view dmd/inline.c @ 883:b52d5de7783f

GC defines and linkage changes.
author Christian Kamm <kamm incasoftware de>
date Thu, 08 Jan 2009 18:20:02 +0100
parents aaade6ded589
children 1860414bf3b7
line wrap: on
line source

// Copyright (c) 1999-2007 by Digital Mars
// All Rights Reserved
// written by Walter Bright
// http://www.digitalmars.com
// License for redistribution is by either the Artistic License
// in artistic.txt, or the GNU General Public License in gnu.txt.
// See the included readme.txt for details.

// Routines to perform function inlining

#define LOG 0

#include <stdio.h>
#include <stdlib.h>
#include <assert.h>

#include "id.h"
#include "init.h"
#include "declaration.h"
#include "aggregate.h"
#include "expression.h"
#include "statement.h"
#include "mtype.h"

/* ========== Compute cost of inlining =============== */

/* Walk trees to determine if inlining can be done, and if so,
 * if it is too complex to be worth inlining or not.
 */

struct InlineCostState
{
    int nested;
    int hasthis;
    int hdrscan;    // !=0 if inline scan for 'header' content
    FuncDeclaration *fd;
};

const int COST_MAX = 250;

int Statement::inlineCost(InlineCostState *ics)
{
    return COST_MAX;		// default is we can't inline it
}

int ExpStatement::inlineCost(InlineCostState *ics)
{
    return exp ? exp->inlineCost(ics) : 0;
}

int CompoundStatement::inlineCost(InlineCostState *ics)
{   int cost = 0;

    for (size_t i = 0; i < statements->dim; i++)
    {	Statement *s = (Statement *) statements->data[i];
	if (s)
	{
	    cost += s->inlineCost(ics);
	    if (cost >= COST_MAX)
		break;
	}
    }
    return cost;
}

int UnrolledLoopStatement::inlineCost(InlineCostState *ics)
{   int cost = 0;

    for (size_t i = 0; i < statements->dim; i++)
    {	Statement *s = (Statement *) statements->data[i];
	if (s)
	{
	    cost += s->inlineCost(ics);
	    if (cost >= COST_MAX)
		break;
	}
    }
    return cost;
}

int IfStatement::inlineCost(InlineCostState *ics)
{
    int cost;

    /* Can't declare variables inside ?: expressions, so
     * we cannot inline if a variable is declared.
     */
    if (arg)
	return COST_MAX;

    cost = condition->inlineCost(ics);

    /* Specifically allow:
     *	if (condition)
     *	    return exp1;
     *	else
     *	    return exp2;
     * Otherwise, we can't handle return statements nested in if's.
     */

    if (elsebody && ifbody &&
	ifbody->isReturnStatement() &&
	elsebody->isReturnStatement())
    {
	cost += ifbody->inlineCost(ics);
	cost += elsebody->inlineCost(ics);
	//printf("cost = %d\n", cost);
    }
    else
    {
	ics->nested += 1;
	if (ifbody)
	    cost += ifbody->inlineCost(ics);
	if (elsebody)
	    cost += elsebody->inlineCost(ics);
	ics->nested -= 1;
    }
    return cost;
}

int ReturnStatement::inlineCost(InlineCostState *ics)
{
    // Can't handle return statements nested in if's
    if (ics->nested)
	return COST_MAX;
    return exp ? exp->inlineCost(ics) : 0;
}

/* -------------------------- */

int arrayInlineCost(InlineCostState *ics, Array *arguments)
{   int cost = 0;

    if (arguments)
    {
	for (int i = 0; i < arguments->dim; i++)
	{   Expression *e = (Expression *)arguments->data[i];

	    if (e)
		cost += e->inlineCost(ics);
	}
    }
    return cost;
}

int Expression::inlineCost(InlineCostState *ics)
{
    return 1;
}

int VarExp::inlineCost(InlineCostState *ics)
{
    //printf("VarExp::inlineCost() %s\n", toChars());
    return 1;
}

int ThisExp::inlineCost(InlineCostState *ics)
{
    FuncDeclaration *fd = ics->fd;
    if (!ics->hdrscan)
	if (fd->isNested() || !ics->hasthis)
	    return COST_MAX;
    return 1;
}

int SuperExp::inlineCost(InlineCostState *ics)
{
    FuncDeclaration *fd = ics->fd;
    if (!ics->hdrscan)
	if (fd->isNested() || !ics->hasthis)
	    return COST_MAX;
    return 1;
}

int TupleExp::inlineCost(InlineCostState *ics)
{
    return 1 + arrayInlineCost(ics, exps);
}

int ArrayLiteralExp::inlineCost(InlineCostState *ics)
{
    return 1 + arrayInlineCost(ics, elements);
}

int AssocArrayLiteralExp::inlineCost(InlineCostState *ics)
{
    return 1 + arrayInlineCost(ics, keys) + arrayInlineCost(ics, values);
}

int StructLiteralExp::inlineCost(InlineCostState *ics)
{
    return 1 + arrayInlineCost(ics, elements);
}

int FuncExp::inlineCost(InlineCostState *ics)
{
    // Right now, this makes the function be output to the .obj file twice.
    return COST_MAX;
}

int DelegateExp::inlineCost(InlineCostState *ics)
{
    return COST_MAX;
}

int DeclarationExp::inlineCost(InlineCostState *ics)
{   int cost = 0;
    VarDeclaration *vd;

    //printf("DeclarationExp::inlineCost()\n");
    vd = declaration->isVarDeclaration();
    if (vd)
    {
	TupleDeclaration *td = vd->toAlias()->isTupleDeclaration();
	if (td)
	{
#if 1
	    return COST_MAX;	// finish DeclarationExp::doInline
#else
	    for (size_t i = 0; i < td->objects->dim; i++)
	    {   Object *o = (Object *)td->objects->data[i];
		if (o->dyncast() != DYNCAST_EXPRESSION)
		    return COST_MAX;
		Expression *eo = (Expression *)o;
		if (eo->op != TOKdsymbol)
		    return COST_MAX;
	    }
	    return td->objects->dim;
#endif
	}
	if (!ics->hdrscan && vd->isDataseg())
	    return COST_MAX;
	cost += 1;

	// Scan initializer (vd->init)
	if (vd->init)
	{
	    ExpInitializer *ie = vd->init->isExpInitializer();

	    if (ie)
	    {
		cost += ie->exp->inlineCost(ics);
	    }
	}
    }

    // These can contain functions, which when copied, get output twice.
    if (declaration->isStructDeclaration() ||
	declaration->isClassDeclaration() ||
	declaration->isFuncDeclaration() ||
	declaration->isTypedefDeclaration() ||
	declaration->isTemplateMixin())
	return COST_MAX;

    //printf("DeclarationExp::inlineCost('%s')\n", toChars());
    return cost;
}

int UnaExp::inlineCost(InlineCostState *ics)
{
    return 1 + e1->inlineCost(ics);
}

int AssertExp::inlineCost(InlineCostState *ics)
{
    return 1 + e1->inlineCost(ics) + (msg ? msg->inlineCost(ics) : 0);
}

int BinExp::inlineCost(InlineCostState *ics)
{
    return 1 + e1->inlineCost(ics) + e2->inlineCost(ics);
}

int CallExp::inlineCost(InlineCostState *ics)
{
    return 1 + e1->inlineCost(ics) + arrayInlineCost(ics, arguments);
}

int SliceExp::inlineCost(InlineCostState *ics)
{   int cost;

    cost = 1 + e1->inlineCost(ics);
    if (lwr)
	cost += lwr->inlineCost(ics);
    if (upr)
	cost += upr->inlineCost(ics);
    return cost;
}

int ArrayExp::inlineCost(InlineCostState *ics)
{
    return 1 + e1->inlineCost(ics) + arrayInlineCost(ics, arguments);
}


int CondExp::inlineCost(InlineCostState *ics)
{
    return 1 +
	 e1->inlineCost(ics) +
	 e2->inlineCost(ics) +
	 econd->inlineCost(ics);
}


/* ======================== Perform the inlining ============================== */

/* Inlining is done by:
 * o	Converting to an Expression
 * o	Copying the trees of the function to be inlined
 * o	Renaming the variables
 */

struct InlineDoState
{
    VarDeclaration *vthis;
    Array from;		// old Dsymbols
    Array to;		// parallel array of new Dsymbols
    Dsymbol *parent;	// new parent
};

Expression *Statement::doInline(InlineDoState *ids)
{
    assert(0);
    return NULL;		// default is we can't inline it
}

Expression *ExpStatement::doInline(InlineDoState *ids)
{
#if LOG
    if (exp) printf("ExpStatement::doInline() '%s'\n", exp->toChars());
#endif
    return exp ? exp->doInline(ids) : NULL;
}

Expression *CompoundStatement::doInline(InlineDoState *ids)
{
    Expression *e = NULL;

    //printf("CompoundStatement::doInline() %d\n", statements->dim);
    for (size_t i = 0; i < statements->dim; i++)
    {	Statement *s = (Statement *) statements->data[i];
	if (s)
	{
	    Expression *e2 = s->doInline(ids);
	    e = Expression::combine(e, e2);
	    if (s->isReturnStatement())
		break;

	    /* Check for:
	     *	if (condition)
	     *	    return exp1;
	     *	else
	     *	    return exp2;
	     */
	    IfStatement *ifs = s->isIfStatement();
	    if (ifs && ifs->elsebody && ifs->ifbody &&
		ifs->ifbody->isReturnStatement() &&
		ifs->elsebody->isReturnStatement()
	       )
		break;

	}
    }
    return e;
}

Expression *UnrolledLoopStatement::doInline(InlineDoState *ids)
{
    Expression *e = NULL;

    //printf("UnrolledLoopStatement::doInline() %d\n", statements->dim);
    for (size_t i = 0; i < statements->dim; i++)
    {	Statement *s = (Statement *) statements->data[i];
	if (s)
	{
	    Expression *e2 = s->doInline(ids);
	    e = Expression::combine(e, e2);
	    if (s->isReturnStatement())
		break;
	}
    }
    return e;
}

Expression *IfStatement::doInline(InlineDoState *ids)
{
    Expression *econd;
    Expression *e1;
    Expression *e2;
    Expression *e;

    assert(!arg);
    econd = condition->doInline(ids);
    assert(econd);
    if (ifbody)
	e1 = ifbody->doInline(ids);
    else
	e1 = NULL;
    if (elsebody)
	e2 = elsebody->doInline(ids);
    else
	e2 = NULL;
    if (e1 && e2)
    {
	e = new CondExp(econd->loc, econd, e1, e2);
	e->type = e1->type;
    }
    else if (e1)
    {
	e = new AndAndExp(econd->loc, econd, e1);
	e->type = Type::tvoid;
    }
    else if (e2)
    {
	e = new OrOrExp(econd->loc, econd, e2);
	e->type = Type::tvoid;
    }
    else
    {
	e = econd;
    }
    return e;
}

Expression *ReturnStatement::doInline(InlineDoState *ids)
{
    //printf("ReturnStatement::doInline() '%s'\n", exp ? exp->toChars() : "");
    return exp ? exp->doInline(ids) : 0;
}

/* --------------------------------------------------------------- */

/******************************
 * Perform doInline() on an array of Expressions.
 */

Expressions *arrayExpressiondoInline(Expressions *a, InlineDoState *ids)
{   Expressions *newa = NULL;

    if (a)
    {
	newa = new Expressions();
	newa->setDim(a->dim);

	for (int i = 0; i < a->dim; i++)
	{   Expression *e = (Expression *)a->data[i];

	    if (e)
	    {
		e = e->doInline(ids);
		newa->data[i] = (void *)e;
	    }
	}
    }
    return newa;
}

Expression *Expression::doInline(InlineDoState *ids)
{
    //printf("Expression::doInline(%s): %s\n", Token::toChars(op), toChars());
    return copy();
}

Expression *SymOffExp::doInline(InlineDoState *ids)
{
    int i;

    //printf("SymOffExp::doInline(%s)\n", toChars());
    for (i = 0; i < ids->from.dim; i++)
    {
	if (var == (Declaration *)ids->from.data[i])
	{
	    SymOffExp *se = (SymOffExp *)copy();

	    se->var = (Declaration *)ids->to.data[i];
	    return se;
	}
    }
    return this;
}

Expression *VarExp::doInline(InlineDoState *ids)
{
    int i;

    //printf("VarExp::doInline(%s)\n", toChars());
    for (i = 0; i < ids->from.dim; i++)
    {
	if (var == (Declaration *)ids->from.data[i])
	{
	    VarExp *ve = (VarExp *)copy();

	    ve->var = (Declaration *)ids->to.data[i];
	    return ve;
	}
    }
    return this;
}

Expression *ThisExp::doInline(InlineDoState *ids)
{
    //if (!ids->vthis)
	//error("no 'this' when inlining %s", ids->parent->toChars());
    if (!ids->vthis)
    {
	return this;
    }

    VarExp *ve = new VarExp(loc, ids->vthis);
    ve->type = type;
    return ve;
}

Expression *SuperExp::doInline(InlineDoState *ids)
{
    assert(ids->vthis);

    VarExp *ve = new VarExp(loc, ids->vthis);
    ve->type = type;
    return ve;
}

Expression *DeclarationExp::doInline(InlineDoState *ids)
{   DeclarationExp *de = (DeclarationExp *)copy();
    VarDeclaration *vd;

    //printf("DeclarationExp::doInline(%s)\n", toChars());
    vd = declaration->isVarDeclaration();
    if (vd)
    {
#if 0
	// Need to figure this out before inlining can work for tuples
	TupleDeclaration *td = vd->toAlias()->isTupleDeclaration();
	if (td)
	{
	    for (size_t i = 0; i < td->objects->dim; i++)
	    {   DsymbolExp *se = (DsymbolExp *)td->objects->data[i];
		assert(se->op == TOKdsymbol);
		se->s;
	    }
	    return st->objects->dim;
	}
#endif
	if (vd->isStatic() || vd->isConst())
	    ;
	else
	{
	    VarDeclaration *vto;

	    vto = new VarDeclaration(vd->loc, vd->type, vd->ident, vd->init);
	    *vto = *vd;
	    vto->parent = ids->parent;
	    vto->csym = NULL;
	    vto->isym = NULL;

	    ids->from.push(vd);
	    ids->to.push(vto);

	    if (vd->init)
	    {
		if (vd->init->isVoidInitializer())
		{
		    vto->init = new VoidInitializer(vd->init->loc);
		}
		else
		{
		    ExpInitializer *ie = vd->init->isExpInitializer();
		    assert(ie);
		    vto->init = new ExpInitializer(ie->loc, ie->exp->doInline(ids));
		}
	    }
	    de->declaration = (Dsymbol *) (void *)vto;
	}
    }
    /* This needs work, like DeclarationExp::toElem(), if we are
     * to handle TemplateMixin's. For now, we just don't inline them.
     */
    return de;
}

Expression *NewExp::doInline(InlineDoState *ids)
{
    //printf("NewExp::doInline(): %s\n", toChars());
    NewExp *ne = (NewExp *)copy();

    if (thisexp)
	ne->thisexp = thisexp->doInline(ids);
    ne->newargs = arrayExpressiondoInline(ne->newargs, ids);
    ne->arguments = arrayExpressiondoInline(ne->arguments, ids);
    return ne;
}

Expression *UnaExp::doInline(InlineDoState *ids)
{
    UnaExp *ue = (UnaExp *)copy();

    ue->e1 = e1->doInline(ids);
    return ue;
}

Expression *AssertExp::doInline(InlineDoState *ids)
{
    AssertExp *ae = (AssertExp *)copy();

    ae->e1 = e1->doInline(ids);
    if (msg)
	ae->msg = msg->doInline(ids);
    return ae;
}

Expression *BinExp::doInline(InlineDoState *ids)
{
    BinExp *be = (BinExp *)copy();

    be->e1 = e1->doInline(ids);
    be->e2 = e2->doInline(ids);
    return be;
}

Expression *CallExp::doInline(InlineDoState *ids)
{
    CallExp *ce;

    ce = (CallExp *)copy();
    ce->e1 = e1->doInline(ids);
    ce->arguments = arrayExpressiondoInline(arguments, ids);
    return ce;
}


Expression *IndexExp::doInline(InlineDoState *ids)
{
    IndexExp *are = (IndexExp *)copy();

    are->e1 = e1->doInline(ids);

    if (lengthVar)
    {	//printf("lengthVar\n");
	VarDeclaration *vd = lengthVar;
	ExpInitializer *ie;
	ExpInitializer *ieto;
	VarDeclaration *vto;

	vto = new VarDeclaration(vd->loc, vd->type, vd->ident, vd->init);
	*vto = *vd;
	vto->parent = ids->parent;
	vto->csym = NULL;
	vto->isym = NULL;

	ids->from.push(vd);
	ids->to.push(vto);

	if (vd->init)
	{
	    ie = vd->init->isExpInitializer();
	    assert(ie);
	    ieto = new ExpInitializer(ie->loc, ie->exp->doInline(ids));
	    vto->init = ieto;
	}

	are->lengthVar = (VarDeclaration *) (void *)vto;
    }
    are->e2 = e2->doInline(ids);
    return are;
}


Expression *SliceExp::doInline(InlineDoState *ids)
{
    SliceExp *are = (SliceExp *)copy();

    are->e1 = e1->doInline(ids);

    if (lengthVar)
    {	//printf("lengthVar\n");
	VarDeclaration *vd = lengthVar;
	ExpInitializer *ie;
	ExpInitializer *ieto;
	VarDeclaration *vto;

	vto = new VarDeclaration(vd->loc, vd->type, vd->ident, vd->init);
	*vto = *vd;
	vto->parent = ids->parent;
	vto->csym = NULL;
	vto->isym = NULL;

	ids->from.push(vd);
	ids->to.push(vto);

	if (vd->init)
	{
	    ie = vd->init->isExpInitializer();
	    assert(ie);
	    ieto = new ExpInitializer(ie->loc, ie->exp->doInline(ids));
	    vto->init = ieto;
	}

	are->lengthVar = (VarDeclaration *) (void *)vto;
    }
    if (lwr)
	are->lwr = lwr->doInline(ids);
    if (upr)
	are->upr = upr->doInline(ids);
    return are;
}


Expression *TupleExp::doInline(InlineDoState *ids)
{
    TupleExp *ce;

    ce = (TupleExp *)copy();
    ce->exps = arrayExpressiondoInline(exps, ids);
    return ce;
}


Expression *ArrayLiteralExp::doInline(InlineDoState *ids)
{
    ArrayLiteralExp *ce;

    ce = (ArrayLiteralExp *)copy();
    ce->elements = arrayExpressiondoInline(elements, ids);
    return ce;
}


Expression *AssocArrayLiteralExp::doInline(InlineDoState *ids)
{
    AssocArrayLiteralExp *ce;

    ce = (AssocArrayLiteralExp *)copy();
    ce->keys = arrayExpressiondoInline(keys, ids);
    ce->values = arrayExpressiondoInline(values, ids);
    return ce;
}


Expression *StructLiteralExp::doInline(InlineDoState *ids)
{
    StructLiteralExp *ce;

    ce = (StructLiteralExp *)copy();
    ce->elements = arrayExpressiondoInline(elements, ids);
    return ce;
}


Expression *ArrayExp::doInline(InlineDoState *ids)
{
    ArrayExp *ce;

    ce = (ArrayExp *)copy();
    ce->e1 = e1->doInline(ids);
    ce->arguments = arrayExpressiondoInline(arguments, ids);
    return ce;
}


Expression *CondExp::doInline(InlineDoState *ids)
{
    CondExp *ce = (CondExp *)copy();

    ce->econd = econd->doInline(ids);
    ce->e1 = e1->doInline(ids);
    ce->e2 = e2->doInline(ids);
    return ce;
}


/* ========== Walk the parse trees, and inline expand functions ============= */

/* Walk the trees, looking for functions to inline.
 * Inline any that can be.
 */

struct InlineScanState
{
    FuncDeclaration *fd;	// function being scanned
};

Statement *Statement::inlineScan(InlineScanState *iss)
{
    return this;
}

Statement *ExpStatement::inlineScan(InlineScanState *iss)
{
#if LOG
    printf("ExpStatement::inlineScan(%s)\n", toChars());
#endif
    if (exp)
	exp = exp->inlineScan(iss);
    return this;
}

Statement *CompoundStatement::inlineScan(InlineScanState *iss)
{
    for (size_t i = 0; i < statements->dim; i++)
    {	Statement *s = (Statement *) statements->data[i];
	if (s)
	    statements->data[i] = (void *)s->inlineScan(iss);
    }
    return this;
}

Statement *UnrolledLoopStatement::inlineScan(InlineScanState *iss)
{
    for (size_t i = 0; i < statements->dim; i++)
    {	Statement *s = (Statement *) statements->data[i];
	if (s)
	    statements->data[i] = (void *)s->inlineScan(iss);
    }
    return this;
}

Statement *ScopeStatement::inlineScan(InlineScanState *iss)
{
    if (statement)
	statement = statement->inlineScan(iss);
    return this;
}

Statement *WhileStatement::inlineScan(InlineScanState *iss)
{
    condition = condition->inlineScan(iss);
    body = body ? body->inlineScan(iss) : NULL;
    return this;
}


Statement *DoStatement::inlineScan(InlineScanState *iss)
{
    body = body ? body->inlineScan(iss) : NULL;
    condition = condition->inlineScan(iss);
    return this;
}


Statement *ForStatement::inlineScan(InlineScanState *iss)
{
    if (init)
	init = init->inlineScan(iss);
    if (condition)
	condition = condition->inlineScan(iss);
    if (increment)
	increment = increment->inlineScan(iss);
    body = body->inlineScan(iss);
    return this;
}


Statement *ForeachStatement::inlineScan(InlineScanState *iss)
{
    aggr = aggr->inlineScan(iss);
    if (body)
	body = body->inlineScan(iss);
    return this;
}


#if DMDV2
Statement *ForeachRangeStatement::inlineScan(InlineScanState *iss)
{
    lwr = lwr->inlineScan(iss);
    upr = upr->inlineScan(iss);
    if (body)
	body = body->inlineScan(iss);
    return this;
}
#endif


Statement *IfStatement::inlineScan(InlineScanState *iss)
{
    condition = condition->inlineScan(iss);
    if (ifbody)
	ifbody = ifbody->inlineScan(iss);
    if (elsebody)
	elsebody = elsebody->inlineScan(iss);
    return this;
}


Statement *SwitchStatement::inlineScan(InlineScanState *iss)
{
    //printf("SwitchStatement::inlineScan()\n");
    condition = condition->inlineScan(iss);
    body = body ? body->inlineScan(iss) : NULL;
    if (sdefault)
	sdefault = (DefaultStatement *)sdefault->inlineScan(iss);
    if (cases)
    {
	for (int i = 0; i < cases->dim; i++)
	{   Statement *s;

	    s = (Statement *) cases->data[i];
	    cases->data[i] = (void *)s->inlineScan(iss);
	}
    }
    return this;
}


Statement *CaseStatement::inlineScan(InlineScanState *iss)
{
    //printf("CaseStatement::inlineScan()\n");
    exp = exp->inlineScan(iss);
    if (statement)
	statement = statement->inlineScan(iss);
    return this;
}


Statement *DefaultStatement::inlineScan(InlineScanState *iss)
{
    if (statement)
	statement = statement->inlineScan(iss);
    return this;
}


Statement *ReturnStatement::inlineScan(InlineScanState *iss)
{
    if (exp)
	exp = exp->inlineScan(iss);
    return this;
}


Statement *SynchronizedStatement::inlineScan(InlineScanState *iss)
{
    if (exp)
	exp = exp->inlineScan(iss);
    if (body)
	body = body->inlineScan(iss);
    return this;
}


Statement *WithStatement::inlineScan(InlineScanState *iss)
{
    if (exp)
	exp = exp->inlineScan(iss);
    if (body)
	body = body->inlineScan(iss);
    return this;
}


Statement *TryCatchStatement::inlineScan(InlineScanState *iss)
{
    if (body)
	body = body->inlineScan(iss);
    if (catches)
    {
	for (int i = 0; i < catches->dim; i++)
	{   Catch *c = (Catch *)catches->data[i];

	    if (c->handler)
		c->handler = c->handler->inlineScan(iss);
	}
    }
    return this;
}


Statement *TryFinallyStatement::inlineScan(InlineScanState *iss)
{
    if (body)
	body = body->inlineScan(iss);
    if (finalbody)
	finalbody = finalbody->inlineScan(iss);
    return this;
}


Statement *ThrowStatement::inlineScan(InlineScanState *iss)
{
    if (exp)
	exp = exp->inlineScan(iss);
    return this;
}


Statement *VolatileStatement::inlineScan(InlineScanState *iss)
{
    if (statement)
	statement = statement->inlineScan(iss);
    return this;
}


Statement *LabelStatement::inlineScan(InlineScanState *iss)
{
    if (statement)
	statement = statement->inlineScan(iss);
    return this;
}

/* -------------------------- */

void arrayInlineScan(InlineScanState *iss, Array *arguments)
{
    if (arguments)
    {
	for (int i = 0; i < arguments->dim; i++)
	{   Expression *e = (Expression *)arguments->data[i];

	    if (e)
	    {
		e = e->inlineScan(iss);
		arguments->data[i] = (void *)e;
	    }
	}
    }
}

Expression *Expression::inlineScan(InlineScanState *iss)
{
    return this;
}

void scanVar(Dsymbol *s, InlineScanState *iss)
{
    VarDeclaration *vd = s->isVarDeclaration();
    if (vd)
    {
	TupleDeclaration *td = vd->toAlias()->isTupleDeclaration();
	if (td)
	{
	    for (size_t i = 0; i < td->objects->dim; i++)
	    {   DsymbolExp *se = (DsymbolExp *)td->objects->data[i];
		assert(se->op == TOKdsymbol);
		scanVar(se->s, iss);
	    }
	}
	else
	{
	    // Scan initializer (vd->init)
	    if (vd->init)
	    {
		ExpInitializer *ie = vd->init->isExpInitializer();

		if (ie)
		{
		    ie->exp = ie->exp->inlineScan(iss);
		}
	    }
	}
    }
}

Expression *DeclarationExp::inlineScan(InlineScanState *iss)
{
    //printf("DeclarationExp::inlineScan()\n");
    scanVar(declaration, iss);
    return this;
}

Expression *UnaExp::inlineScan(InlineScanState *iss)
{
    e1 = e1->inlineScan(iss);
    return this;
}

Expression *AssertExp::inlineScan(InlineScanState *iss)
{
    e1 = e1->inlineScan(iss);
    if (msg)
	msg = msg->inlineScan(iss);
    return this;
}

Expression *BinExp::inlineScan(InlineScanState *iss)
{
    e1 = e1->inlineScan(iss);
    e2 = e2->inlineScan(iss);
    return this;
}


Expression *CallExp::inlineScan(InlineScanState *iss)
{   Expression *e = this;

    //printf("CallExp::inlineScan()\n");
    e1 = e1->inlineScan(iss);
    arrayInlineScan(iss, arguments);

    if (e1->op == TOKvar)
    {
	VarExp *ve = (VarExp *)e1;
	FuncDeclaration *fd = ve->var->isFuncDeclaration();

	if (fd && fd != iss->fd && fd->canInline(0))
	{
	    e = fd->doInline(iss, NULL, arguments);
	}
    }
    else if (e1->op == TOKdotvar)
    {
	DotVarExp *dve = (DotVarExp *)e1;
	FuncDeclaration *fd = dve->var->isFuncDeclaration();

	if (fd && fd != iss->fd && fd->canInline(1))
	{
	    if (dve->e1->op == TOKcall &&
		dve->e1->type->toBasetype()->ty == Tstruct)
	    {
		/* To create ethis, we'll need to take the address
		 * of dve->e1, but this won't work if dve->e1 is
		 * a function call.
		 */
		;
	    }
	    else
		e = fd->doInline(iss, dve->e1, arguments);
	}
    }

    return e;
}


Expression *SliceExp::inlineScan(InlineScanState *iss)
{
    e1 = e1->inlineScan(iss);
    if (lwr)
	lwr = lwr->inlineScan(iss);
    if (upr)
	upr = upr->inlineScan(iss);
    return this;
}


Expression *TupleExp::inlineScan(InlineScanState *iss)
{   Expression *e = this;

    //printf("TupleExp::inlineScan()\n");
    arrayInlineScan(iss, exps);

    return e;
}


Expression *ArrayLiteralExp::inlineScan(InlineScanState *iss)
{   Expression *e = this;

    //printf("ArrayLiteralExp::inlineScan()\n");
    arrayInlineScan(iss, elements);

    return e;
}


Expression *AssocArrayLiteralExp::inlineScan(InlineScanState *iss)
{   Expression *e = this;

    //printf("AssocArrayLiteralExp::inlineScan()\n");
    arrayInlineScan(iss, keys);
    arrayInlineScan(iss, values);

    return e;
}


Expression *StructLiteralExp::inlineScan(InlineScanState *iss)
{   Expression *e = this;

    //printf("StructLiteralExp::inlineScan()\n");
    arrayInlineScan(iss, elements);

    return e;
}


Expression *ArrayExp::inlineScan(InlineScanState *iss)
{   Expression *e = this;

    //printf("ArrayExp::inlineScan()\n");
    e1 = e1->inlineScan(iss);
    arrayInlineScan(iss, arguments);

    return e;
}


Expression *CondExp::inlineScan(InlineScanState *iss)
{
    econd = econd->inlineScan(iss);
    e1 = e1->inlineScan(iss);
    e2 = e2->inlineScan(iss);
    return this;
}


/* ==========  =============== */

void FuncDeclaration::inlineScan()
{
    InlineScanState iss;

#if LOG
    printf("FuncDeclaration::inlineScan('%s')\n", toChars());
#endif
    memset(&iss, 0, sizeof(iss));
    iss.fd = this;
    if (fbody)
    {
	inlineNest++;
	fbody = fbody->inlineScan(&iss);
	inlineNest--;
    }
}

int FuncDeclaration::canInline(int hasthis, int hdrscan)
{
    InlineCostState ics;
    int cost;

#define CANINLINE_LOG 0

#if CANINLINE_LOG
    printf("FuncDeclaration::canInline(hasthis = %d, '%s')\n", hasthis, toChars());
#endif

    if (needThis() && !hasthis)
	return 0;

    if (inlineNest || (!semanticRun && !hdrscan))
    {
#if CANINLINE_LOG
	printf("\t1: no, inlineNest = %d, semanticRun = %d\n", inlineNest, semanticRun);
#endif
	return 0;
    }

    switch (inlineStatus)
    {
	case ILSyes:
#if CANINLINE_LOG
	    printf("\tyes\n");
#endif
	    return 1;

	case ILSno:
#if CANINLINE_LOG
	    printf("\t2: no\n");
#endif
	    return 0;

	case ILSuninitialized:
	    break;

	default:
	    assert(0);
    }

    if (type)
    {	assert(type->ty == Tfunction);
	TypeFunction *tf = (TypeFunction *)(type);
	if (tf->varargs == 1)	// no variadic parameter lists
	    goto Lno;

	/* Don't inline a function that returns non-void, but has
	 * no return expression.
	 */
	if (tf->next && tf->next->ty != Tvoid &&
	    !(hasReturnExp & 1) &&
	    !hdrscan)
	    goto Lno;
    }
    else
    {	CtorDeclaration *ctor = isCtorDeclaration();

	if (ctor && ctor->varargs == 1)
	    goto Lno;
    }

    if (
	!fbody ||
	!hdrscan &&
	(
#if 0
	isCtorDeclaration() ||	// cannot because need to convert:
				//	return;
				// to:
				//	return this;
#endif
	isSynchronized() ||
	isImportedSymbol() ||
#if DMDV2
	closureVars.dim ||	// no nested references to this frame
#else
	nestedFrameRef ||	// no nested references to this frame
#endif
	(isVirtual() && !isFinal())
       ))
    {
	goto Lno;
    }

    /* If any parameters are Tsarray's (which are passed by reference)
     * or out parameters (also passed by reference), don't do inlining.
     */
    if (parameters)
    {
	for (int i = 0; i < parameters->dim; i++)
	{
	    VarDeclaration *v = (VarDeclaration *)parameters->data[i];
	    if (v->isOut() || v->isRef() || v->type->toBasetype()->ty == Tsarray)
		goto Lno;
	}
    }

    memset(&ics, 0, sizeof(ics));
    ics.hasthis = hasthis;
    ics.fd = this;
    ics.hdrscan = hdrscan;
    cost = fbody->inlineCost(&ics);
#if CANINLINE_LOG
    printf("cost = %d\n", cost);
#endif
    if (cost >= COST_MAX)
	goto Lno;

    if (!hdrscan)    // Don't scan recursively for header content scan
	inlineScan();

Lyes:
    if (!hdrscan)    // Don't modify inlineStatus for header content scan
	inlineStatus = ILSyes;
#if CANINLINE_LOG
    printf("\tyes\n");
#endif
    return 1;

Lno:
    if (!hdrscan)    // Don't modify inlineStatus for header content scan
	inlineStatus = ILSno;
#if CANINLINE_LOG
    printf("\tno\n");
#endif
    return 0;
}

Expression *FuncDeclaration::doInline(InlineScanState *iss, Expression *ethis, Array *arguments)
{
    InlineDoState ids;
    DeclarationExp *de;
    Expression *e = NULL;

#if LOG
    printf("FuncDeclaration::doInline('%s')\n", toChars());
#endif

    memset(&ids, 0, sizeof(ids));
    ids.parent = iss->fd;

    // Set up vthis
    if (ethis)
    {
	VarDeclaration *vthis;
	ExpInitializer *ei;
	VarExp *ve;

	if (ethis->type->ty != Tclass && ethis->type->ty != Tpointer)
	{
	    ethis = ethis->addressOf(NULL);
	}

	ei = new ExpInitializer(ethis->loc, ethis);

	vthis = new VarDeclaration(ethis->loc, ethis->type, Id::This, ei);
	vthis->storage_class = STCin;
	vthis->linkage = LINKd;
	vthis->parent = iss->fd;

	ve = new VarExp(vthis->loc, vthis);
	ve->type = vthis->type;

	ei->exp = new AssignExp(vthis->loc, ve, ethis);
	ei->exp->type = ve->type;

	ids.vthis = vthis;
    }

    // Set up parameters
    if (ethis)
    {
	e = new DeclarationExp(0, ids.vthis);
	e->type = Type::tvoid;
    }

    if (arguments && arguments->dim)
    {
	assert(parameters->dim == arguments->dim);

	for (int i = 0; i < arguments->dim; i++)
	{
	    VarDeclaration *vfrom = (VarDeclaration *)parameters->data[i];
	    VarDeclaration *vto;
	    Expression *arg = (Expression *)arguments->data[i];
	    ExpInitializer *ei;
	    VarExp *ve;

	    ei = new ExpInitializer(arg->loc, arg);

	    vto = new VarDeclaration(vfrom->loc, vfrom->type, vfrom->ident, ei);
	    vto->storage_class |= vfrom->storage_class & (STCin | STCout | STClazy | STCref);
	    vto->linkage = vfrom->linkage;
	    vto->parent = iss->fd;
	    //printf("vto = '%s', vto->storage_class = x%x\n", vto->toChars(), vto->storage_class);
	    //printf("vto->parent = '%s'\n", iss->fd->toChars());

	    ve = new VarExp(vto->loc, vto);
	    //ve->type = vto->type;
	    ve->type = arg->type;

	    ei->exp = new AssignExp(vto->loc, ve, arg);
	    ei->exp->type = ve->type;
//ve->type->print();
//arg->type->print();
//ei->exp->print();

	    ids.from.push(vfrom);
	    ids.to.push(vto);

	    de = new DeclarationExp(0, vto);
	    de->type = Type::tvoid;

	    e = Expression::combine(e, de);
	}
    }

    inlineNest++;
    Expression *eb = fbody->doInline(&ids);
    inlineNest--;
//eb->type->print();
//eb->print();
//eb->dump(0);
    return Expression::combine(e, eb);
}