#include <msp/core/raii.h>
#include <msp/strings/format.h>
+#include <msp/strings/utils.h>
#include "optimize.h"
+#include "reflect.h"
using namespace std;
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(); (!specializable && i!=qualifiers.end()); ++i)
+ if(i->name=="constant_id")
+ {
+ specializable = true;
+ qualifiers.erase(i);
+ }
+
+ if(qualifiers.empty())
+ var.layout = 0;
+ }
+
+ if(specializable)
+ {
+ 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;
+ }
+ }
+}
+
+
InlineableFunctionLocator::InlineableFunctionLocator():
current_function(0),
return_count(0)
++count;
/* Don't inline functions which are called more than once or are called
recursively. */
- if(count>1 || def==current_function)
+ if((count>1 && def->source!=BUILTIN_SOURCE) || def==current_function)
inlineable.erase(def);
}
void InlineableFunctionLocator::visit(FunctionDeclaration &func)
{
+ bool has_out_params = false;
+ for(NodeArray<VariableDeclaration>::const_iterator i=func.parameters.begin(); (!has_out_params && i!=func.parameters.end()); ++i)
+ has_out_params = ((*i)->interface=="out");
+
unsigned &count = refcounts[func.definition];
- if(count<=1 && func.parameters.empty())
+ if((count<=1 || func.source==BUILTIN_SOURCE) && !has_out_params)
inlineable.insert(func.definition);
SetForScope<FunctionDeclaration *> set(current_function, &func);
InlineContentInjector::InlineContentInjector():
source_func(0),
- pass(DEPENDS)
+ pass(REFERENCED)
{ }
-const string &InlineContentInjector::apply(Stage &stage, FunctionDeclaration &target_func, Block &tgt_blk, const NodeList<Statement>::iterator &ins_pt, FunctionDeclaration &src)
+string InlineContentInjector::apply(Stage &stage, FunctionDeclaration &target_func, Block &tgt_blk, const NodeList<Statement>::iterator &ins_pt, FunctionCall &call)
{
- source_func = &src;
-
- // Collect all declarations the inlined function depends on.
- pass = DEPENDS;
- source_func->visit(*this);
+ source_func = call.declaration->definition;
/* Populate referenced_names from the target function so we can rename
variables from the inlined function that would conflict. */
pass = INLINE;
staging_block.parent = &tgt_blk;
staging_block.variables.clear();
- remap_prefix = source_func->name;
- for(NodeList<Statement>::iterator i=src.body.body.begin(); i!=src.body.body.end(); ++i)
+ vector<RefPtr<VariableDeclaration> > params;
+ params.reserve(source_func->parameters.size());
+ for(NodeArray<VariableDeclaration>::iterator i=source_func->parameters.begin(); i!=source_func->parameters.end(); ++i)
+ {
+ RefPtr<VariableDeclaration> var = (*i)->clone();
+ var->interface.clear();
+
+ SetForScope<Pass> set_pass(pass, RENAME);
+ var->visit(*this);
+
+ staging_block.body.push_back_nocopy(var);
+ params.push_back(var);
+ }
+
+ for(NodeList<Statement>::iterator i=source_func->body.body.begin(); i!=source_func->body.body.end(); ++i)
{
r_inlined_statement = 0;
(*i)->visit(*this);
SetForScope<Pass> set_pass(pass, RENAME);
r_inlined_statement->visit(*this);
- staging_block.body.push_back(0);
- staging_block.body.back() = r_inlined_statement;
+ staging_block.body.push_back_nocopy(r_inlined_statement);
}
/* Now collect names from the staging block. Local variables that would
global identifiers used by the source function. */
pass = RENAME;
staging_block.parent = source_func->body.parent;
- remap_prefix = target_func.name;
target_func.visit(*this);
+ // Put the argument expressions in place after all renaming has been done.
+ for(unsigned i=0; i<source_func->parameters.size(); ++i)
+ params[i]->init_expression = call.arguments[i]->clone();
+
tgt_blk.body.splice(ins_pt, staging_block.body);
- NodeReorderer().apply(stage, target_func, dependencies);
+ NodeReorderer().apply(stage, target_func, DependencyCollector().apply(*source_func));
return r_result_name;
}
if(i!=staging_block.variables.end())
var.name = i->second->name;
}
- else if(pass==DEPENDS && var.declaration)
- {
- dependencies.insert(var.declaration);
- var.declaration->visit(*this);
- }
else if(pass==REFERENCED)
referenced_names.insert(var.name);
}
void InlineContentInjector::visit(InterfaceBlockReference &iface)
{
- if(pass==DEPENDS && iface.declaration)
- {
- dependencies.insert(iface.declaration);
- iface.declaration->visit(*this);
- }
- else if(pass==REFERENCED)
+ if(pass==REFERENCED)
referenced_names.insert(iface.name);
}
void InlineContentInjector::visit(FunctionCall &call)
{
- if(pass==DEPENDS && call.declaration)
- dependencies.insert(call.declaration);
- else if(pass==REFERENCED)
+ if(pass==REFERENCED)
referenced_names.insert(call.name);
TraversingVisitor::visit(call);
}
if(pass==RENAME)
{
+ /* Check against conflicts with the other context as well as variables
+ already renamed here. */
+ bool conflict = (staging_block.variables.count(var.name) || referenced_names.count(var.name));
staging_block.variables[var.name] = &var;
- if(referenced_names.count(var.name))
+ if(conflict)
{
- string mapped_name = get_unused_variable_name(staging_block, var.name, remap_prefix);
+ string mapped_name = get_unused_variable_name(staging_block, var.name);
if(mapped_name!=var.name)
{
staging_block.variables[mapped_name] = &var;
}
}
}
- else if(pass==DEPENDS && var.type_declaration)
- {
- dependencies.insert(var.type_declaration);
- var.type_declaration->visit(*this);
- }
else if(pass==REFERENCED)
referenced_names.insert(var.type);
}
if(pass==INLINE && ret.expression)
{
// Create a new variable to hold the return value of the inlined function.
- r_result_name = get_unused_variable_name(staging_block, "_return", source_func->name);
+ r_result_name = get_unused_variable_name(staging_block, "_return");
RefPtr<VariableDeclaration> var = new VariableDeclaration;
var->source = ret.source;
var->line = ret.line;
void FunctionInliner::visit(FunctionCall &call)
{
+ for(NodeArray<Expression>::iterator i=call.arguments.begin(); (!r_inlined_here && i!=call.arguments.end()); ++i)
+ visit(*i);
+
if(r_inlined_here)
return;
- for(NodeArray<Expression>::iterator i=call.arguments.begin(); i!=call.arguments.end(); ++i)
- visit(*i);
-
FunctionDeclaration *def = call.declaration;
if(def)
def = def->definition;
if(def && inlineable.count(def))
{
- string result_name = InlineContentInjector().apply(*stage, *current_function, *current_block, insert_point, *def);
+ string result_name = InlineContentInjector().apply(*stage, *current_function, *current_block, insert_point, call);
// This will later get removed by UnusedVariableRemover.
if(result_name.empty())
- result_name = "msp_unused_from_inline";
+ result_name = "_msp_unused_from_inline";
RefPtr<VariableReference> ref = new VariableReference;
ref->name = result_name;
}
-ExpressionInliner::ExpressionInfo::ExpressionInfo():
- expression(0),
- assign_scope(0),
- inline_point(0),
- trivial(false),
- available(true)
-{ }
-
-
ExpressionInliner::ExpressionInliner():
r_ref_info(0),
- r_any_inlined(false),
r_trivial(false),
- mutating(false),
+ access_read(true),
+ access_write(false),
iteration_init(false),
iteration_body(0),
r_oper(0)
bool ExpressionInliner::apply(Stage &s)
{
s.content.visit(*this);
- return r_any_inlined;
-}
-
-void ExpressionInliner::inline_expression(Expression &expr, RefPtr<Expression> &ptr)
-{
- ptr = expr.clone();
- r_any_inlined = true;
-}
-
-void ExpressionInliner::visit(Block &block)
-{
- TraversingVisitor::visit(block);
- for(map<string, VariableDeclaration *>::iterator i=block.variables.begin(); i!=block.variables.end(); ++i)
- {
- map<Assignment::Target, ExpressionInfo>::iterator j = expressions.lower_bound(i->second);
- for(; (j!=expressions.end() && j->first.declaration==i->second); )
+ bool any_inlined = false;
+ for(list<ExpressionInfo>::iterator i=expressions.begin(); i!=expressions.end(); ++i)
+ if(i->expression && (i->trivial || i->uses.size()==1))
{
- if(j->second.expression && j->second.inline_point)
- inline_expression(*j->second.expression, *j->second.inline_point);
-
- expressions.erase(j++);
+ for(vector<ExpressionUse>::iterator j=i->uses.begin(); j!=i->uses.end(); ++j)
+ if(!j->blocked)
+ {
+ *j->reference = i->expression->clone();
+ any_inlined = true;
+ }
}
- }
- /* Expressions assigned in this block may depend on local variables of the
- block. If this is a conditionally executed block, the assignments might not
- always happen. Mark the expressions as not available to any outer blocks. */
- for(map<Assignment::Target, ExpressionInfo>::iterator i=expressions.begin(); i!=expressions.end(); ++i)
- if(i->second.assign_scope==&block)
- i->second.available = false;
+ return any_inlined;
}
void ExpressionInliner::visit(RefPtr<Expression> &expr)
{
r_ref_info = 0;
expr->visit(*this);
- if(r_ref_info && r_ref_info->expression && r_ref_info->available)
+ if(r_ref_info && r_ref_info->expression)
{
+ ExpressionUse use;
+ use.reference = &expr;
+ use.ref_scope = current_block;
+ use.blocked = access_write;
+
if(iteration_body && !r_ref_info->trivial)
{
- /* Don't inline non-trivial expressions which were assigned outside
- an iteration statement. The iteration may run multiple times, which
+ /* Block inlining of non-trivial expressions assigned outside an
+ iteration statement. The iteration may run multiple times, which
would cause the expression to also be evaluated multiple times. */
- Block *i = r_ref_info->assign_scope;
- for(; (i && i!=iteration_body); i=i->parent) ;
- if(!i)
- return;
+ for(Block *i=iteration_body->parent; (!use.blocked && i); i=i->parent)
+ use.blocked = (i==r_ref_info->assign_scope);
}
- if(r_ref_info->trivial)
- inline_expression(*r_ref_info->expression, expr);
- else
- /* Record the inline point for a non-trivial expression but don't
- inline it yet. It might turn out it shouldn't be inlined after all. */
- r_ref_info->inline_point = &expr;
+ /* Block inlining assignments from from inner scopes. The assignment may
+ depend on local variables of that scope or may not always be executed. */
+ for(Block *i=r_ref_info->assign_scope->parent; (!use.blocked && i); i=i->parent)
+ use.blocked = (i==current_block);
+
+ r_ref_info->uses.push_back(use);
}
r_oper = expr->oper;
r_ref_info = 0;
void ExpressionInliner::visit(VariableReference &var)
{
- if(var.declaration)
+ if(var.declaration && access_read)
{
- map<Assignment::Target, ExpressionInfo>::iterator i = expressions.find(var.declaration);
- if(i!=expressions.end())
- {
- /* If a non-trivial expression is referenced multiple times, don't
- inline it. */
- if(i->second.inline_point && !i->second.trivial)
- i->second.expression = 0;
- /* Mutating expressions are analogous to self-referencing assignments
- and prevent inlining. */
- if(mutating)
- i->second.expression = 0;
- r_ref_info = &i->second;
- }
+ map<Assignment::Target, ExpressionInfo *>::iterator i = assignments.find(var.declaration);
+ if(i!=assignments.end())
+ r_ref_info = i->second;
}
}
void ExpressionInliner::visit(UnaryExpression &unary)
{
- SetFlag set_target(mutating, mutating || unary.oper->token[1]=='+' || unary.oper->token[1]=='-');
+ SetFlag set_write(access_write, access_write || unary.oper->token[1]=='+' || unary.oper->token[1]=='-');
visit(unary.expression);
r_trivial = false;
}
{
visit(binary.left);
{
- SetFlag clear_target(mutating, false);
+ SetFlag clear_write(access_write, false);
visit(binary.right);
}
r_trivial = false;
void ExpressionInliner::visit(Assignment &assign)
{
{
- SetFlag set_target(mutating);
+ SetFlag set_read(access_read, assign.oper->token[0]!='=');
+ SetFlag set_write(access_write);
visit(assign.left);
}
r_oper = 0;
+ r_trivial = true;
visit(assign.right);
- map<Assignment::Target, ExpressionInfo>::iterator i = expressions.find(assign.target);
- if(i!=expressions.end())
+ map<Assignment::Target, ExpressionInfo *>::iterator i = assignments.find(assign.target);
+ if(i!=assignments.end())
{
- /* Self-referencing assignments can't be inlined without additional
- work. Just clear any previous expression. */
- i->second.expression = (assign.self_referencing ? 0 : assign.right.get());
- i->second.assign_scope = current_block;
- i->second.inline_point = 0;
- i->second.available = true;
+ if(iteration_body && i->second->expression)
+ {
+ /* Block inlining into previous references within the iteration
+ statement. On iterations after the first they would refer to the
+ assignment within the iteration. */
+ for(vector<ExpressionUse>::iterator j=i->second->uses.begin(); j!=i->second->uses.end(); ++j)
+ for(Block *k=j->ref_scope; (!j->blocked && k); k=k->parent)
+ j->blocked = (k==iteration_body);
+ }
+
+ expressions.push_back(ExpressionInfo());
+ ExpressionInfo &info = expressions.back();
+ info.target = assign.target;
+ // Self-referencing assignments can't be inlined without additional work.
+ if(!assign.self_referencing)
+ info.expression = assign.right;
+ info.assign_scope = current_block;
+ info.trivial = r_trivial;
+
+ i->second = &info;
}
r_trivial = false;
analyze and non-trivial expressions could be expensive to inline. */
if((current_block->parent || (constant && r_trivial)) && var.interface.empty())
{
- ExpressionInfo &info = expressions[&var];
+ expressions.push_back(ExpressionInfo());
+ ExpressionInfo &info = expressions.back();
+ info.target = &var;
/* Assume variables declared in an iteration initialization statement
will have their values change throughout the iteration. */
- info.expression = (iteration_init ? 0 : var.init_expression.get());
+ if(!iteration_init)
+ info.expression = var.init_expression;
info.assign_scope = current_block;
info.trivial = r_trivial;
+
+ assignments[&var] = &info;
}
}
}
-BasicTypeDeclaration::Kind ConstantFolder::get_value_kind(const Variant &value)
-{
- if(value.check_type<bool>())
- return BasicTypeDeclaration::BOOL;
- else if(value.check_type<int>())
- return BasicTypeDeclaration::INT;
- else if(value.check_type<float>())
- return BasicTypeDeclaration::FLOAT;
- else
- return BasicTypeDeclaration::VOID;
-}
-
template<typename T>
T ConstantFolder::evaluate_logical(char oper, T left, T right)
{
}
}
+template<typename T>
+T ConstantFolder::evaluate_int_special_op(char oper, T left, T right)
+{
+ switch(oper)
+ {
+ case '%': return left%right;
+ case '<': return left<<right;
+ case '>': return left>>right;
+ default: return T();
+ }
+}
+
+template<typename T>
+void ConstantFolder::convert_to_result(const Variant &value)
+{
+ if(value.check_type<bool>())
+ set_result(static_cast<T>(value.value<bool>()));
+ else if(value.check_type<int>())
+ set_result(static_cast<T>(value.value<int>()));
+ else if(value.check_type<unsigned>())
+ set_result(static_cast<T>(value.value<unsigned>()));
+ else if(value.check_type<float>())
+ set_result(static_cast<T>(value.value<float>()));
+}
+
void ConstantFolder::set_result(const Variant &value, bool literal)
{
r_constant_value = value;
if(!r_constant || r_literal || r_uses_iter_var)
return;
- BasicTypeDeclaration::Kind kind = get_value_kind(r_constant_value);
- if(kind==BasicTypeDeclaration::VOID)
+ RefPtr<Literal> literal = new Literal;
+ if(r_constant_value.check_type<bool>())
+ literal->token = (r_constant_value.value<bool>() ? "true" : "false");
+ else if(r_constant_value.check_type<int>())
+ literal->token = lexical_cast<string>(r_constant_value.value<int>());
+ else if(r_constant_value.check_type<unsigned>())
+ literal->token = lexical_cast<string>(r_constant_value.value<unsigned>())+"u";
+ else if(r_constant_value.check_type<float>())
+ {
+ literal->token = lexical_cast<string>(r_constant_value.value<float>(), Fmt().precision(8));
+ if(literal->token.find('.')==string::npos && literal->token.find('e')==string::npos)
+ literal->token += ".0";
+ }
+ else
{
r_constant = false;
return;
}
-
- RefPtr<Literal> literal = new Literal;
- if(kind==BasicTypeDeclaration::BOOL)
- literal->token = (r_constant_value.value<bool>() ? "true" : "false");
- else if(kind==BasicTypeDeclaration::INT)
- literal->token = lexical_cast<string>(r_constant_value.value<int>());
- else if(kind==BasicTypeDeclaration::FLOAT)
- literal->token = lexical_cast<string>(r_constant_value.value<float>());
literal->value = r_constant_value;
expr = literal;
+ r_any_folded = true;
}
void ConstantFolder::visit(Literal &literal)
if(!can_fold)
return;
- BasicTypeDeclaration::Kind kind = get_value_kind(r_constant_value);
-
char oper = unary.oper->token[0];
char oper2 = unary.oper->token[1];
if(oper=='!')
{
- if(kind==BasicTypeDeclaration::BOOL)
+ if(r_constant_value.check_type<bool>())
set_result(!r_constant_value.value<bool>());
}
else if(oper=='~')
{
- if(kind==BasicTypeDeclaration::INT)
+ if(r_constant_value.check_type<int>())
set_result(~r_constant_value.value<int>());
+ else if(r_constant_value.check_type<unsigned>())
+ set_result(~r_constant_value.value<unsigned>());
}
else if(oper=='-' && !oper2)
{
- if(kind==BasicTypeDeclaration::INT)
+ if(r_constant_value.check_type<int>())
set_result(-r_constant_value.value<int>());
- else if(kind==BasicTypeDeclaration::FLOAT)
+ else if(r_constant_value.check_type<unsigned>())
+ set_result(-r_constant_value.value<unsigned>());
+ else if(r_constant_value.check_type<float>())
set_result(-r_constant_value.value<float>());
}
}
if(!can_fold)
return;
- BasicTypeDeclaration::Kind left_kind = get_value_kind(left_value);
- BasicTypeDeclaration::Kind right_kind = get_value_kind(r_constant_value);
// Currently only expressions with both sides of equal types are handled.
- if(left_kind!=right_kind)
+ if(!left_value.check_same_type(r_constant_value))
return;
char oper = binary.oper->token[0];
char oper2 = binary.oper->token[1];
if(oper=='&' || oper=='|' || oper=='^')
{
- if(oper2==oper && left_kind==BasicTypeDeclaration::BOOL)
+ if(oper2==oper && left_value.check_type<bool>())
set_result(evaluate_logical(oper, left_value.value<bool>(), r_constant_value.value<bool>()));
- else if(!oper2 && left_kind==BasicTypeDeclaration::INT)
+ else if(!oper2 && left_value.check_type<int>())
set_result(evaluate_logical(oper, left_value.value<int>(), r_constant_value.value<int>()));
+ else if(!oper2 && left_value.check_type<unsigned>())
+ set_result(evaluate_logical(oper, left_value.value<unsigned>(), r_constant_value.value<unsigned>()));
}
else if((oper=='<' || oper=='>') && oper2!=oper)
{
- if(left_kind==BasicTypeDeclaration::INT)
+ if(left_value.check_type<int>())
set_result(evaluate_relation(binary.oper->token, left_value.value<int>(), r_constant_value.value<int>()));
- else if(left_kind==BasicTypeDeclaration::FLOAT)
+ else if(left_value.check_type<unsigned>())
+ set_result(evaluate_relation(binary.oper->token, left_value.value<unsigned>(), r_constant_value.value<unsigned>()));
+ else if(left_value.check_type<float>())
set_result(evaluate_relation(binary.oper->token, left_value.value<float>(), r_constant_value.value<float>()));
}
else if((oper=='=' || oper=='!') && oper2=='=')
{
- if(left_kind==BasicTypeDeclaration::INT)
+ if(left_value.check_type<int>())
set_result((left_value.value<int>()==r_constant_value.value<int>()) == (oper=='='));
- if(left_kind==BasicTypeDeclaration::FLOAT)
+ else if(left_value.check_type<unsigned>())
+ set_result((left_value.value<unsigned>()==r_constant_value.value<unsigned>()) == (oper=='='));
+ else if(left_value.check_type<float>())
set_result((left_value.value<float>()==r_constant_value.value<float>()) == (oper=='='));
}
else if(oper=='+' || oper=='-' || oper=='*' || oper=='/')
{
- if(left_kind==BasicTypeDeclaration::INT)
+ if(left_value.check_type<int>())
set_result(evaluate_arithmetic(oper, left_value.value<int>(), r_constant_value.value<int>()));
- else if(left_kind==BasicTypeDeclaration::FLOAT)
+ else if(left_value.check_type<unsigned>())
+ set_result(evaluate_arithmetic(oper, left_value.value<unsigned>(), r_constant_value.value<unsigned>()));
+ else if(left_value.check_type<float>())
set_result(evaluate_arithmetic(oper, left_value.value<float>(), r_constant_value.value<float>()));
}
else if(oper=='%' || ((oper=='<' || oper=='>') && oper2==oper))
{
- if(left_kind!=BasicTypeDeclaration::INT)
- return;
-
- if(oper=='%')
- set_result(left_value.value<int>()%r_constant_value.value<int>());
- else if(oper=='<')
- set_result(left_value.value<int>()<<r_constant_value.value<int>());
- else if(oper=='>')
- set_result(left_value.value<int>()>>r_constant_value.value<int>());
+ if(left_value.check_type<int>())
+ set_result(evaluate_int_special_op(oper, left_value.value<int>(), r_constant_value.value<int>()));
+ else if(left_value.check_type<unsigned>())
+ set_result(evaluate_int_special_op(oper, left_value.value<unsigned>(), r_constant_value.value<unsigned>()));
}
}
void ConstantFolder::visit(FunctionCall &call)
{
+ if(call.constructor && call.type && call.arguments.size()==1)
+ {
+ const BasicTypeDeclaration *basic = dynamic_cast<const BasicTypeDeclaration *>(call.type);
+ if(basic)
+ {
+ visit(call.arguments[0]);
+ bool can_fold = r_constant;
+ r_constant = false;
+ if(!can_fold)
+ return;
+
+ if(basic->kind==BasicTypeDeclaration::BOOL)
+ convert_to_result<bool>(r_constant_value);
+ else if(basic->kind==BasicTypeDeclaration::INT && basic->size==32 && basic->sign)
+ convert_to_result<int>(r_constant_value);
+ else if(basic->kind==BasicTypeDeclaration::INT && basic->size==32 && !basic->sign)
+ convert_to_result<unsigned>(r_constant_value);
+ else if(basic->kind==BasicTypeDeclaration::FLOAT && basic->size==32)
+ convert_to_result<float>(r_constant_value);
+
+ return;
+ }
+ }
+
TraversingVisitor::visit(call);
r_constant = false;
}
}
-bool UnusedTypeRemover::apply(Stage &stage)
+UnreachableCodeRemover::UnreachableCodeRemover():
+ reachable(true)
+{ }
+
+bool UnreachableCodeRemover::apply(Stage &stage)
{
stage.content.visit(*this);
- NodeRemover().apply(stage, unused_nodes);
- return !unused_nodes.empty();
+ NodeRemover().apply(stage, unreachable_nodes);
+ return !unreachable_nodes.empty();
+}
+
+void UnreachableCodeRemover::visit(Block &block)
+{
+ NodeList<Statement>::iterator i = block.body.begin();
+ for(; (reachable && i!=block.body.end()); ++i)
+ (*i)->visit(*this);
+ for(; i!=block.body.end(); ++i)
+ unreachable_nodes.insert(i->get());
}
-void UnusedTypeRemover::visit(Literal &literal)
+void UnreachableCodeRemover::visit(FunctionDeclaration &func)
{
- unused_nodes.erase(literal.type);
+ TraversingVisitor::visit(func);
+ reachable = true;
}
-void UnusedTypeRemover::visit(UnaryExpression &unary)
+void UnreachableCodeRemover::visit(Conditional &cond)
{
- unused_nodes.erase(unary.type);
- TraversingVisitor::visit(unary);
+ cond.body.visit(*this);
+ bool reachable_if_true = reachable;
+ reachable = true;
+ cond.else_body.visit(*this);
+
+ reachable |= reachable_if_true;
}
-void UnusedTypeRemover::visit(BinaryExpression &binary)
+void UnreachableCodeRemover::visit(Iteration &iter)
{
- unused_nodes.erase(binary.type);
- TraversingVisitor::visit(binary);
+ TraversingVisitor::visit(iter);
+
+ /* Always consider code after a loop reachable, since there's no checking
+ for whether the loop executes. */
+ reachable = true;
}
-void UnusedTypeRemover::visit(TernaryExpression &ternary)
+
+bool UnusedTypeRemover::apply(Stage &stage)
{
- unused_nodes.erase(ternary.type);
- TraversingVisitor::visit(ternary);
+ stage.content.visit(*this);
+ NodeRemover().apply(stage, unused_nodes);
+ return !unused_nodes.empty();
}
-void UnusedTypeRemover::visit(FunctionCall &call)
+void UnusedTypeRemover::visit(RefPtr<Expression> &expr)
{
- unused_nodes.erase(call.type);
- TraversingVisitor::visit(call);
+ unused_nodes.erase(expr->type);
+ TraversingVisitor::visit(expr);
}
void UnusedTypeRemover::visit(BasicTypeDeclaration &type)
void UnusedTypeRemover::visit(VariableDeclaration &var)
{
unused_nodes.erase(var.type_declaration);
+ TraversingVisitor::visit(var);
}
void UnusedTypeRemover::visit(InterfaceBlock &iface)
interface_block(0),
r_assignment(0),
assignment_target(false),
- r_side_effects(false)
+ r_side_effects(false),
+ in_struct(false),
+ composite_reference(false),
+ in_loop(0)
{ }
bool UnusedVariableRemover::apply(Stage &s)
if(i->used_by.empty())
unused_nodes.insert(i->node);
- for(map<string, InterfaceBlock *>::const_iterator i=s.interface_blocks.begin(); i!=s.interface_blocks.end(); ++i)
- if(i->second->instance_name.empty())
- unused_nodes.insert(i->second);
-
for(BlockVariableMap::const_iterator i=variables.begin(); i!=variables.end(); ++i)
{
if(i->second.output)
var_info.referenced = true;
if(!assignment_target)
{
+ bool loop_external = false;
for(vector<AssignmentInfo *>::const_iterator i=var_info.assignments.begin(); i!=var_info.assignments.end(); ++i)
- (*i)->used_by.push_back(&node);
+ {
+ bool covered = true;
+ for(unsigned j=0; (covered && j<(*i)->target.chain_len && j<target.chain_len); ++j)
+ {
+ Assignment::Target::ChainType type1 = static_cast<Assignment::Target::ChainType>((*i)->target.chain[j]&0xC0);
+ Assignment::Target::ChainType type2 = static_cast<Assignment::Target::ChainType>(target.chain[j]&0xC0);
+ if(type1==Assignment::Target::SWIZZLE || type2==Assignment::Target::SWIZZLE)
+ {
+ unsigned index1 = (*i)->target.chain[j]&0x3F;
+ unsigned index2 = target.chain[j]&0x3F;
+ if(type1==Assignment::Target::SWIZZLE && type2==Assignment::Target::SWIZZLE)
+ covered = index1&index2;
+ else if(type1==Assignment::Target::ARRAY && index1<4)
+ covered = index2&(1<<index1);
+ else if(type2==Assignment::Target::ARRAY && index2<4)
+ covered = index1&(1<<index2);
+ /* If it's some other combination (shouldn't happen), leave
+ covered as true */
+ }
+ else
+ covered = ((*i)->target.chain[j]==target.chain[j]);
+ }
+
+ if(covered)
+ {
+ (*i)->used_by.push_back(&node);
+ if((*i)->in_loop<in_loop)
+ loop_external = true;
+ }
+ }
+
+ if(loop_external)
+ loop_ext_refs.push_back(&node);
}
}
void UnusedVariableRemover::visit(VariableReference &var)
{
- referenced(var.declaration, var);
+ if(composite_reference)
+ r_reference.declaration = var.declaration;
+ else
+ referenced(var.declaration, var);
}
void UnusedVariableRemover::visit(InterfaceBlockReference &iface)
{
- referenced(iface.declaration, iface);
+ if(composite_reference)
+ r_reference.declaration = iface.declaration;
+ else
+ referenced(iface.declaration, iface);
+}
+
+void UnusedVariableRemover::visit_composite(Expression &expr)
+{
+ if(!composite_reference)
+ r_reference = Assignment::Target();
+
+ SetFlag set_composite(composite_reference);
+ expr.visit(*this);
+}
+
+void UnusedVariableRemover::visit(MemberAccess &memacc)
+{
+ visit_composite(*memacc.left);
+
+ add_to_chain(r_reference, Assignment::Target::MEMBER, memacc.index);
+
+ if(!composite_reference && r_reference.declaration)
+ referenced(r_reference, memacc);
+}
+
+void UnusedVariableRemover::visit(Swizzle &swizzle)
+{
+ visit_composite(*swizzle.left);
+
+ unsigned mask = 0;
+ for(unsigned i=0; i<swizzle.count; ++i)
+ mask |= 1<<swizzle.components[i];
+ add_to_chain(r_reference, Assignment::Target::SWIZZLE, mask);
+
+ if(!composite_reference && r_reference.declaration)
+ referenced(r_reference, swizzle);
}
void UnusedVariableRemover::visit(UnaryExpression &unary)
{
if(binary.oper->token[0]=='[')
{
- binary.left->visit(*this);
- SetFlag set(assignment_target, false);
- binary.right->visit(*this);
+ visit_composite(*binary.left);
+
+ {
+ SetFlag clear_assignment(assignment_target, false);
+ SetFlag clear_composite(composite_reference, false);
+ binary.right->visit(*this);
+ }
+
+ add_to_chain(r_reference, Assignment::Target::ARRAY, 0x3F);
+
+ if(!composite_reference && r_reference.declaration)
+ referenced(r_reference, binary);
}
else
+ {
+ SetFlag clear_composite(composite_reference, false);
TraversingVisitor::visit(binary);
+ }
+}
+
+void UnusedVariableRemover::visit(TernaryExpression &ternary)
+{
+ SetFlag clear_composite(composite_reference, false);
+ TraversingVisitor::visit(ternary);
}
void UnusedVariableRemover::visit(Assignment &assign)
void UnusedVariableRemover::visit(FunctionCall &call)
{
+ SetFlag clear_composite(composite_reference, false);
TraversingVisitor::visit(call);
/* Treat function calls as having side effects so expression statements
consisting of nothing but a function call won't be optimized away. */
AssignmentInfo &assign_info = assignments.back();
assign_info.node = &node;
assign_info.target = target;
+ assign_info.in_loop = in_loop;
/* An assignment to the target hides any assignments to the same target or
its subfields. */
VariableInfo &var_info = variables[target.declaration];
- for(unsigned i=0; i<var_info.assignments.size(); ++i)
+ for(unsigned i=0; i<var_info.assignments.size(); )
{
const Assignment::Target &t = var_info.assignments[i]->target;
unused_nodes.insert(&expr);
}
+void UnusedVariableRemover::visit(StructDeclaration &strct)
+{
+ SetFlag set_struct(in_struct);
+ TraversingVisitor::visit(strct);
+}
+
void UnusedVariableRemover::visit(VariableDeclaration &var)
{
+ TraversingVisitor::visit(var);
+
+ if(in_struct)
+ return;
+
VariableInfo &var_info = variables[&var];
var_info.interface_block = interface_block;
/* Mark variables as output if they're used by the next stage or the
graphics API. */
if(interface_block)
- var_info.output = (interface_block->interface=="out" && (interface_block->linked_block || !interface_block->name.compare(0, 3, "gl_")));
+ var_info.output = (interface_block->interface=="out" && (interface_block->linked_block || !interface_block->block_name.compare(0, 3, "gl_")));
else
var_info.output = (var.interface=="out" && (stage->type==Stage::FRAGMENT || var.linked_declaration || !var.name.compare(0, 3, "gl_")));
var_info.initialized = true;
record_assignment(&var, *var.init_expression);
}
- TraversingVisitor::visit(var);
}
void UnusedVariableRemover::visit(InterfaceBlock &iface)
{
- if(iface.instance_name.empty())
- {
- SetForScope<InterfaceBlock *> set_block(interface_block, &iface);
- iface.struct_declaration->members.visit(*this);
- }
- else
- {
- VariableInfo &var_info = variables[&iface];
- var_info.output = (iface.interface=="out" && (iface.linked_block || !iface.name.compare(0, 3, "gl_")));
- }
+ VariableInfo &var_info = variables[&iface];
+ var_info.output = (iface.interface=="out" && (iface.linked_block || !iface.block_name.compare(0, 3, "gl_")));
}
void UnusedVariableRemover::merge_variables(const BlockVariableMap &other_vars)
void UnusedVariableRemover::visit(Iteration &iter)
{
BlockVariableMap saved_vars = variables;
- TraversingVisitor::visit(iter);
+ vector<Node *> saved_refs;
+ swap(loop_ext_refs, saved_refs);
+ {
+ SetForScope<unsigned> set_loop(in_loop, in_loop+1);
+ TraversingVisitor::visit(iter);
+ }
+ swap(loop_ext_refs, saved_refs);
+
+ /* Visit the external references of the loop again to record assignments
+ done in the loop as used. */
+ for(vector<Node *>::const_iterator i=saved_refs.begin(); i!=saved_refs.end(); ++i)
+ (*i)->visit(*this);
/* Merge assignments from the iteration, without clearing previous state.
Further analysis is needed to determine which parts of the iteration body