)
                        stage_decl = &func;
        }
        decls.push_back(&func);

        TraversingVisitor::visit(func);
}


InterfaceGenerator::InterfaceGenerator():
        stage(0),
        function_scope(false),
        copy_block(false),
        iface_target_block(0)
{ }

string InterfaceGenerator::get_out_prefix(Stage::Type type)
{
        if(type==Stage::VERTEX)
                return "_vs_out_";
        else if(type==Stage::GEOMETRY)
                return "_gs_out_";
        else
                return string();
}

void InterfaceGenerator::apply(Stage &s)
{
        stage = &s;
        iface_target_block = &stage->content;
        if(stage->previous)
                in_prefix = get_out_prefix(stage->previous->type);
        out_prefix = get_out_prefix(stage->type);
        s.content.visit(*this);
        NodeRemover().apply(s, nodes_to_remove);
}

void InterfaceGenerator::visit(Block &block)
{
        SetForScope<Block *> set_block(current_block, &block);
        for(NodeList<Statement>::iterator i=block.body.begin(); i!=block.body.end(); ++i)
        {
                assignment_insert_point = i;
                if(&block==&stage->content)
                        iface_insert_point = i;

                (*i)->visit(*this);
        }
}

string InterfaceGenerator::change_prefix(const string &name, const string &prefix) const
{
        unsigned offset = (name.compare(0, in_prefix.size(), in_prefix) ? 0 : in_prefix.size());
        return prefix+name.substr(offset);
}

VariableDeclaration *InterfaceGenerator::generate_interface(VariableDeclaration &var, const string &iface, const string &name)
{
        if(stage->content.variables.count(name))
                return 0;

        if(stage->type==Stage::GEOMETRY && !copy_block && var.interface=="out" && var.array)
                return 0;

        VariableDeclaration* iface_var = new VariableDeclaration;
        iface_var->sampling = var.sampling;
        iface_var->interface = iface;
        iface_var->type = var.type;
        iface_var->name = name;
        /* Geometry shader inputs are always arrays.  But if we're bringing in an
        entire block, the array is on the block and not individual variables. */
        if(stage->type==Stage::GEOMETRY && !copy_block)
                iface_var->array = ((var.array && var.interface!="in") || iface=="in");
        else
                iface_var->array = var.array;
        if(iface_var->array)
                iface_var->array_size = var.array_size;
        if(iface=="in")
        {
                iface_var->layout = var.layout;
                iface_var->linked_declaration = &var;
                var.linked_declaration = iface_var;
        }

        iface_target_block->body.insert(iface_insert_point, iface_var);
        iface_target_block->variables.insert(make_pair(name, iface_var));
        if(iface_target_block==&stage->content && iface=="in")
                declared_inputs.push_back(iface_var);

        return iface_var;
}

InterfaceBlock *InterfaceGenerator::generate_interface(InterfaceBlock &out_block)
{
        if(stage->interface_blocks.count("in"+out_block.name))
                return 0;

        InterfaceBlock *in_block = new InterfaceBlock;
        in_block->interface = "in";
        in_block->name = out_block.name;
        in_block->members = new Block;
        in_block->instance_name = out_block.instance_name;
        if(stage->type==Stage::GEOMETRY)
                in_block->array = true;
        else
                in_block->array = out_block.array;
        in_block->linked_block = &out_block;
        out_block.linked_block = in_block;

        {
                SetFlag set_copy(copy_block, true);
                SetForScope<Block *> set_target(iface_target_block, in_block->members.get());
                SetForScope<NodeList<Statement>::iterator> set_ins_pt(iface_insert_point, in_block->members->body.end());
                if(out_block.struct_declaration)
                        out_block.struct_declaration->members.visit(*this);
                else if(out_block.members)
                        out_block.members->visit(*this);
        }

        iface_target_block->body.insert(iface_insert_point, in_block);
        stage->interface_blocks.insert(make_pair("in"+in_block->name, in_block));
        if(!in_block->instance_name.empty())
                stage->interface_blocks.insert(make_pair("_"+in_block->instance_name, in_block));

        SetFlag set_scope(function_scope, false);
        SetForScope<Block *> set_block(current_block, &stage->content);
        in_block->visit(*this);

        return in_block;
}

ExpressionStatement &InterfaceGenerator::insert_assignment(const string &left, Expression *right)
{
        Assignment *assign = new Assignment;
        VariableReference *ref = new VariableReference;
        ref->name = left;
        assign->left = ref;
        assign->oper = &Operator::get_operator("=", Operator::BINARY);
        assign->right = right;

        ExpressionStatement *stmt = new ExpressionStatement;
        stmt->expression = assign;
        current_block->body.insert(assignment_insert_point, stmt);
        stmt->visit(*this);

        return *stmt;
}

void InterfaceGenerator::visit(VariableReference &var)
{
        if(var.declaration || !stage->previous)
                return;
        /* Don't pull a variable from previous stage if we just generated an output
        interface in this stage */
        if(stage->content.variables.count(var.name))
                return;

        const map<string, VariableDeclaration *> &prev_vars = stage->previous->content.variables;
        map<string, VariableDeclaration *>::const_iterator i = prev_vars.find(var.name);
        if(i==prev_vars.end() || i->second->interface!="out")
                i = prev_vars.find(in_prefix+var.name);
        if(i!=prev_vars.end() && i->second->interface=="out")
        {
                if(stage->type==Stage::GEOMETRY && i->second->array)
                        stage->diagnostics.push_back(Diagnostic(Diagnostic::WARN, var.source, var.line,
                                format("Can't access '%s' through automatic interface because it's an array", var.name)));
                else
                {
                        generate_interface(*i->second, "in", i->second->name);
                        var.name = i->second->name;
                }
                return;
        }

        const map<string, InterfaceBlock *> &prev_blocks = stage->previous->interface_blocks;
        map<string, InterfaceBlock *>::const_iterator j = prev_blocks.find("_"+var.name);
        if(j!=prev_blocks.end() && j->second->interface=="out")
        {
                generate_interface(*j->second);
                /* Let VariableResolver convert the variable reference into an interface
                block reference. */
                return;
        }

        for(j=prev_blocks.begin(); j!=prev_blocks.end(); ++j)
                if(j->second->instance_name.empty() && j->second->struct_declaration)
                {
                        const map<string, VariableDeclaration *> &iface_vars = j->second->struct_declaration->members.variables;
                        i = iface_vars.find(var.name);
                        if(i!=iface_vars.end())
                        {
                                generate_interface(*j->second);
                                return;
                        }
                }
}

void InterfaceGenerator::visit(VariableDeclaration &var)
{
        if(copy_block)
                generate_interface(var, "in", var.name);
        else if(var.interface=="out")
        {
                /* For output variables in function scope, generate a global interface
                and replace the local declaration with an assignment. */
                VariableDeclaration *out_var = 0;
                if(function_scope && (out_var=generate_interface(var, "out", var.name)))
                {
                        out_var->source = var.source;
                        out_var->line = var.line;
                        nodes_to_remove.insert(&var);
                        if(var.init_expression)
                        {
                                ExpressionStatement &stmt = insert_assignment(var.name, var.init_expression->clone());
                                stmt.source = var.source;
                                stmt.line = var.line;
                                return;
                        }
                }
        }
        else if(var.interface=="in" && current_block==&stage->content)
        {
                if(var.name.compare(0, 3, "gl_"))
                        declared_inputs.push_back(&var);

                /* Try to link input variables in global scope with output variables from
                previous stage. */
                if(!var.linked_declaration && stage->previous)
                {
                        const map<string, VariableDeclaration *> &prev_vars = stage->previous->content.variables;
                        map<string, VariableDeclaration *>::const_iterator i = prev_vars.find(var.name);
                        if(i!=prev_vars.end() && i->second->interface=="out")
                        {
                                var.linked_declaration = i->second;
                                i->second->linked_declaration = &var;
                        }
                }
        }

        TraversingVisitor::visit(var);
}

void InterfaceGenerator::visit(InterfaceBlock &iface)
{
        if(iface.interface=="in")
        {
                /* Try to link input blocks with output blocks sharing the same block
                name from previous stage. */
                if(!iface.linked_block && stage->previous)
                {
                        const map<string, InterfaceBlock *> &prev_blocks = stage->previous->interface_blocks;
                        map<string, InterfaceBlock *>::const_iterator i = prev_blocks.find("out"+iface.name);
                        if(i!=prev_blocks.end())
                        {
                                iface.linked_block = i->second;
                                i->second->linked_block = &iface;
                        }
                }
        }

        TraversingVisitor::visit(iface);
}

void InterfaceGenerator::visit(FunctionDeclaration &func)
{
        SetFlag set_scope(function_scope, true);
        // Skip parameters because they're not useful here
        func.body.visit(*this);
}

void InterfaceGenerator::visit(Passthrough &pass)
{
        // Pass through all input variables declared so far.
        vector<VariableDeclaration *> pass_vars = declared_inputs;

        if(stage->previous)
        {
                const map<string, VariableDeclaration *> &prev_vars = stage->previous->content.variables;
                for(map<string, VariableDeclaration *>::const_iterator i=prev_vars.begin(); i!=prev_vars.end(); ++i)
                {
                        if(i->second->interface!="out")
                                continue;

                        /* Pass through output variables from the previous stage, but only
                        those which are not already linked to an input here. */
                        if(!i->second->linked_declaration && generate_interface(*i->second, "in", i->second->name))
                                pass_vars.push_back(i->second);
                }
        }

        if(stage->type==Stage::GEOMETRY)
        {
                /* Special case for geometry shader: copy gl_Position from input to
                output. */
                InterfaceBlockReference *ref = new InterfaceBlockReference;
                ref->name = "gl_in";

                BinaryExpression *subscript = new BinaryExpression;
                subscript->left = ref;
                subscript->oper = &Operator::get_operator("[", Operator::BINARY);
                subscript->right = pass.subscript;

                MemberAccess *memacc = new MemberAccess;
                memacc->left = subscript;
                memacc->member = "gl_Position";

                insert_assignment("gl_Position", memacc);
        }

        for(vector<VariableDeclaration *>::const_iterator i=pass_vars.begin(); i!=pass_vars.end(); ++i)
        {
                string out_name = change_prefix((*i)->name, out_prefix);
                generate_interface(**i, "out", out_name);

                VariableReference *ref = new VariableReference;
                ref->name = (*i)->name;
                if(pass.subscript)
                {
                        BinaryExpression *subscript = new BinaryExpression;
                        subscript->left = ref;
                        subscript->oper = &Operator::get_operator("[", Operator::BINARY);
                        subscript->right = pass.subscript;
                        insert_assignment(out_name, subscript);
                }
                else
                        insert_assignment(out_name, ref);
        }

        nodes_to_remove.insert(&pass);
}

} // namespace SL
} // namespace GL
} // namespace Msp