+ const MCSchedModel &getSchedModelForCPU(StringRef CPU) const;
+
+ /// Get the machine model for this subtarget's CPU.
+ const MCSchedModel &getSchedModel() const { return *CPUSchedModel; }
+
+ /// Return an iterator at the first process resource consumed by the given
+ /// scheduling class.
+ const MCWriteProcResEntry *getWriteProcResBegin(
+ const MCSchedClassDesc *SC) const {
+ return &WriteProcResTable[SC->WriteProcResIdx];
+ }
+ const MCWriteProcResEntry *getWriteProcResEnd(
+ const MCSchedClassDesc *SC) const {
+ return getWriteProcResBegin(SC) + SC->NumWriteProcResEntries;
+ }
+
+ const MCWriteLatencyEntry *getWriteLatencyEntry(const MCSchedClassDesc *SC,
+ unsigned DefIdx) const {
+ assert(DefIdx < SC->NumWriteLatencyEntries &&
+ "MachineModel does not specify a WriteResource for DefIdx");
+
+ return &WriteLatencyTable[SC->WriteLatencyIdx + DefIdx];
+ }
+
+ int getReadAdvanceCycles(const MCSchedClassDesc *SC, unsigned UseIdx,
+ unsigned WriteResID) const {
+ // TODO: The number of read advance entries in a class can be significant
+ // (~50). Consider compressing the WriteID into a dense ID of those that are
+ // used by ReadAdvance and representing them as a bitset.
+ for (const MCReadAdvanceEntry *I = &ReadAdvanceTable[SC->ReadAdvanceIdx],
+ *E = I + SC->NumReadAdvanceEntries; I != E; ++I) {
+ if (I->UseIdx < UseIdx)
+ continue;
+ if (I->UseIdx > UseIdx)
+ break;
+ // Find the first WriteResIdx match, which has the highest cycle count.
+ if (!I->WriteResourceID || I->WriteResourceID == WriteResID) {
+ return I->Cycles;
+ }
+ }
+ return 0;
+ }