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379 lines
12 KiB
C++
379 lines
12 KiB
C++
/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
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*
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* The contents of this file are subject to the Netscape Public
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* License Version 1.1 (the "License"); you may not use this file
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* except in compliance with the License. You may obtain a copy of
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* the License at http://www.mozilla.org/NPL/
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*
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* Software distributed under the License is distributed on an "AS
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* IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
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* implied. See the License for the specific language governing
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* rights and limitations under the License.
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*
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* The Original Code is mozilla.org code.
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*
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* The Initial Developer of the Original Code is Netscape
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* Communications Corporation. Portions created by Netscape are
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* Copyright (C) 1998 Netscape Communications Corporation. All
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* Rights Reserved.
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*
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* Contributor(s):
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*/
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// LinearInstructionScheduler.cpp
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//
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// Peter DeSantis 28 April 1997
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#include "Scheduler.h"
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#include "Vector.h"
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#include "ControlNodes.h"
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#include "Primitives.h"
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#include "DoublyLinkedList.h"
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#include "Instruction.h"
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void swapRootToEnd(Vector<RootPair>& inRoots, RootPair* inSwapToEnd);
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// schedule [no real purpose currently] FIX-ME
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// Calls the appropriate internal routine(s).
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void LinearInstructionScheduler::
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schedule(Vector<RootPair>& roots, ControlNode& controlNode)
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{
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linearSchedule(roots, controlNode);
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}
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// The primary goal of linear scheduling is to schedule all the instructions
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// which are derived from one line of src code one after another. There are numerous
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// ways to meet this objective. The simpliest method is to do a simple prioritived
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// topological sort of the control node. The priority is that from any node the
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// algorith follows the edges in increasing linenumber order. (Each instruction has
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// a line number associated with it which corresponds to src code line number.) As the
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// topological sort backtracks it inserts the instruction which it is leaving into
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// the list of instructions in the control node. The instructions have to be inserted
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// in an ordered fashion such that each new instruction is added at the end of the
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// section with the same associated line numbers. Currently this is done in the
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// simpliest n^2 fashion. If scheduling is determined to take significant time this
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// running time can be improved by using a binary search insertion routine.
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/*
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priorityTopoEmit
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does a priority topological sort of the instructions rooted at root and fills the
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controlnode's list ordered list of instructions.
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*/
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void LinearInstructionScheduler::
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priorityTopoEmit(Instruction* inInstruction, ControlNode& controlNode)
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{
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if (controlNode.haveScheduledInstruction(*inInstruction))
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return;
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InstructionUse* conditionCodeUse = NULL;
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InstructionUse* curUse;
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Instruction* curInstruction;
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for (curUse = inInstruction->getInstructionUseBegin();
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curUse < inInstruction->getInstructionUseEnd();
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curUse++)
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{
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if(curUse->kind == udCond)
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{
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assert(conditionCodeUse == NULL); // Instructions only allowed to use one condition code
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conditionCodeUse = curUse;
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} else {
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curInstruction = CodeGenerator::instructionUseToInstruction(*curUse);
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// Only need to schedule if it hasn't been scheduled and it is in coltrolNode
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if (curInstruction != NULL
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&& curInstruction->getPrimitive()->getContainer() == inInstruction->getPrimitive()->getContainer())
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{
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priorityTopoEmit(curInstruction, controlNode);
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}
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}
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}
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if(conditionCodeUse != NULL)
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{
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curInstruction = CodeGenerator::instructionUseToInstruction(*conditionCodeUse);
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if (curInstruction != NULL
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&& curInstruction->getPrimitive()->getContainer() == inInstruction->getPrimitive()->getContainer())
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{
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priorityTopoEmit(curInstruction, controlNode);
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}
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}
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// Now insert the instruction into the controlnodes list of instructions
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controlNode.addScheduledInstruction(*inInstruction);
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}
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// swapRootToEnd
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//
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// Swaps the passed in root to the end of the root vector
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void
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swapRootToEnd(Vector<RootPair>& inRoots, RootPair* inSwapToEnd)
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{
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RootPair oldRoot;
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RootPair* end = inRoots.end() - 1;
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oldRoot = *end;
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*end = *inSwapToEnd;
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*inSwapToEnd = oldRoot;
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}
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/*
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linearSchedule
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Does a prioritized linear search which fills in controlNode->instructions from the
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back to the front.
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*/
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void LinearInstructionScheduler::
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linearSchedule(Vector<RootPair>& roots, ControlNode& controlNode)
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{
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// FIX-ME move this stuff to the function that builds up roots
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if (controlNode.hasControlKind(ckReturn))
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{
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// Enforce the register allocator requirement that code emitted for
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// Result nodes be placed at the end of the block
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// The register allocator has no "global scope" uses, so basically it
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// would be sufficient to place the ExternalUse instruction emitted for
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// each Result node at the end, however we just go ahead and make sure
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// all of the code for a Result is last thing scheduled in a node.
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// Hopefully the register allocator will have globally scoped uses
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// in the future. FIX-ME.
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RootPair* curRoot;
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RootPair* resultRoot = NULL;
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// find poResult
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for (curRoot = roots.begin(); curRoot < roots.end(); curRoot++)
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if (curRoot->root->hasCategory(pcResult))
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{
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assert(!resultRoot); // verify there is only one Result node (is this true?)
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resultRoot = curRoot;
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#ifndef DEBUG
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break;
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#endif
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}
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// it is not necessary that there be a pcResult
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if (resultRoot)
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swapRootToEnd(roots, resultRoot);
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}
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else if (controlNode.hasControlKind(ckExc))
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{
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// Satisfy constraint that an exception producing primitive
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// must be the last excecuted in the ControlNode
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RootPair* curRoot;
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RootPair* exceptionRoot = NULL;
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// find poResult
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for (curRoot = roots.begin(); curRoot < roots.end(); curRoot++)
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if (curRoot->root->canRaiseException())
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{
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assert(!exceptionRoot); // verify there is only one exception generating root
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exceptionRoot = curRoot;
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#ifndef DEBUG
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break;
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#endif
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}
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assert(exceptionRoot);
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swapRootToEnd(roots, exceptionRoot);
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}
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renumberCN(roots, controlNode);
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RootPair* curRoot;
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Primitive* anchoredPrimitive;
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// take care of any anchored primitives last, so find out the anchored primitive
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if (controlNode.hasControlKind(ckIf) || controlNode.hasControlKind(ckSwitch))
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anchoredPrimitive = &controlNode.getControlPrimExtra();
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else
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anchoredPrimitive = NULL;
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//For each primary root, rum topologicalEmit
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for(curRoot = roots.begin(); curRoot < roots.end(); curRoot++)
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{
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if(curRoot->isPrimary && (curRoot->root != anchoredPrimitive))
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{
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if (curRoot->root->getInstructionRoot() != NULL)
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priorityTopoEmit(curRoot->root->getInstructionRoot(), controlNode);
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// FIX-ME no longer need curOutput
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DataNode* curOutput = curRoot->root;
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// although exception edges are not explicit
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// we need to consider them as real outgoing edges
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if ((curOutput->hasConsumers() || curOutput->canRaiseException()) && !curOutput->hasKind(vkVoid))
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{
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// now walk through all vr's assigned to this producer
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VirtualRegister* curVR;
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Instruction* nextInsn;
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switch (curOutput->getKind())
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{
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case vkCond:
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case vkMemory:
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nextInsn = curOutput->getInstructionAnnotation();
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if (nextInsn)
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priorityTopoEmit(nextInsn, controlNode);
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break;
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case vkLong:
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curVR = curOutput->getHighVirtualRegisterAnnotation();
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assert(curVR);
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nextInsn = curVR->getDefiningInstruction();
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if (nextInsn)
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priorityTopoEmit(nextInsn, controlNode);
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// FALL THROUGH for low vr
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case vkAddr:
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case vkInt:
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case vkFloat:
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case vkDouble:
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curVR = curOutput->getLowVirtualRegisterAnnotation();
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assert(curVR);
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nextInsn = curVR->getDefiningInstruction();
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if (nextInsn)
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priorityTopoEmit(nextInsn, controlNode);
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break;
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case vkTuple:
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case vkVoid:
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break;
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default:
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trespass("unknown or unhandled output");
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}
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}
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}
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}
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if (anchoredPrimitive)
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priorityTopoEmit(anchoredPrimitive->getInstructionRoot(), controlNode);
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}
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/*
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Compute the debugLineNumbers for each Primitive in the CN.
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The debugLineNumber assures that the stable sort will not invalidate the scheduled instruction
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ordering. Debug line numbers are the minimum integer values which maintain the following
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properties: lineNumber(P) <= debugLineNumber(P) and for every Primitive P' which
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defines an edge consumed by P, debugLineNumber(P) >= debugLineNumber(P').
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*/
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void LinearInstructionScheduler::
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renumberCN(Vector<RootPair>& roots, ControlNode& /*controlNode*/)
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{
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RootPair* curRoot;
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int rootsToRenumber = roots.size();
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int rootsRenumbered = 0;
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const DoublyLinkedList<DataConsumer>* consumers;
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DoublyLinkedList<DataConsumer> :: iterator curConsumer;
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// Initialize all root's renumberData
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for(curRoot = roots.begin(); curRoot < roots.end(); curRoot++)
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{
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if(curRoot->isPrimary)
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curRoot->data.renumbered = false;
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else {
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curRoot->data.renumbered = false;
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curRoot->data.timesVisited = 0;
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curRoot->data.neededVisits = 0;
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if (curRoot->root->getOutgoingEdgesEnd() > curRoot->root->getOutgoingEdgesBegin())
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{
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DataNode* curOutput;
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for (curOutput = curRoot->root->getOutgoingEdgesBegin();
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curOutput < curRoot->root->getOutgoingEdgesEnd();
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curOutput++)
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{
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consumers = &curOutput->getConsumers();
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for(curConsumer = consumers->begin(); !consumers->done(curConsumer);
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curConsumer = consumers->advance(curConsumer))
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curRoot->data.neededVisits++;
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}
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}
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}
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}
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// Renumber Primary Roots
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for(curRoot = roots.begin(); curRoot < roots.end(); curRoot++)
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{
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if(curRoot->isPrimary)
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{
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curRoot->root->setDebugLineNumber(curRoot->root->getLineNumber());
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renumberPrimitive(roots, *(curRoot->root));
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rootsRenumbered++;
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curRoot->data.renumbered = true;
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}
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}
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curRoot = roots.begin();
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while ( rootsRenumbered != rootsToRenumber )
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{
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while(curRoot->data.renumbered)
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{
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curRoot++;
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if(curRoot == roots.end())
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curRoot = roots.begin();
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}
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if(curRoot->data.timesVisited != curRoot->data.neededVisits)
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{
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renumberPrimitive(roots, *(curRoot->root));
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rootsRenumbered++;
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curRoot->data.renumbered = true;
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}
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curRoot++;
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if(curRoot == roots.end())
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curRoot = roots.begin();
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}
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}
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void LinearInstructionScheduler::
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renumberPrimitive(Vector<RootPair>& roots, Primitive& p)
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{
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DataConsumer* curConsumer;
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for (curConsumer = p.getInputsBegin();
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curConsumer < p.getInputsEnd();
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curConsumer++)
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{
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if(curConsumer->isVariable())
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{
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DataNode& possibleChild = curConsumer->getNode();
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if (!possibleChild.hasCategory(pcPhi))
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{
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Primitive &child = Primitive::cast(possibleChild);
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if(child.getDebugLineNumber() == 0)
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child.setDebugLineNumber(child.getLineNumber());
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if(child.getDebugLineNumber() < p.getDebugLineNumber())
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child.setDebugLineNumber(p.getDebugLineNumber());
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RootPair* curRoot;
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bool isRoot = false;
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for(curRoot = roots.begin(); curRoot < roots.end(); curRoot++)
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{
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if(curRoot->root == &child)
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{
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isRoot = true;
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curRoot->data.timesVisited++;
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break;
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}
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}
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if(!isRoot)
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renumberPrimitive(roots, child);
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}
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}
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}
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}
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