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/*
* Copyright (c) 1999 by Mark Hill and David Wood for the Wisconsin
* Multifacet Project. ALL RIGHTS RESERVED.
*
* ##HEADER##
*
* This software is furnished under a license and may be used and
* copied only in accordance with the terms of such license and the
* inclusion of the above copyright notice. This software or any
* other copies thereof or any derivative works may not be provided or
* otherwise made available to any other persons. Title to and
* ownership of the software is retained by Mark Hill and David Wood.
* Any use of this software must include the above copyright notice.
*
* THIS SOFTWARE IS PROVIDED "AS IS". THE LICENSOR MAKES NO
* WARRANTIES ABOUT ITS CORRECTNESS OR PERFORMANCE.
* */
/*
* $Id$
*/
#ifndef ADDRESS_H
#define ADDRESS_H
#include <iomanip>
#include "mem/ruby/common/Global.hh"
#include "mem/ruby/config/RubyConfig.hh"
#include "mem/ruby/system/NodeID.hh"
#include "mem/ruby/system/MachineID.hh"
const int ADDRESS_WIDTH = 64; // address width in bytes
class Address;
typedef Address PhysAddress;
typedef Address VirtAddress;
class Address {
public:
// Constructors
Address() { m_address = 0; }
explicit Address(physical_address_t address) { m_address = address; }
Address(const Address& obj);
Address& operator=(const Address& obj);
// Destructor
// ~Address();
// Public Methods
void setAddress(physical_address_t address) { m_address = address; }
physical_address_t getAddress() const {return m_address;}
// selects bits inclusive
physical_address_t bitSelect(int small, int big) const;
physical_address_t maskLowOrderBits(int number) const;
physical_address_t maskHighOrderBits(int number) const;
physical_address_t shiftLowOrderBits(int number) const;
physical_address_t getLineAddress() const
{ return bitSelect(RubyConfig::dataBlockBits(), ADDRESS_WIDTH); }
physical_address_t getOffset() const
{ return bitSelect(0, RubyConfig::dataBlockBits()-1); }
void makeLineAddress() { m_address = maskLowOrderBits(RubyConfig::dataBlockBits()); }
// returns the next stride address based on line address
void makeNextStrideAddress( int stride) {
m_address = maskLowOrderBits(RubyConfig::dataBlockBits())
+ RubyConfig::dataBlockBytes()*stride;
}
void makePageAddress() { m_address = maskLowOrderBits(RubyConfig::pageSizeBits()); }
int getBankSetNum() const;
int getBankSetDist() const;
Index memoryModuleIndex() const;
void print(ostream& out) const;
void output(ostream& out) const;
void input(istream& in);
void setOffset( int offset ){
// first, zero out the offset bits
makeLineAddress();
m_address |= (physical_address_t) offset;
}
private:
// Private Methods
// Private copy constructor and assignment operator
// Address(const Address& obj);
// Address& operator=(const Address& obj);
// Data Members (m_ prefix)
physical_address_t m_address;
};
inline
Address line_address(const Address& addr) { Address temp(addr); temp.makeLineAddress(); return temp; }
inline
Address next_stride_address(const Address& addr, int stride) {
Address temp = addr;
temp.makeNextStrideAddress(stride);
temp.setAddress(temp.maskHighOrderBits(ADDRESS_WIDTH-RubyConfig::memorySizeBits())); // surpress wrap-around problem
return temp;
}
inline
Address page_address(const Address& addr) { Address temp(addr); temp.makePageAddress(); return temp; }
// Output operator declaration
ostream& operator<<(ostream& out, const Address& obj);
// comparison operator declaration
bool operator==(const Address& obj1, const Address& obj2);
bool operator!=(const Address& obj1, const Address& obj2);
bool operator<(const Address& obj1, const Address& obj2);
/* Address& operator=(const physical_address_t address); */
inline
bool operator<(const Address& obj1, const Address& obj2)
{
return obj1.getAddress() < obj2.getAddress();
}
// ******************* Definitions *******************
// Output operator definition
inline
ostream& operator<<(ostream& out, const Address& obj)
{
obj.print(out);
out << flush;
return out;
}
inline
bool operator==(const Address& obj1, const Address& obj2)
{
return (obj1.getAddress() == obj2.getAddress());
}
inline
bool operator!=(const Address& obj1, const Address& obj2)
{
return (obj1.getAddress() != obj2.getAddress());
}
inline
physical_address_t Address::bitSelect(int small, int big) const // rips bits inclusive
{
physical_address_t mask;
assert(big >= small);
if (big >= ADDRESS_WIDTH - 1) {
return (m_address >> small);
} else {
mask = ~((physical_address_t)~0 << (big + 1));
// FIXME - this is slow to manipulate a 64-bit number using 32-bits
physical_address_t partial = (m_address & mask);
return (partial >> small);
}
}
inline
physical_address_t Address::maskLowOrderBits(int number) const
{
physical_address_t mask;
if (number >= ADDRESS_WIDTH - 1) {
mask = ~0;
} else {
mask = (physical_address_t)~0 << number;
}
return (m_address & mask);
}
inline
physical_address_t Address::maskHighOrderBits(int number) const
{
physical_address_t mask;
if (number >= ADDRESS_WIDTH - 1) {
mask = ~0;
} else {
mask = (physical_address_t)~0 >> number;
}
return (m_address & mask);
}
inline
physical_address_t Address::shiftLowOrderBits(int number) const
{
return (m_address >> number);
}
inline
integer_t Address::memoryModuleIndex() const
{
integer_t index = bitSelect(RubyConfig::dataBlockBits()+RubyConfig::memoryBits(), ADDRESS_WIDTH);
assert (index >= 0);
if (index >= RubyConfig::memoryModuleBlocks()) {
cerr << " memoryBits: " << RubyConfig::memoryBits() << " memorySizeBits: " << RubyConfig::memorySizeBits()
<< " Address: " << "[" << hex << "0x" << m_address << "," << " line 0x" << maskLowOrderBits(RubyConfig::dataBlockBits()) << dec << "]" << flush
<< "error: limit exceeded. " <<
" dataBlockBits: " << RubyConfig::dataBlockBits() <<
" memoryModuleBlocks: " << RubyConfig::memoryModuleBlocks() <<
" index: " << index << endl;
}
assert (index < RubyConfig::memoryModuleBlocks());
return index;
// Index indexHighPortion = address.bitSelect(MEMORY_SIZE_BITS-1, PAGE_SIZE_BITS+NUMBER_OF_MEMORY_MODULE_BITS);
// Index indexLowPortion = address.bitSelect(DATA_BLOCK_BITS, PAGE_SIZE_BITS-1);
//Index index = indexLowPortion | (indexHighPortion << (PAGE_SIZE_BITS - DATA_BLOCK_BITS));
/*
Round-robin mapping of addresses, at page size granularity
ADDRESS_WIDTH MEMORY_SIZE_BITS PAGE_SIZE_BITS DATA_BLOCK_BITS
| | | |
\ / \ / \ / \ / 0
-----------------------------------------------------------------------
| unused |xxxxxxxxxxxxxxx| |xxxxxxxxxxxxxxx| |
| |xxxxxxxxxxxxxxx| |xxxxxxxxxxxxxxx| |
-----------------------------------------------------------------------
indexHighPortion indexLowPortion
<------->
NUMBER_OF_MEMORY_MODULE_BITS
*/
}
inline
void Address::print(ostream& out) const
{
out << "[" << hex << "0x" << m_address << "," << " line 0x" << maskLowOrderBits(RubyConfig::dataBlockBits()) << dec << "]" << flush;
}
class Address;
namespace __gnu_cxx {
template <> struct hash<Address>
{
size_t operator()(const Address &s) const { return (size_t) s.getAddress(); }
};
}
namespace std {
template <> struct equal_to<Address>
{
bool operator()(const Address& s1, const Address& s2) const { return s1 == s2; }
};
}
#endif //ADDRESS_H
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