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/*
* Copyright (c) 2004-2005 The Regents of The University of Michigan
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Authors: Kevin Lim
*/
#include <vector>
#include "cpu/o3/rename_map.hh"
using namespace std;
// @todo: Consider making inline bool functions that determine if the
// register is a logical int, logical fp, physical int, physical fp,
// etc.
SimpleRenameMap::~SimpleRenameMap()
{
}
void
SimpleRenameMap::init(unsigned _numLogicalIntRegs,
unsigned _numPhysicalIntRegs,
PhysRegIndex &ireg_idx,
unsigned _numLogicalFloatRegs,
unsigned _numPhysicalFloatRegs,
PhysRegIndex &freg_idx,
unsigned _numMiscRegs,
RegIndex _intZeroReg,
RegIndex _floatZeroReg,
int map_id,
bool bindRegs)
{
id = map_id;
numLogicalIntRegs = _numLogicalIntRegs;
numLogicalFloatRegs = _numLogicalFloatRegs;
numPhysicalIntRegs = _numPhysicalIntRegs;
numPhysicalFloatRegs = _numPhysicalFloatRegs;
numMiscRegs = _numMiscRegs;
intZeroReg = _intZeroReg;
floatZeroReg = _floatZeroReg;
DPRINTF(Rename, "Creating rename map %i. Phys: %i / %i, Float: "
"%i / %i.\n", id, numLogicalIntRegs, numPhysicalIntRegs,
numLogicalFloatRegs, numPhysicalFloatRegs);
numLogicalRegs = numLogicalIntRegs + numLogicalFloatRegs;
numPhysicalRegs = numPhysicalIntRegs + numPhysicalFloatRegs;
//Create the rename maps
intRenameMap.resize(numLogicalIntRegs);
floatRenameMap.resize(numLogicalRegs);
if (bindRegs) {
DPRINTF(Rename, "Binding registers into rename map %i",id);
// Initialize the entries in the integer rename map to point to the
// physical registers of the same index
for (RegIndex index = 0; index < numLogicalIntRegs; ++index)
{
intRenameMap[index].physical_reg = ireg_idx++;
}
// Initialize the entries in the floating point rename map to point to
// the physical registers of the same index
// Although the index refers purely to architected registers, because
// the floating reg indices come after the integer reg indices, they
// may exceed the size of a normal RegIndex (short).
for (PhysRegIndex index = numLogicalIntRegs;
index < numLogicalRegs; ++index)
{
floatRenameMap[index].physical_reg = freg_idx++;
}
} else {
DPRINTF(Rename, "Binding registers into rename map %i",id);
PhysRegIndex temp_ireg = ireg_idx;
for (RegIndex index = 0; index < numLogicalIntRegs; ++index)
{
intRenameMap[index].physical_reg = temp_ireg++;
}
PhysRegIndex temp_freg = freg_idx;
for (PhysRegIndex index = numLogicalIntRegs;
index < numLogicalRegs; ++index)
{
floatRenameMap[index].physical_reg = temp_freg++;
}
}
}
void
SimpleRenameMap::setFreeList(SimpleFreeList *fl_ptr)
{
freeList = fl_ptr;
}
SimpleRenameMap::RenameInfo
SimpleRenameMap::rename(RegIndex arch_reg)
{
PhysRegIndex renamed_reg;
PhysRegIndex prev_reg;
if (arch_reg < numLogicalIntRegs) {
// Record the current physical register that is renamed to the
// requested architected register.
prev_reg = intRenameMap[arch_reg].physical_reg;
// If it's not referencing the zero register, then rename the
// register.
if (arch_reg != intZeroReg) {
renamed_reg = freeList->getIntReg();
intRenameMap[arch_reg].physical_reg = renamed_reg;
assert(renamed_reg >= 0 && renamed_reg < numPhysicalIntRegs);
} else {
// Otherwise return the zero register so nothing bad happens.
renamed_reg = intZeroReg;
}
} else if (arch_reg < numLogicalRegs) {
// Record the current physical register that is renamed to the
// requested architected register.
prev_reg = floatRenameMap[arch_reg].physical_reg;
// If it's not referencing the zero register, then rename the
// register.
if (arch_reg != floatZeroReg) {
renamed_reg = freeList->getFloatReg();
floatRenameMap[arch_reg].physical_reg = renamed_reg;
assert(renamed_reg < numPhysicalRegs &&
renamed_reg >= numPhysicalIntRegs);
} else {
// Otherwise return the zero register so nothing bad happens.
renamed_reg = floatZeroReg;
}
} else {
// Subtract off the base offset for miscellaneous registers.
arch_reg = arch_reg - numLogicalRegs;
DPRINTF(Rename, "Renamed misc reg %d\n", arch_reg);
// No renaming happens to the misc. registers. They are
// simply the registers that come after all the physical
// registers; thus take the base architected register and add
// the physical registers to it.
renamed_reg = arch_reg + numPhysicalRegs;
// Set the previous register to the same register; mainly it must be
// known that the prev reg was outside the range of normal registers
// so the free list can avoid adding it.
prev_reg = renamed_reg;
assert(renamed_reg < numPhysicalRegs + numMiscRegs);
}
DPRINTF(Rename, "Renamed reg %d to physical reg %d old mapping was %d\n",
arch_reg, renamed_reg, prev_reg);
return RenameInfo(renamed_reg, prev_reg);
}
PhysRegIndex
SimpleRenameMap::lookup(RegIndex arch_reg)
{
if (arch_reg < numLogicalIntRegs) {
return intRenameMap[arch_reg].physical_reg;
} else if (arch_reg < numLogicalRegs) {
return floatRenameMap[arch_reg].physical_reg;
} else {
// Subtract off the misc registers offset.
arch_reg = arch_reg - numLogicalRegs;
// Misc. regs don't rename, so simply add the base arch reg to
// the number of physical registers.
return numPhysicalRegs + arch_reg;
}
}
void
SimpleRenameMap::setEntry(RegIndex arch_reg, PhysRegIndex renamed_reg)
{
// In this implementation the miscellaneous registers do not
// actually rename, so this function does not allow you to try to
// change their mappings.
if (arch_reg < numLogicalIntRegs) {
DPRINTF(Rename, "Rename Map: Integer register %i being set to %i.\n",
(int)arch_reg, renamed_reg);
intRenameMap[arch_reg].physical_reg = renamed_reg;
} else if (arch_reg < numLogicalIntRegs + numLogicalFloatRegs) {
DPRINTF(Rename, "Rename Map: Float register %i being set to %i.\n",
(int)arch_reg - numLogicalIntRegs, renamed_reg);
floatRenameMap[arch_reg].physical_reg = renamed_reg;
}
}
int
SimpleRenameMap::numFreeEntries()
{
int free_int_regs = freeList->numFreeIntRegs();
int free_float_regs = freeList->numFreeFloatRegs();
if (free_int_regs < free_float_regs) {
return free_int_regs;
} else {
return free_float_regs;
}
}
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