-//===-- SparcRegClassInfo.cpp - Register class def'ns for Sparc -----------===//
+//===-- SparcV9RegClassInfo.cpp - Register class def'ns for SparcV9 -------===//
//
-// This file defines the register classes used by the Sparc target description.
+// The LLVM Compiler Infrastructure
+//
+// This file was developed by the LLVM research group and is distributed under
+// the University of Illinois Open Source License. See LICENSE.TXT for details.
+//
+//===----------------------------------------------------------------------===//
+//
+// This file defines the methods used by the SparcV9 register allocator
+// to pick registers of various classes. Most of this code should be
+// considered part of the register allocator.
//
//===----------------------------------------------------------------------===//
-#include "SparcRegClassInfo.h"
#include "llvm/Type.h"
-#include "../../CodeGen/RegAlloc/RegAllocCommon.h" // FIXME!
+#include "SparcV9RegClassInfo.h"
+#include "SparcV9Internals.h"
+#include "SparcV9RegInfo.h"
+#include "RegAlloc/RegAllocCommon.h"
+#include "RegAlloc/IGNode.h"
+#include <iostream>
+
+namespace llvm {
//-----------------------------------------------------------------------------
// Int Register Class - method for coloring a node in the interference graph.
// If there is call interf, try to allocate non-volatile. If that fails
// try to allocate a volatile and insert save across calls
// If both above fail, spill.
-//
+//
//-----------------------------------------------------------------------------
-void SparcIntRegClass::colorIGNode(IGNode * Node,
- std::vector<bool> &IsColorUsedArr) const
+void SparcV9IntRegClass::colorIGNode(IGNode * Node,
+ const std::vector<bool> &IsColorUsedArr) const
{
- LiveRange *LR = Node->getParentLR();
+ V9LiveRange *LR = Node->getParentLR();
- if (DEBUG_RA) {
- std::cerr << "\nColoring LR [CallInt=" << LR->isCallInterference() <<"]:";
- printSet(*LR);
- }
+ if (DEBUG_RA)
+ std::cerr << "\nColoring LR [CallInt=" << LR->isCallInterference() <<"]:"
+ << *LR << "\n";
if (LR->hasSuggestedColor()) {
unsigned SugCol = LR->getSuggestedColor();
std::cerr << "\n Couldn't alloc Sug col - LR volatile & calls interf";
}
} else if (DEBUG_RA) { // can't allocate the suggested col
- std::cerr << "\n Could NOT allocate the suggested color (already used) ";
- printSet(*LR); std::cerr << "\n";
+ std::cerr << "\n Could NOT allocate the suggested color (already used) "
+ << *LR << "\n";
}
}
bool ColorFound= false; // have we found a color yet?
//if this Node is between calls
- if (! LR->isCallInterference()) {
+ if (! LR->isCallInterference()) {
// start with volatiles (we can allocate volatiles safely)
- SearchStart = SparcIntRegClass::StartOfAllRegs;
- } else {
+ SearchStart = SparcV9IntRegClass::StartOfAllRegs;
+ } else {
// start with non volatiles (no non-volatiles)
- SearchStart = SparcIntRegClass::StartOfNonVolatileRegs;
+ SearchStart = SparcV9IntRegClass::StartOfNonVolatileRegs;
}
unsigned c=0; // color
-
+
// find first unused color
- for (c=SearchStart; c < SparcIntRegClass::NumOfAvailRegs; c++) {
+ for (c=SearchStart; c < SparcV9IntRegClass::NumOfAvailRegs; c++) {
if (!IsColorUsedArr[c]) {
ColorFound = true;
break;
}
if (ColorFound) {
- LR->setColor(c); // first color found in preffered order
+ LR->setColor(c); // first color found in preferred order
if (DEBUG_RA) std::cerr << "\n Colored after first search with col " << c;
}
//
else if (LR->isCallInterference()) {
// start from 0 - try to find even a volatile this time
- SearchStart = SparcIntRegClass::StartOfAllRegs;
+ SearchStart = SparcV9IntRegClass::StartOfAllRegs;
// find first unused volatile color
- for(c=SearchStart; c < SparcIntRegClass::StartOfNonVolatileRegs; c++) {
+ for(c=SearchStart; c < SparcV9IntRegClass::StartOfNonVolatileRegs; c++) {
if (! IsColorUsedArr[c]) {
ColorFound = true;
break;
}
}
- if (ColorFound) {
- LR->setColor(c);
+ if (ColorFound) {
+ LR->setColor(c);
// get the live range corresponding to live var
- // since LR span across calls, must save across calls
+ // since LR span across calls, must save across calls
//
- LR->markForSaveAcrossCalls();
if (DEBUG_RA)
std::cerr << "\n Colored after SECOND search with col " << c;
}
// If we couldn't find a color regardless of call interference - i.e., we
// don't have either a volatile or non-volatile color left
//
- if (!ColorFound)
+ if (!ColorFound)
LR->markForSpill(); // no color found - must spill
}
//
// Algorithm:
//
-// If the single int CC register is used (either as icc or xcc)
+// If (node has any interferences)
+// /* all interference operations can use only one register! */
// mark the LR for spilling
// else {
// if (the LR is a 64-bit comparison) use %xcc
// else /*32-bit or smaller*/ use %icc
// }
-//
+//
// Note: The third name (%ccr) is essentially an assembly mnemonic and
// depends solely on the opcode, so the name can be chosen in EmitAssembly.
//-----------------------------------------------------------------------------
-void SparcIntCCRegClass::colorIGNode(IGNode *Node,
- std::vector<bool> &IsColorUsedArr) const
+void SparcV9IntCCRegClass::colorIGNode(IGNode *Node,
+ const std::vector<bool> &IsColorUsedArr) const
{
- if (IsColorUsedArr[xcc] && IsColorUsedArr[icc])
+ if (Node->getNumOfNeighbors() > 0)
Node->getParentLR()->markForSpill();
- else {
- // Choose whether to use %xcc or %icc based on type of value compared
- const LiveRange* ccLR = Node->getParentLR();
- const Type* setCCType = (* ccLR->begin())->getType(); // any Value in LR
- assert(setCCType->isIntegral());
- int ccReg = (setCCType == Type::LongTy)? xcc : icc;
+
+ // Mark the appropriate register in any case (even if it needs to be spilled)
+ // because there is only one possible register, but more importantly, the
+ // spill algorithm cannot find it. In particular, we have to choose
+ // whether to use %xcc or %icc based on type of value compared
+ //
+ const V9LiveRange* ccLR = Node->getParentLR();
+ const Type* setCCType = (* ccLR->begin())->getType(); // any Value in LR
+ assert(setCCType->isIntegral() || isa<PointerType>(setCCType));
+ int ccReg = ((isa<PointerType>(setCCType) || setCCType == Type::LongTy)
+ ? xcc : icc);
#ifndef NDEBUG
- // Let's just make sure values of two different types have not been
- // coalesced into this LR.
- for (ValueSet::const_iterator I=ccLR->begin(), E=ccLR->end(); I != E; ++I)
- assert(setCCType->isIntegral() &&
- ((ccReg == xcc && (*I)->getType() == Type::LongTy) ||
- (ccReg == icc && (*I)->getType() != Type::LongTy))
- && "Comparisons needing different intCC regs coalesced in LR!");
+ // Let's just make sure values of two different types have not been
+ // coalesced into this LR.
+ for (V9LiveRange::const_iterator I=ccLR->begin(), E=ccLR->end(); I!=E; ++I) {
+ const Type* ccType = (*I)->getType();
+ assert((ccReg == xcc && (isa<PointerType>(ccType)
+ || ccType == Type::LongTy)) ||
+ (ccReg == icc && ccType->isIntegral() && ccType != Type::LongTy)
+ && "Comparisons needing different intCC regs coalesced in LR!");
+ }
#endif
- Node->setColor(ccReg); // only one int cc reg is available
- }
+ Node->setColor(ccReg); // only one int cc reg is available
+}
+
+
+void SparcV9FloatCCRegClass::colorIGNode(IGNode *Node,
+ const std::vector<bool> &IsColorUsedArr) const {
+ for(unsigned c = 0; c != 4; ++c)
+ if (!IsColorUsedArr[c]) { // find unused color
+ Node->setColor(c);
+ return;
+ }
+
+ Node->getParentLR()->markForSpill();
}
+
//-----------------------------------------------------------------------------
// Float Register Class - method for coloring a node in the interference graph.
//
// If a color is still not fond, mark for spilling
//
//----------------------------------------------------------------------------
-void SparcFloatRegClass::colorIGNode(IGNode * Node,
- std::vector<bool> &IsColorUsedArr) const
+void SparcV9FloatRegClass::colorIGNode(IGNode * Node,
+ const std::vector<bool> &IsColorUsedArr) const
{
- LiveRange *LR = Node->getParentLR();
+ V9LiveRange *LR = Node->getParentLR();
- // Mark the second color for double-precision registers:
- // This is UGLY and should be merged into nearly identical code
- // in RegClass::colorIGNode that handles the first color.
- //
+#ifndef NDEBUG
+ // Check that the correct colors have been are marked for fp-doubles.
+ //
+ // FIXME: This is old code that is no longer needed. Temporarily converting
+ // it into a big assertion just to check that the replacement logic
+ // (invoking SparcV9FloatRegClass::markColorsUsed() directly from
+ // RegClass::colorIGNode) works correctly.
+ //
+ // In fact, this entire function should be identical to
+ // SparcV9IntRegClass::colorIGNode(), and perhaps can be
+ // made into a general case in CodeGen/RegAlloc/RegClass.cpp.
+ //
unsigned NumNeighbors = Node->getNumOfNeighbors(); // total # of neighbors
- for(unsigned n=0; n < NumNeighbors; n++) { // for each neigh
+ for(unsigned n=0; n < NumNeighbors; n++) { // for each neigh
IGNode *NeighIGNode = Node->getAdjIGNode(n);
- LiveRange *NeighLR = NeighIGNode->getParentLR();
-
- if (NeighLR->hasColor() &&
- NeighLR->getType() == Type::DoubleTy) {
- IsColorUsedArr[ (NeighLR->getColor()) + 1 ] = true;
-
+ V9LiveRange *NeighLR = NeighIGNode->getParentLR();
+
+ if (NeighLR->hasColor()) {
+ assert(IsColorUsedArr[ NeighLR->getColor() ]);
+ if (NeighLR->getType() == Type::DoubleTy)
+ assert(IsColorUsedArr[ NeighLR->getColor()+1 ]);
+
} else if (NeighLR->hasSuggestedColor() &&
NeighLR-> isSuggestedColorUsable() ) {
- // if the neighbour can use the suggested color
- IsColorUsedArr[ NeighLR->getSuggestedColor() ] = true;
+ // if the neighbour can use the suggested color
+ assert(IsColorUsedArr[ NeighLR->getSuggestedColor() ]);
if (NeighLR->getType() == Type::DoubleTy)
- IsColorUsedArr[ (NeighLR->getSuggestedColor()) + 1 ] = true;
+ assert(IsColorUsedArr[ NeighLR->getSuggestedColor()+1 ]);
}
}
+#endif
// **NOTE: We don't check for call interferences in allocating suggested
// color in this class since ALL registers are volatile. If this fact
- // changes, we should change the following part
- //- see SparcIntRegClass::colorIGNode()
- //
+ // changes, we should change the following part
+ //- see SparcV9IntRegClass::colorIGNode()
+ //
if( LR->hasSuggestedColor() ) {
if( ! IsColorUsedArr[ LR->getSuggestedColor() ] ) {
LR->setColor( LR->getSuggestedColor() );
return;
} else if (DEBUG_RA) { // can't allocate the suggested col
- std::cerr << " Could NOT allocate the suggested color for LR ";
- printSet(*LR); std::cerr << "\n";
+ std::cerr << " Could NOT allocate the suggested color for LR " << *LR
+ << "\n";
}
}
// cannot go there. By doing that, we provide more space for singles
// in f0 - f31
//
- if (LR->getType() == Type::DoubleTy)
+ if (LR->getType() == Type::DoubleTy)
ColorFound = findFloatColor( LR, 32, 64, IsColorUsedArr );
if (ColorFound >= 0) { // if we could find a color
- LR->setColor(ColorFound);
+ LR->setColor(ColorFound);
return;
- } else {
+ } else {
- // if we didn't find a color becuase the LR was single precision or
+ // if we didn't find a color because the LR was single precision or
// all f32-f63 range is filled, we try to allocate a register from
- // the f0 - f31 region
+ // the f0 - f31 region
unsigned SearchStart; // start pos of color in pref-order
//if this Node is between calls (i.e., no call interferences )
if (! isCallInterf) {
// start with volatiles (we can allocate volatiles safely)
- SearchStart = SparcFloatRegClass::StartOfAllRegs;
+ SearchStart = SparcV9FloatRegClass::StartOfAllRegs;
} else {
// start with non volatiles (no non-volatiles)
- SearchStart = SparcFloatRegClass::StartOfNonVolatileRegs;
+ SearchStart = SparcV9FloatRegClass::StartOfNonVolatileRegs;
}
-
+
ColorFound = findFloatColor(LR, SearchStart, 32, IsColorUsedArr);
}
if (ColorFound >= 0) { // if we could find a color
- LR->setColor(ColorFound);
+ LR->setColor(ColorFound);
return;
- } else if (isCallInterf) {
+ } else if (isCallInterf) {
// We are here because there is a call interference and no non-volatile
// color could be found.
// Now try to allocate even a volatile color
- ColorFound = findFloatColor(LR, SparcFloatRegClass::StartOfAllRegs,
- SparcFloatRegClass::StartOfNonVolatileRegs,
+ ColorFound = findFloatColor(LR, SparcV9FloatRegClass::StartOfAllRegs,
+ SparcV9FloatRegClass::StartOfNonVolatileRegs,
IsColorUsedArr);
}
if (ColorFound >= 0) {
- LR->setColor(ColorFound); // first color found in prefered order
- LR->markForSaveAcrossCalls();
+ LR->setColor(ColorFound); // first color found in preferred order
} else {
// we are here because no color could be found
LR->markForSpill(); // no color found - must spill
}
}
+//-----------------------------------------------------------------------------
+// This method marks the registers used for a given register number.
+// This marks a single register for Float regs, but the R,R+1 pair
+// for double-precision registers.
+//-----------------------------------------------------------------------------
+
+void SparcV9FloatRegClass::markColorsUsed(unsigned RegInClass,
+ int UserRegType,
+ int RegTypeWanted,
+ std::vector<bool> &IsColorUsedArr) const
+{
+ if (UserRegType == SparcV9RegInfo::FPDoubleRegType ||
+ RegTypeWanted == SparcV9RegInfo::FPDoubleRegType) {
+ // This register is used as or is needed as a double-precision reg.
+ // We need to mark the [even,odd] pair corresponding to this reg.
+ // Get the even numbered register corresponding to this reg.
+ unsigned EvenRegInClass = RegInClass & ~1u;
+ assert(EvenRegInClass+1 < NumOfAllRegs &&
+ EvenRegInClass+1 < IsColorUsedArr.size());
+ IsColorUsedArr[EvenRegInClass] = true;
+ IsColorUsedArr[EvenRegInClass+1] = true;
+ }
+ else {
+ assert(RegInClass < NumOfAllRegs && RegInClass < IsColorUsedArr.size());
+ assert(UserRegType == RegTypeWanted
+ && "Something other than FP single/double types share a reg class?");
+ IsColorUsedArr[RegInClass] = true;
+ }
+}
+
+// This method finds unused registers of the specified register type,
+// using the given "used" flag array IsColorUsedArr. It checks a single
+// entry in the array directly for float regs, and checks the pair [R,R+1]
+// for double-precision registers
+// It returns -1 if no unused color is found.
+//
+int SparcV9FloatRegClass::findUnusedColor(int RegTypeWanted,
+ const std::vector<bool> &IsColorUsedArr) const
+{
+ if (RegTypeWanted == SparcV9RegInfo::FPDoubleRegType) {
+ unsigned NC = 2 * this->getNumOfAvailRegs();
+ assert(IsColorUsedArr.size() == NC && "Invalid colors-used array");
+ for (unsigned c = 0; c < NC; c+=2)
+ if (!IsColorUsedArr[c]) {
+ assert(!IsColorUsedArr[c+1] && "Incorrect used regs for FP double!");
+ return c;
+ }
+ return -1;
+ }
+ else
+ return TargetRegClassInfo::findUnusedColor(RegTypeWanted, IsColorUsedArr);
+}
//-----------------------------------------------------------------------------
// Helper method for coloring a node of Float Reg class.
// type of the Node (i.e., float/double)
//-----------------------------------------------------------------------------
-int SparcFloatRegClass::findFloatColor(const LiveRange *LR,
+int SparcV9FloatRegClass::findFloatColor(const V9LiveRange *LR,
unsigned Start,
- unsigned End,
- std::vector<bool> &IsColorUsedArr) const
+ unsigned End,
+ const std::vector<bool> &IsColorUsedArr) const
{
- bool ColorFound = false;
- unsigned c;
-
- if (LR->getType() == Type::DoubleTy) {
- // find first unused color for a double
- for (c=Start; c < End ; c+= 2)
- if (!IsColorUsedArr[c] && !IsColorUsedArr[c+1])
+ if (LR->getType() == Type::DoubleTy) {
+ // find first unused color for a double
+ assert(Start % 2 == 0 && "Odd register number could be used for double!");
+ for (unsigned c=Start; c < End ; c+= 2)
+ if (!IsColorUsedArr[c]) {
+ assert(!IsColorUsedArr[c+1] &&
+ "Incorrect marking of used regs for SparcV9 FP double!");
return c;
+ }
} else {
// find first unused color for a single
- for (c = Start; c < End; c++)
+ for (unsigned c = Start; c < End; c++)
if (!IsColorUsedArr[c])
return c;
}
-
+
return -1;
+
}
+
+} // End llvm namespace