#include <string>
#include "arch/isa_traits.hh"
+#include "arch/utility.hh"
#include "sim/faults.hh"
#include "base/bitfield.hh"
#include "base/hashmap.hh"
#include "base/misc.hh"
#include "base/refcnt.hh"
#include "cpu/op_class.hh"
-#include "cpu/o3/dyn_inst.hh"
#include "sim/faults.hh"
#include "sim/host.hh"
class DynInst;
class Packet;
-template <class Impl>
-class OzoneDynInst;
+class O3CPUImpl;
+template <class Impl> class BaseO3DynInst;
+typedef BaseO3DynInst<O3CPUImpl> O3DynInst;
+template <class Impl> class OzoneDynInst;
+class InOrderDynInst;
class CheckerCPU;
class FastCPU;
class TimingSimpleCPU;
class InorderCPU;
class SymbolTable;
+class AddrDecodePage;
namespace Trace {
class InstRecord;
}
-typedef uint32_t MicroPC;
+typedef uint16_t MicroPC;
+
+static const MicroPC MicroPCRomBit = 1 << (sizeof(MicroPC) * 8 - 1);
+
+static inline MicroPC
+romMicroPC(MicroPC upc)
+{
+ return upc | MicroPCRomBit;
+}
+
+static inline MicroPC
+normalMicroPC(MicroPC upc)
+{
+ return upc & ~MicroPCRomBit;
+}
+
+static inline bool
+isRomMicroPC(MicroPC upc)
+{
+ return MicroPCRomBit & upc;
+}
/**
* Base, ISA-independent static instruction class.
/// implement this behavior via the execute() methods.
///
enum Flags {
- IsNop, ///< Is a no-op (no effect at all).
+ IsNop, ///< Is a no-op (no effect at all).
- IsInteger, ///< References integer regs.
- IsFloating, ///< References FP regs.
+ IsInteger, ///< References integer regs.
+ IsFloating, ///< References FP regs.
- IsMemRef, ///< References memory (load, store, or prefetch).
- IsLoad, ///< Reads from memory (load or prefetch).
- IsStore, ///< Writes to memory.
+ IsMemRef, ///< References memory (load, store, or prefetch).
+ IsLoad, ///< Reads from memory (load or prefetch).
+ IsStore, ///< Writes to memory.
IsStoreConditional, ///< Store conditional instruction.
- IsInstPrefetch, ///< Instruction-cache prefetch.
- IsDataPrefetch, ///< Data-cache prefetch.
+ IsIndexed, ///< Accesses memory with an indexed address computation
+ IsInstPrefetch, ///< Instruction-cache prefetch.
+ IsDataPrefetch, ///< Data-cache prefetch.
IsCopy, ///< Fast Cache block copy
- IsControl, ///< Control transfer instruction.
- IsDirectControl, ///< PC relative control transfer.
- IsIndirectControl, ///< Register indirect control transfer.
- IsCondControl, ///< Conditional control transfer.
- IsUncondControl, ///< Unconditional control transfer.
- IsCall, ///< Subroutine call.
- IsReturn, ///< Subroutine return.
+ IsControl, ///< Control transfer instruction.
+ IsDirectControl, ///< PC relative control transfer.
+ IsIndirectControl, ///< Register indirect control transfer.
+ IsCondControl, ///< Conditional control transfer.
+ IsUncondControl, ///< Unconditional control transfer.
+ IsCall, ///< Subroutine call.
+ IsReturn, ///< Subroutine return.
IsCondDelaySlot,///< Conditional Delay-Slot Instruction
- IsThreadSync, ///< Thread synchronization operation.
+ IsThreadSync, ///< Thread synchronization operation.
- IsSerializing, ///< Serializes pipeline: won't execute until all
+ IsSerializing, ///< Serializes pipeline: won't execute until all
/// older instructions have committed.
IsSerializeBefore,
IsSerializeAfter,
- IsMemBarrier, ///< Is a memory barrier
- IsWriteBarrier, ///< Is a write barrier
+ IsMemBarrier, ///< Is a memory barrier
+ IsWriteBarrier, ///< Is a write barrier
+ IsERET, /// <- Causes the IFU to stall (MIPS ISA)
IsNonSpeculative, ///< Should not be executed speculatively
IsQuiesce, ///< Is a quiesce instruction
IsIprAccess, ///< Accesses IPRs
IsUnverifiable, ///< Can't be verified by a checker
+ IsSyscall, ///< Causes a system call to be emulated in syscall
+ /// emulation mode.
+
//Flags for microcode
- IsMacroOp, ///< Is a macroop containing microops
- IsMicroOp, ///< Is a microop
- IsDelayedCommit, ///< This microop doesn't commit right away
- IsLastMicroOp, ///< This microop ends a microop sequence
- IsFirstMicroOp, ///< This microop begins a microop sequence
+ IsMacroop, ///< Is a macroop containing microops
+ IsMicroop, ///< Is a microop
+ IsDelayedCommit, ///< This microop doesn't commit right away
+ IsLastMicroop, ///< This microop ends a microop sequence
+ IsFirstMicroop, ///< This microop begins a microop sequence
//This flag doesn't do anything yet
- IsMicroBranch, ///< This microop branches within the microcode for a macroop
+ IsMicroBranch, ///< This microop branches within the microcode for a macroop
+ IsDspOp,
NumFlags
};
/// of the individual flags.
//@{
- bool isNop() const { return flags[IsNop]; }
+ bool isNop() const { return flags[IsNop]; }
- bool isMemRef() const { return flags[IsMemRef]; }
- bool isLoad() const { return flags[IsLoad]; }
- bool isStore() const { return flags[IsStore]; }
- bool isStoreConditional() const { return flags[IsStoreConditional]; }
+ bool isMemRef() const { return flags[IsMemRef]; }
+ bool isLoad() const { return flags[IsLoad]; }
+ bool isStore() const { return flags[IsStore]; }
+ bool isStoreConditional() const { return flags[IsStoreConditional]; }
bool isInstPrefetch() const { return flags[IsInstPrefetch]; }
bool isDataPrefetch() const { return flags[IsDataPrefetch]; }
bool isCopy() const { return flags[IsCopy];}
- bool isInteger() const { return flags[IsInteger]; }
- bool isFloating() const { return flags[IsFloating]; }
+ bool isInteger() const { return flags[IsInteger]; }
+ bool isFloating() const { return flags[IsFloating]; }
- bool isControl() const { return flags[IsControl]; }
- bool isCall() const { return flags[IsCall]; }
- bool isReturn() const { return flags[IsReturn]; }
- bool isDirectCtrl() const { return flags[IsDirectControl]; }
+ bool isControl() const { return flags[IsControl]; }
+ bool isCall() const { return flags[IsCall]; }
+ bool isReturn() const { return flags[IsReturn]; }
+ bool isDirectCtrl() const { return flags[IsDirectControl]; }
bool isIndirectCtrl() const { return flags[IsIndirectControl]; }
- bool isCondCtrl() const { return flags[IsCondControl]; }
- bool isUncondCtrl() const { return flags[IsUncondControl]; }
+ bool isCondCtrl() const { return flags[IsCondControl]; }
+ bool isUncondCtrl() const { return flags[IsUncondControl]; }
bool isCondDelaySlot() const { return flags[IsCondDelaySlot]; }
bool isThreadSync() const { return flags[IsThreadSync]; }
bool isQuiesce() const { return flags[IsQuiesce]; }
bool isIprAccess() const { return flags[IsIprAccess]; }
bool isUnverifiable() const { return flags[IsUnverifiable]; }
- bool isMacroOp() const { return flags[IsMacroOp]; }
- bool isMicroOp() const { return flags[IsMicroOp]; }
+ bool isSyscall() const { return flags[IsSyscall]; }
+ bool isMacroop() const { return flags[IsMacroop]; }
+ bool isMicroop() const { return flags[IsMicroop]; }
bool isDelayedCommit() const { return flags[IsDelayedCommit]; }
- bool isLastMicroOp() const { return flags[IsLastMicroOp]; }
- bool isFirstMicroOp() const { return flags[IsFirstMicroOp]; }
+ bool isLastMicroop() const { return flags[IsLastMicroop]; }
+ bool isFirstMicroop() const { return flags[IsFirstMicroop]; }
//This flag doesn't do anything yet
bool isMicroBranch() const { return flags[IsMicroBranch]; }
//@}
+ void setLastMicroop() { flags[IsLastMicroop] = true; }
/// Operation class. Used to select appropriate function unit in issue.
OpClass opClass() const { return _opClass; }
};
typedef TheISA::RegIndex RegIndex;
enum {
- MaxInstSrcRegs = TheISA::MaxInstSrcRegs, //< Max source regs
- MaxInstDestRegs = TheISA::MaxInstDestRegs, //< Max dest regs
+ MaxInstSrcRegs = TheISA::MaxInstSrcRegs, //< Max source regs
+ MaxInstDestRegs = TheISA::MaxInstDestRegs, //< Max dest regs
};
StaticInst(const char *_mnemonic, ExtMachInst _machInst, OpClass __opClass)
: StaticInstBase(__opClass),
machInst(_machInst), mnemonic(_mnemonic), cachedDisassembly(0)
- {
- }
+ { }
public:
-
- virtual ~StaticInst()
- {
- if (cachedDisassembly)
- delete cachedDisassembly;
- }
+ virtual ~StaticInst();
/**
* The execute() signatures are auto-generated by scons based on the
* Return the microop that goes with a particular micropc. This should
* only be defined/used in macroops which will contain microops
*/
- virtual StaticInstPtr fetchMicroOp(MicroPC micropc);
+ virtual StaticInstPtr fetchMicroop(MicroPC micropc);
/**
* Return the target address for a PC-relative branch.
* Invalid if not a PC-relative branch (i.e. isDirectCtrl()
* should be true).
*/
- virtual Addr branchTarget(Addr branchPC) const
- {
- panic("StaticInst::branchTarget() called on instruction "
- "that is not a PC-relative branch.");
- M5_DUMMY_RETURN
- }
+ virtual Addr branchTarget(Addr branchPC) const;
/**
* Return the target address for an indirect branch (jump). The
* execute the branch in question. Invalid if not an indirect
* branch (i.e. isIndirectCtrl() should be true).
*/
- virtual Addr branchTarget(ThreadContext *tc) const
- {
- panic("StaticInst::branchTarget() called on instruction "
- "that is not an indirect branch.");
- }
- M5_DUMMY_RETURN
+ virtual Addr branchTarget(ThreadContext *tc) const;
/**
* Return true if the instruction is a control transfer, and if so,
*/
bool hasBranchTarget(Addr pc, ThreadContext *tc, Addr &tgt) const;
+ virtual Request::Flags memAccFlags();
+
/**
* Return string representation of disassembled instruction.
* The default version of this function will call the internal
* should not be cached, this function should be overridden directly.
*/
virtual const std::string &disassemble(Addr pc,
- const SymbolTable *symtab = 0) const
- {
- if (!cachedDisassembly)
- cachedDisassembly =
- new std::string(generateDisassembly(pc, symtab));
-
- return *cachedDisassembly;
- }
+ const SymbolTable *symtab = 0) const;
/// Decoded instruction cache type.
/// For now we're using a generic hash_map; this seems to work
/// Decode a machine instruction.
/// @param mach_inst The binary instruction to decode.
/// @retval A pointer to the corresponding StaticInst object.
- //This is defined as inline below.
- static StaticInstPtr decode(ExtMachInst mach_inst);
-
- /// Return opcode of machine instruction
- uint32_t getOpcode() { return bits(machInst, 31, 26);}
+ //This is defined as inlined below.
+ static StaticInstPtr decode(ExtMachInst mach_inst, Addr addr);
/// Return name of machine instruction
std::string getName() { return mnemonic; }
+
+ /// Decoded instruction cache type, for address decoding.
+ /// A generic hash_map is used.
+ typedef m5::hash_map<Addr, AddrDecodePage *> AddrDecodeCache;
+
+ /// A cache of decoded instruction objects from addresses.
+ static AddrDecodeCache addrDecodeCache;
+
+ struct cacheElement
+ {
+ Addr page_addr;
+ AddrDecodePage *decodePage;
+
+ cacheElement() : decodePage(NULL) { }
+ };
+
+ /// An array of recently decoded instructions.
+ // might not use an array if there is only two elements
+ static struct cacheElement recentDecodes[2];
+
+ /// Updates the recently decoded instructions entries
+ /// @param page_addr The page address recently used.
+ /// @param decodePage Pointer to decoding page containing the decoded
+ /// instruction.
+ static inline void
+ updateCache(Addr page_addr, AddrDecodePage *decodePage)
+ {
+ recentDecodes[1].page_addr = recentDecodes[0].page_addr;
+ recentDecodes[1].decodePage = recentDecodes[0].decodePage;
+ recentDecodes[0].page_addr = page_addr;
+ recentDecodes[0].decodePage = decodePage;
+ }
+
+ /// Searches the decoded instruction cache for instruction decoding.
+ /// If it is not found, then we decode the instruction.
+ /// Otherwise, we get the instruction from the cache and move it into
+ /// the address-to-instruction decoding page.
+ /// @param mach_inst The binary instruction to decode.
+ /// @param addr The address that contained the binary instruction.
+ /// @param decodePage Pointer to decoding page containing the instruction.
+ /// @retval A pointer to the corresponding StaticInst object.
+ //This is defined as inlined below.
+ static StaticInstPtr searchCache(ExtMachInst mach_inst, Addr addr,
+ AddrDecodePage *decodePage);
};
typedef RefCountingPtr<StaticInstBase> StaticInstBasePtr;
/// Construct directly from machine instruction.
/// Calls StaticInst::decode().
- StaticInstPtr(TheISA::ExtMachInst mach_inst)
- : RefCountingPtr<StaticInst>(StaticInst::decode(mach_inst))
+ explicit StaticInstPtr(TheISA::ExtMachInst mach_inst, Addr addr)
+ : RefCountingPtr<StaticInst>(StaticInst::decode(mach_inst, addr))
{
}
}
};
+/// A page of a list of decoded instructions from an address.
+class AddrDecodePage
+{
+ typedef TheISA::ExtMachInst ExtMachInst;
+ protected:
+ StaticInstPtr instructions[TheISA::PageBytes];
+ bool valid[TheISA::PageBytes];
+ Addr lowerMask;
+
+ public:
+ /// Constructor
+ AddrDecodePage()
+ {
+ lowerMask = TheISA::PageBytes - 1;
+ memset(valid, 0, TheISA::PageBytes);
+ }
+
+ /// Checks if the instruction is already decoded and the machine
+ /// instruction in the cache matches the current machine instruction
+ /// related to the address
+ /// @param mach_inst The binary instruction to check
+ /// @param addr The address containing the instruction
+ bool
+ decoded(ExtMachInst mach_inst, Addr addr)
+ {
+ return (valid[addr & lowerMask] &&
+ (instructions[addr & lowerMask]->machInst == mach_inst));
+ }
+
+ /// Returns the instruction object. decoded should be called first
+ /// to check if the instruction is valid.
+ /// @param addr The address of the instruction.
+ /// @retval A pointer to the corresponding StaticInst object.
+ StaticInstPtr
+ getInst(Addr addr)
+ {
+ return instructions[addr & lowerMask];
+ }
+
+ /// Inserts a pointer to a StaticInst object into the list of decoded
+ /// instructions on the page.
+ /// @param addr The address of the instruction.
+ /// @param si A pointer to the corresponding StaticInst object.
+ void
+ insert(Addr addr, StaticInstPtr &si)
+ {
+ instructions[addr & lowerMask] = si;
+ valid[addr & lowerMask] = true;
+ }
+};
+
+
inline StaticInstPtr
-StaticInst::decode(StaticInst::ExtMachInst mach_inst)
+StaticInst::decode(StaticInst::ExtMachInst mach_inst, Addr addr)
{
#ifdef DECODE_CACHE_HASH_STATS
// Simple stats on decode hash_map. Turns out the default
}
#endif
+ Addr page_addr = addr & ~(TheISA::PageBytes - 1);
+
+ // checks recently decoded addresses
+ if (recentDecodes[0].decodePage &&
+ page_addr == recentDecodes[0].page_addr) {
+ if (recentDecodes[0].decodePage->decoded(mach_inst, addr))
+ return recentDecodes[0].decodePage->getInst(addr);
+
+ return searchCache(mach_inst, addr, recentDecodes[0].decodePage);
+ }
+
+ if (recentDecodes[1].decodePage &&
+ page_addr == recentDecodes[1].page_addr) {
+ if (recentDecodes[1].decodePage->decoded(mach_inst, addr))
+ return recentDecodes[1].decodePage->getInst(addr);
+
+ return searchCache(mach_inst, addr, recentDecodes[1].decodePage);
+ }
+
+ // searches the page containing the address to decode
+ AddrDecodeCache::iterator iter = addrDecodeCache.find(page_addr);
+ if (iter != addrDecodeCache.end()) {
+ updateCache(page_addr, iter->second);
+ if (iter->second->decoded(mach_inst, addr))
+ return iter->second->getInst(addr);
+
+ return searchCache(mach_inst, addr, iter->second);
+ }
+
+ // creates a new object for a page of decoded instructions
+ AddrDecodePage *decodePage = new AddrDecodePage;
+ addrDecodeCache[page_addr] = decodePage;
+ updateCache(page_addr, decodePage);
+ return searchCache(mach_inst, addr, decodePage);
+}
+
+inline StaticInstPtr
+StaticInst::searchCache(ExtMachInst mach_inst, Addr addr,
+ AddrDecodePage *decodePage)
+{
DecodeCache::iterator iter = decodeCache.find(mach_inst);
if (iter != decodeCache.end()) {
+ decodePage->insert(addr, iter->second);
return iter->second;
}
StaticInstPtr si = TheISA::decodeInst(mach_inst);
+ decodePage->insert(addr, si);
decodeCache[mach_inst] = si;
return si;
}