class Instruction; // Forward def
+// DAG operator that interprets the DAG args as Instruction defs.
+def instrs;
+
+// DAG operator that interprets each DAG arg as a regex pattern for
+// matching Instruction opcode names.
+// The regex must match the beginning of the opcode (as in Python re.match).
+// To avoid matching prefixes, append '$' to the pattern.
+def instregex;
+
// Define the SchedMachineModel and provide basic properties for
// coarse grained instruction cost model. Default values for the
// properties are defined in MCSchedModel. A value of "-1" in the
//
// Target hooks allow subtargets to associate LoadLatency and
// HighLatency with groups of opcodes.
+//
+// See MCSchedule.h for detailed comments.
class SchedMachineModel {
int IssueWidth = -1; // Max micro-ops that may be scheduled per cycle.
- int MinLatency = -1; // Determines which instrucions are allowed in a group.
+ int MinLatency = -1; // Determines which instructions are allowed in a group.
// (-1) inorder (0) ooo, (1): inorder +var latencies.
+ int MicroOpBufferSize = -1; // Max micro-ops that can be buffered.
+ int LoopMicroOpBufferSize = -1; // Max micro-ops that can be buffered for
+ // optimized loop dispatch/execution.
int LoadLatency = -1; // Cycles for loads to access the cache.
int HighLatency = -1; // Approximation of cycles for "high latency" ops.
int MispredictPenalty = -1; // Extra cycles for a mispredicted branch.
// Per-cycle resources tables.
ProcessorItineraries Itineraries = NoItineraries;
+ bit PostRAScheduler = 0; // Enable Post RegAlloc Scheduler pass.
+
+ // Subtargets that define a model for only a subset of instructions
+ // that have a scheduling class (itinerary class or SchedRW list)
+ // and may actually be generated for that subtarget must clear this
+ // bit. Otherwise, the scheduler considers an unmodelled opcode to
+ // be an error. This should only be set during initial bringup,
+ // or there will be no way to catch simple errors in the model
+ // resulting from changes to the instruction definitions.
+ bit CompleteModel = 1;
+
bit NoModel = 0; // Special tag to indicate missing machine model.
}
// resources implies using one of the super resoruces.
//
// ProcResourceUnits normally model a few buffered resources within an
-// out-of-order engine that the compiler attempts to conserve.
-// Buffered resources may be held for multiple clock cycles, but the
-// scheduler does not pin them to a particular clock cycle relative to
-// instruction dispatch. Setting Buffered=0 changes this to an
-// in-order resource. In this case, the scheduler counts down from the
-// cycle that the instruction issues in-order, forcing an interlock
-// with subsequent instructions that require the same resource until
-// the number of ResourceCyles specified in WriteRes expire.
+// out-of-order engine. Buffered resources may be held for multiple
+// clock cycles, but the scheduler does not pin them to a particular
+// clock cycle relative to instruction dispatch. Setting BufferSize=0
+// changes this to an in-order issue/dispatch resource. In this case,
+// the scheduler counts down from the cycle that the instruction
+// issues in-order, forcing a stall whenever a subsequent instruction
+// requires the same resource until the number of ResourceCyles
+// specified in WriteRes expire. Setting BufferSize=1 changes this to
+// an in-order latency resource. In this case, the scheduler models
+// producer/consumer stalls between instructions that use the
+// resource.
+//
+// Examples (all assume an out-of-order engine):
+//
+// Use BufferSize = -1 for "issue ports" fed by a unified reservation
+// station. Here the size of the reservation station is modeled by
+// MicroOpBufferSize, which should be the minimum size of either the
+// register rename pool, unified reservation station, or reorder
+// buffer.
+//
+// Use BufferSize = 0 for resources that force "dispatch/issue
+// groups". (Different processors define dispath/issue
+// differently. Here we refer to stage between decoding into micro-ops
+// and moving them into a reservation station.) Normally NumMicroOps
+// is sufficient to limit dispatch/issue groups. However, some
+// processors can form groups of with only certain combinitions of
+// instruction types. e.g. POWER7.
+//
+// Use BufferSize = 1 for in-order execution units. This is used for
+// an in-order pipeline within an out-of-order core where scheduling
+// dependent operations back-to-back is guaranteed to cause a
+// bubble. e.g. Cortex-a9 floating-point.
+//
+// Use BufferSize > 1 for out-of-order executions units with a
+// separate reservation station. This simply models the size of the
+// reservation station.
+//
+// To model both dispatch/issue groups and in-order execution units,
+// create two types of units, one with BufferSize=0 and one with
+// BufferSize=1.
//
// SchedModel ties these units to a processor for any stand-alone defs
// of this class. Instances of subclass ProcResource will be automatically
ProcResourceKind Kind = kind;
int NumUnits = num;
ProcResourceKind Super = ?;
- bit Buffered = 1;
+ int BufferSize = -1;
SchedMachineModel SchedModel = ?;
}
class ProcResource<int num> : ProcResourceKind,
ProcResourceUnits<EponymousProcResourceKind, num>;
+class ProcResGroup<list<ProcResource> resources> : ProcResourceKind {
+ list<ProcResource> Resources = resources;
+ SchedMachineModel SchedModel = ?;
+ int BufferSize = -1;
+}
+
// A target architecture may define SchedReadWrite types and associate
// them with instruction operands.
class SchedReadWrite;
// the subtarget to easily override specific operations.
//
// SchedModel ties this opcode mapping to a processor.
-class InstRW<list<SchedReadWrite> rw, list<Instruction> instrs> {
+class InstRW<list<SchedReadWrite> rw, dag instrlist> {
list<SchedReadWrite> OperandReadWrites = rw;
- list<Instruction> Instrs = instrs;
+ dag Instrs = instrlist;
SchedMachineModel SchedModel = ?;
}