gem5/cpu/beta_cpu/rename_map.cc


#include "cpu/beta_cpu/rename_map.hh"

// Todo: Consider making functions inline.  Avoid having things that are
// using the zero register or misc registers from adding on the registers
// to the free list.

SimpleRenameMap::RenameEntry::RenameEntry()
    : physical_reg(0), valid(false)
{
}

SimpleRenameMap::SimpleRenameMap(unsigned _numLogicalIntRegs,
                                 unsigned _numPhysicalIntRegs,
                                 unsigned _numLogicalFloatRegs,
                                 unsigned _numPhysicalFloatRegs,
                                 unsigned _numMiscRegs,
                                 RegIndex _intZeroReg,
                                 RegIndex _floatZeroReg)
    : numLogicalIntRegs(_numLogicalIntRegs),
      numPhysicalIntRegs(_numPhysicalIntRegs),
      numLogicalFloatRegs(_numLogicalFloatRegs),
      numPhysicalFloatRegs(_numPhysicalFloatRegs),
      numMiscRegs(_numMiscRegs),
      intZeroReg(_intZeroReg),
      floatZeroReg(_floatZeroReg)
{
    DPRINTF(Rename, "Rename: Creating rename map.  Phys: %i / %i, Float: "
            "%i / %i.\n", numLogicalIntRegs, numPhysicalIntRegs,
            numLogicalFloatRegs, numPhysicalFloatRegs);

    numLogicalRegs = numLogicalIntRegs + numLogicalFloatRegs;

    numPhysicalRegs = numPhysicalIntRegs + numPhysicalFloatRegs;

    //Create the rename maps, and their scoreboards.
    intRenameMap = new RenameEntry[numLogicalIntRegs];
    floatRenameMap = new RenameEntry[numLogicalFloatRegs];

    intScoreboard.resize(numPhysicalIntRegs);
    floatScoreboard.resize(numPhysicalFloatRegs);
    miscScoreboard.resize(numMiscRegs);

    // Initialize the entries in the integer rename map to point to the
    // physical registers of the same index, and consider each register
    // ready until the first rename occurs.
    for (RegIndex index = 0; index < numLogicalIntRegs; ++index)
    {
        intRenameMap[index].physical_reg = index;
        intScoreboard[index] = 1;
    }

    // Initialize the rest of the physical registers (the ones that don't
    // directly map to a logical register) as unready.
    for (PhysRegIndex index = numLogicalIntRegs;
         index < numPhysicalIntRegs;
         ++index)
    {
        intScoreboard[index] = 0;
    }

    // Initialize the entries in the floating point rename map to point to
    // the physical registers of the same index, and consider each register
    // ready until the first rename occurs.
    for (RegIndex index = 0; index < numLogicalFloatRegs; ++index)
    {
        floatRenameMap[index].physical_reg = index + numPhysicalIntRegs;
        floatScoreboard[index] = 1;
    }

    // Initialize the rest of the physical registers (the ones that don't
    // directly map to a logical register) as unready.
    for (PhysRegIndex index = numLogicalFloatRegs;
         index < numPhysicalFloatRegs;
         ++index)
    {
        floatScoreboard[index] = 0;
    }

    // Initialize the entries in the misc register scoreboard to be ready.
    for (RegIndex index = 0; index < numMiscRegs; ++index)
    {
        miscScoreboard[index] = 1;
    }
}

void
SimpleRenameMap::setFreeList(SimpleFreeList *fl_ptr)
{
    //Setup the interface to the freelist.
    freeList = fl_ptr;
}


// Don't allow this stage to fault; force that check to the rename stage.
// Simply ask to rename a logical register and get back a new physical
// register index.
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 mark the register
        // as not ready.
        if (arch_reg != intZeroReg) {
            // Get a free physical register to rename to.
            renamed_reg = freeList->getIntReg();

            // Update the integer rename map.
            intRenameMap[arch_reg].physical_reg = renamed_reg;

            // Mark register as not ready.
            intScoreboard[renamed_reg] = false;
        } else {
            // Otherwise return the zero register so nothing bad happens.
            renamed_reg = intZeroReg;
        }
    } else if (arch_reg < numLogicalRegs) {
        // Subtract off the base offset for floating point registers.
        arch_reg = arch_reg - numLogicalIntRegs;

        // 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 mark the register
        // as not ready.
        if (arch_reg != floatZeroReg) {
            // Get a free floating point register to rename to.
            renamed_reg = freeList->getFloatReg();

            // Update the floating point rename map.
            floatRenameMap[arch_reg].physical_reg = renamed_reg;

            // Mark register as not ready.
            floatScoreboard[renamed_reg] = false;
        } 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;

        // 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;

        miscScoreboard[renamed_reg] = false;
    }

    return RenameInfo(renamed_reg, prev_reg);
}

//Perhaps give this a pair as a return value, of the physical register
//and whether or not it's ready.
PhysRegIndex
SimpleRenameMap::lookup(RegIndex arch_reg)
{
    if (arch_reg < numLogicalIntRegs) {
        return intRenameMap[arch_reg].physical_reg;
    } else if (arch_reg < numLogicalRegs) {
        // Subtract off the base FP offset.
        arch_reg = arch_reg - numLogicalIntRegs;

        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;
    }
}

bool
SimpleRenameMap::isReady(PhysRegIndex phys_reg)
{
    if (phys_reg < numPhysicalIntRegs) {
        return intScoreboard[phys_reg];
    } else if (phys_reg < numPhysicalRegs) {

        // Subtract off the base FP offset.
        phys_reg = phys_reg - numPhysicalIntRegs;

        return floatScoreboard[phys_reg];
    } else {
        // Subtract off the misc registers offset.
        phys_reg = phys_reg - numPhysicalRegs;

        return miscScoreboard[phys_reg];
    }
}

// In this implementation the miscellaneous registers do not actually rename,
// so this function does not allow you to try to change their mappings.
void
SimpleRenameMap::setEntry(RegIndex arch_reg, PhysRegIndex renamed_reg)
{
    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 {
//        assert(arch_reg < (numLogicalIntRegs + numLogicalFloatRegs));

        // Subtract off the base FP offset.
        arch_reg = arch_reg - numLogicalIntRegs;

        DPRINTF(Rename, "Rename Map: Float register %i being set to %i.\n",
                (int)arch_reg, renamed_reg);

        floatRenameMap[arch_reg].physical_reg = renamed_reg;
    }
}

void
SimpleRenameMap::squash(vector<RegIndex> freed_regs,
                        vector<UnmapInfo> unmaps)
{
    // Not sure the rename map should be able to access the free list
    // like this.
    while (!freed_regs.empty()) {
        RegIndex free_register = freed_regs.back();

        if (free_register < numPhysicalIntRegs) {
            freeList->addIntReg(free_register);
        } else {
            // Subtract off the base FP dependence tag.
            free_register = free_register - numPhysicalIntRegs;
            freeList->addFloatReg(free_register);
        }

        freed_regs.pop_back();
    }

    // Take unmap info and roll back the rename map.
}

void
SimpleRenameMap::markAsReady(PhysRegIndex ready_reg)
{
    DPRINTF(Rename, "Rename map: Marking register %i as ready.\n",
            (int)ready_reg);

    if (ready_reg < numPhysicalIntRegs) {
        intScoreboard[ready_reg] = 1;
    } else if (ready_reg < numPhysicalRegs) {

        // Subtract off the base FP offset.
        ready_reg = ready_reg - numPhysicalIntRegs;

        floatScoreboard[ready_reg] = 1;
    } else {
        //Subtract off the misc registers offset.
        ready_reg = ready_reg - numPhysicalRegs;

        miscScoreboard[ready_reg] = 1;
    }
}

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;
    }
}
Check in of new CPU. This checkin works under non-Fullsystem mode, with no caches. SConscript: Added new CPU files to build. arch/alpha/isa_desc: Changed rduniq and wruniq to be nonspeculative because the uniq register is not renamed. arch/isa_parser.py: Added new CPU exec method. base/statistics.hh: Minor change for namespace conflict. Probably can change back one the new CPU files are cleaned up. base/traceflags.py: Added new CPU trace flags. cpu/static_inst.hh: Changed static inst to use a file that defines the execute functions. --HG-- extra : convert_revision : bd4ce34361308280168324817fc1258dd253e519 2004-08-20 20:54:07 +02:00
			`#include "cpu/beta_cpu/rename_map.hh"`

			`// Todo: Consider making functions inline. Avoid having things that are`
			`// using the zero register or misc registers from adding on the registers`
			`// to the free list.`

			`SimpleRenameMap::RenameEntry::RenameEntry()`
			`: physical_reg(0), valid(false)`
			`{`
			`}`

			`SimpleRenameMap::SimpleRenameMap(unsigned _numLogicalIntRegs,`
			`unsigned _numPhysicalIntRegs,`
			`unsigned _numLogicalFloatRegs,`
			`unsigned _numPhysicalFloatRegs,`
			`unsigned _numMiscRegs,`
			`RegIndex _intZeroReg,`
			`RegIndex _floatZeroReg)`
			`: numLogicalIntRegs(_numLogicalIntRegs),`
			`numPhysicalIntRegs(_numPhysicalIntRegs),`
			`numLogicalFloatRegs(_numLogicalFloatRegs),`
			`numPhysicalFloatRegs(_numPhysicalFloatRegs),`
			`numMiscRegs(_numMiscRegs),`
			`intZeroReg(_intZeroReg),`
			`floatZeroReg(_floatZeroReg)`
			`{`
			`DPRINTF(Rename, "Rename: Creating rename map. Phys: %i / %i, Float: "`
			`"%i / %i.\n", numLogicalIntRegs, numPhysicalIntRegs,`
			`numLogicalFloatRegs, numPhysicalFloatRegs);`

			`numLogicalRegs = numLogicalIntRegs + numLogicalFloatRegs;`

			`numPhysicalRegs = numPhysicalIntRegs + numPhysicalFloatRegs;`

			`//Create the rename maps, and their scoreboards.`
			`intRenameMap = new RenameEntry[numLogicalIntRegs];`
			`floatRenameMap = new RenameEntry[numLogicalFloatRegs];`

			`intScoreboard.resize(numPhysicalIntRegs);`
			`floatScoreboard.resize(numPhysicalFloatRegs);`
			`miscScoreboard.resize(numMiscRegs);`

			`// Initialize the entries in the integer rename map to point to the`
			`// physical registers of the same index, and consider each register`
			`// ready until the first rename occurs.`
			`for (RegIndex index = 0; index < numLogicalIntRegs; ++index)`
			`{`
			`intRenameMap[index].physical_reg = index;`
			`intScoreboard[index] = 1;`
			`}`

			`// Initialize the rest of the physical registers (the ones that don't`
			`// directly map to a logical register) as unready.`
			`for (PhysRegIndex index = numLogicalIntRegs;`
			`index < numPhysicalIntRegs;`
			`++index)`
			`{`
			`intScoreboard[index] = 0;`
			`}`

			`// Initialize the entries in the floating point rename map to point to`
			`// the physical registers of the same index, and consider each register`
			`// ready until the first rename occurs.`
			`for (RegIndex index = 0; index < numLogicalFloatRegs; ++index)`
			`{`
			`floatRenameMap[index].physical_reg = index + numPhysicalIntRegs;`
			`floatScoreboard[index] = 1;`
			`}`

			`// Initialize the rest of the physical registers (the ones that don't`
			`// directly map to a logical register) as unready.`
			`for (PhysRegIndex index = numLogicalFloatRegs;`
			`index < numPhysicalFloatRegs;`
			`++index)`
			`{`
			`floatScoreboard[index] = 0;`
			`}`

			`// Initialize the entries in the misc register scoreboard to be ready.`
			`for (RegIndex index = 0; index < numMiscRegs; ++index)`
			`{`
			`miscScoreboard[index] = 1;`
			`}`
			`}`

			`void`
			`SimpleRenameMap::setFreeList(SimpleFreeList *fl_ptr)`
			`{`
			`//Setup the interface to the freelist.`
			`freeList = fl_ptr;`
			`}`


			`// Don't allow this stage to fault; force that check to the rename stage.`
			`// Simply ask to rename a logical register and get back a new physical`
			`// register index.`
			`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 mark the register`
			`// as not ready.`
			`if (arch_reg != intZeroReg) {`
			`// Get a free physical register to rename to.`
			`renamed_reg = freeList->getIntReg();`

			`// Update the integer rename map.`
			`intRenameMap[arch_reg].physical_reg = renamed_reg;`

			`// Mark register as not ready.`
			`intScoreboard[renamed_reg] = false;`
			`} else {`
			`// Otherwise return the zero register so nothing bad happens.`
			`renamed_reg = intZeroReg;`
			`}`
			`} else if (arch_reg < numLogicalRegs) {`
			`// Subtract off the base offset for floating point registers.`
			`arch_reg = arch_reg - numLogicalIntRegs;`

			`// 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 mark the register`
			`// as not ready.`
			`if (arch_reg != floatZeroReg) {`
			`// Get a free floating point register to rename to.`
			`renamed_reg = freeList->getFloatReg();`

			`// Update the floating point rename map.`
			`floatRenameMap[arch_reg].physical_reg = renamed_reg;`

			`// Mark register as not ready.`
			`floatScoreboard[renamed_reg] = false;`
			`} 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;`

			`// 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;`

			`miscScoreboard[renamed_reg] = false;`
			`}`

			`return RenameInfo(renamed_reg, prev_reg);`
			`}`

			`//Perhaps give this a pair as a return value, of the physical register`
			`//and whether or not it's ready.`
			`PhysRegIndex`
			`SimpleRenameMap::lookup(RegIndex arch_reg)`
			`{`
			`if (arch_reg < numLogicalIntRegs) {`
			`return intRenameMap[arch_reg].physical_reg;`
			`} else if (arch_reg < numLogicalRegs) {`
			`// Subtract off the base FP offset.`
			`arch_reg = arch_reg - numLogicalIntRegs;`

			`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;`
			`}`
			`}`

			`bool`
			`SimpleRenameMap::isReady(PhysRegIndex phys_reg)`
			`{`
			`if (phys_reg < numPhysicalIntRegs) {`
			`return intScoreboard[phys_reg];`
			`} else if (phys_reg < numPhysicalRegs) {`

			`// Subtract off the base FP offset.`
			`phys_reg = phys_reg - numPhysicalIntRegs;`

			`return floatScoreboard[phys_reg];`
			`} else {`
			`// Subtract off the misc registers offset.`
			`phys_reg = phys_reg - numPhysicalRegs;`

			`return miscScoreboard[phys_reg];`
			`}`
			`}`

			`// In this implementation the miscellaneous registers do not actually rename,`
			`// so this function does not allow you to try to change their mappings.`
			`void`
			`SimpleRenameMap::setEntry(RegIndex arch_reg, PhysRegIndex renamed_reg)`
			`{`
			`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 {`
			`// assert(arch_reg < (numLogicalIntRegs + numLogicalFloatRegs));`

			`// Subtract off the base FP offset.`
			`arch_reg = arch_reg - numLogicalIntRegs;`

			`DPRINTF(Rename, "Rename Map: Float register %i being set to %i.\n",`
			`(int)arch_reg, renamed_reg);`

			`floatRenameMap[arch_reg].physical_reg = renamed_reg;`
			`}`
			`}`

			`void`
			`SimpleRenameMap::squash(vector<RegIndex> freed_regs,`
			`vector<UnmapInfo> unmaps)`
			`{`
			`// Not sure the rename map should be able to access the free list`
			`// like this.`
			`while (!freed_regs.empty()) {`
			`RegIndex free_register = freed_regs.back();`

			`if (free_register < numPhysicalIntRegs) {`
			`freeList->addIntReg(free_register);`
			`} else {`
			`// Subtract off the base FP dependence tag.`
			`free_register = free_register - numPhysicalIntRegs;`
			`freeList->addFloatReg(free_register);`
			`}`

			`freed_regs.pop_back();`
			`}`

			`// Take unmap info and roll back the rename map.`
			`}`

			`void`
			`SimpleRenameMap::markAsReady(PhysRegIndex ready_reg)`
			`{`
			`DPRINTF(Rename, "Rename map: Marking register %i as ready.\n",`
			`(int)ready_reg);`

			`if (ready_reg < numPhysicalIntRegs) {`
			`intScoreboard[ready_reg] = 1;`
			`} else if (ready_reg < numPhysicalRegs) {`

			`// Subtract off the base FP offset.`
			`ready_reg = ready_reg - numPhysicalIntRegs;`

			`floatScoreboard[ready_reg] = 1;`
			`} else {`
			`//Subtract off the misc registers offset.`
			`ready_reg = ready_reg - numPhysicalRegs;`

			`miscScoreboard[ready_reg] = 1;`
			`}`
			`}`

			`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;`
			`}`
			`}`