//===--------------------- ResourceManager.h --------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// /// \file /// /// The classes here represent processor resource units and their management /// strategy. These classes are managed by the Scheduler. /// //===----------------------------------------------------------------------===// #ifndef LLVM_MCA_RESOURCE_MANAGER_H #define LLVM_MCA_RESOURCE_MANAGER_H #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/SmallVector.h" #include "llvm/MC/MCSchedule.h" #include "llvm/MCA/Instruction.h" #include "llvm/MCA/Support.h" namespace llvm { namespace mca { /// Used to notify the internal state of a processor resource. /// /// A processor resource is available if it is not reserved, and there are /// available slots in the buffer. A processor resource is unavailable if it /// is either reserved, or the associated buffer is full. A processor resource /// with a buffer size of -1 is always available if it is not reserved. /// /// Values of type ResourceStateEvent are returned by method /// ResourceManager::canBeDispatched() /// /// The naming convention for resource state events is: /// * Event names start with prefix RS_ /// * Prefix RS_ is followed by a string describing the actual resource state. enum ResourceStateEvent { RS_BUFFER_AVAILABLE, RS_BUFFER_UNAVAILABLE, RS_RESERVED }; /// Resource allocation strategy used by hardware scheduler resources. class ResourceStrategy { ResourceStrategy(const ResourceStrategy &) = delete; ResourceStrategy &operator=(const ResourceStrategy &) = delete; public: ResourceStrategy() {} virtual ~ResourceStrategy(); /// Selects a processor resource unit from a ReadyMask. virtual uint64_t select(uint64_t ReadyMask) = 0; /// Called by the ResourceManager when a processor resource group, or a /// processor resource with multiple units has become unavailable. /// /// The default strategy uses this information to bias its selection logic. virtual void used(uint64_t ResourceMask) {} }; /// Default resource allocation strategy used by processor resource groups and /// processor resources with multiple units. class DefaultResourceStrategy final : public ResourceStrategy { /// A Mask of resource unit identifiers. /// /// There is one bit set for every available resource unit. /// It defaults to the value of field ResourceSizeMask in ResourceState. const uint64_t ResourceUnitMask; /// A simple round-robin selector for processor resource units. /// Each bit of this mask identifies a sub resource within a group. /// /// As an example, lets assume that this is a default policy for a /// processor resource group composed by the following three units: /// ResourceA -- 0b001 /// ResourceB -- 0b010 /// ResourceC -- 0b100 /// /// Field NextInSequenceMask is used to select the next unit from the set of /// resource units. It defaults to the value of field `ResourceUnitMasks` (in /// this example, it defaults to mask '0b111'). /// /// The round-robin selector would firstly select 'ResourceC', then /// 'ResourceB', and eventually 'ResourceA'. When a resource R is used, the /// corresponding bit in NextInSequenceMask is cleared. For example, if /// 'ResourceC' is selected, then the new value of NextInSequenceMask becomes /// 0xb011. /// /// When NextInSequenceMask becomes zero, it is automatically reset to the /// default value (i.e. ResourceUnitMask). uint64_t NextInSequenceMask; /// This field is used to track resource units that are used (i.e. selected) /// by other groups other than the one associated with this strategy object. /// /// In LLVM processor resource groups are allowed to partially (or fully) /// overlap. That means, a same unit may be visible to multiple groups. /// This field keeps track of uses that have originated from outside of /// this group. The idea is to bias the selection strategy, so that resources /// that haven't been used by other groups get prioritized. /// /// The end goal is to (try to) keep the resource distribution as much uniform /// as possible. By construction, this mask only tracks one-level of resource /// usage. Therefore, this strategy is expected to be less accurate when same /// units are used multiple times by other groups within a single round of /// select. /// /// Note: an LRU selector would have a better accuracy at the cost of being /// slightly more expensive (mostly in terms of runtime cost). Methods /// 'select' and 'used', are always in the hot execution path of llvm-mca. /// Therefore, a slow implementation of 'select' would have a negative impact /// on the overall performance of the tool. uint64_t RemovedFromNextInSequence; public: DefaultResourceStrategy(uint64_t UnitMask) : ResourceStrategy(), ResourceUnitMask(UnitMask), NextInSequenceMask(UnitMask), RemovedFromNextInSequence(0) {} virtual ~DefaultResourceStrategy() = default; uint64_t select(uint64_t ReadyMask) override; void used(uint64_t Mask) override; }; /// A processor resource descriptor. /// /// There is an instance of this class for every processor resource defined by /// the machine scheduling model. /// Objects of class ResourceState dynamically track the usage of processor /// resource units. class ResourceState { /// An index to the MCProcResourceDesc entry in the processor model. const unsigned ProcResourceDescIndex; /// A resource mask. This is generated by the tool with the help of /// function `mca::computeProcResourceMasks' (see Support.h). /// /// Field ResourceMask only has one bit set if this resource state describes a /// processor resource unit (i.e. this is not a group). That means, we can /// quickly check if a resource is a group by simply counting the number of /// bits that are set in the mask. /// /// The most significant bit of a mask (MSB) uniquely identifies a resource. /// Remaining bits are used to describe the composition of a group (Group). /// /// Example (little endian): /// Resource | Mask | MSB | Group /// ---------+------------+------------+------------ /// A | 0b000001 | 0b000001 | 0b000000 /// | | | /// B | 0b000010 | 0b000010 | 0b000000 /// | | | /// C | 0b010000 | 0b010000 | 0b000000 /// | | | /// D | 0b110010 | 0b100000 | 0b010010 /// /// In this example, resources A, B and C are processor resource units. /// Only resource D is a group resource, and it contains resources B and C. /// That is because MSB(B) and MSB(C) are both contained within Group(D). const uint64_t ResourceMask; /// A ProcResource can have multiple units. /// /// For processor resource groups this field is a mask of contained resource /// units. It is obtained from ResourceMask by clearing the highest set bit. /// The number of resource units in a group can be simply computed as the /// population count of this field. /// /// For normal (i.e. non-group) resources, the number of bits set in this mask /// is equivalent to the number of units declared by the processor model (see /// field 'NumUnits' in 'ProcResourceUnits'). uint64_t ResourceSizeMask; /// A mask of ready units. uint64_t ReadyMask; /// Buffered resources will have this field set to a positive number different /// than zero. A buffered resource behaves like a reservation station /// implementing its own buffer for out-of-order execution. /// /// A BufferSize of 1 is used by scheduler resources that force in-order /// execution. /// /// A BufferSize of 0 is used to model in-order issue/dispatch resources. /// Since in-order issue/dispatch resources don't implement buffers, dispatch /// events coincide with issue events. /// Also, no other instruction ca be dispatched/issue while this resource is /// in use. Only when all the "resource cycles" are consumed (after the issue /// event), a new instruction ca be dispatched. const int BufferSize; /// Available slots in the buffer (zero, if this is not a buffered resource). unsigned AvailableSlots; /// This field is set if this resource is currently reserved. /// /// Resources can be reserved for a number of cycles. /// Instructions can still be dispatched to reserved resources. However, /// istructions dispatched to a reserved resource cannot be issued to the /// underlying units (i.e. pipelines) until the resource is released. bool Unavailable; const bool IsAGroup; /// Checks for the availability of unit 'SubResMask' in the group. bool isSubResourceReady(uint64_t SubResMask) const { return ReadyMask & SubResMask; } public: ResourceState(const MCProcResourceDesc &Desc, unsigned Index, uint64_t Mask); unsigned getProcResourceID() const { return ProcResourceDescIndex; } uint64_t getResourceMask() const { return ResourceMask; } uint64_t getReadyMask() const { return ReadyMask; } int getBufferSize() const { return BufferSize; } bool isBuffered() const { return BufferSize > 0; } bool isInOrder() const { return BufferSize == 1; } /// Returns true if this is an in-order dispatch/issue resource. bool isADispatchHazard() const { return BufferSize == 0; } bool isReserved() const { return Unavailable; } void setReserved() { Unavailable = true; } void clearReserved() { Unavailable = false; } /// Returs true if this resource is not reserved, and if there are at least /// `NumUnits` available units. bool isReady(unsigned NumUnits = 1) const; bool isAResourceGroup() const { return IsAGroup; } bool containsResource(uint64_t ID) const { return ResourceMask & ID; } void markSubResourceAsUsed(uint64_t ID) { assert(isSubResourceReady(ID)); ReadyMask ^= ID; } void releaseSubResource(uint64_t ID) { assert(!isSubResourceReady(ID)); ReadyMask ^= ID; } unsigned getNumUnits() const { return isAResourceGroup() ? 1U : countPopulation(ResourceSizeMask); } /// Checks if there is an available slot in the resource buffer. /// /// Returns RS_BUFFER_AVAILABLE if this is not a buffered resource, or if /// there is a slot available. /// /// Returns RS_RESERVED if this buffered resource is a dispatch hazard, and it /// is reserved. /// /// Returns RS_BUFFER_UNAVAILABLE if there are no available slots. ResourceStateEvent isBufferAvailable() const; /// Reserve a buffer slot. /// /// Returns true if the buffer is not full. /// It always returns true if BufferSize is set to zero. bool reserveBuffer() { if (BufferSize <= 0) return true; --AvailableSlots; assert(AvailableSlots <= static_cast(BufferSize)); return AvailableSlots; } /// Releases a slot in the buffer. void releaseBuffer() { // Ignore dispatch hazards or invalid buffer sizes. if (BufferSize <= 0) return; ++AvailableSlots; assert(AvailableSlots <= static_cast(BufferSize)); } #ifndef NDEBUG void dump() const; #endif }; /// A resource unit identifier. /// /// This is used to identify a specific processor resource unit using a pair /// of indices where the 'first' index is a processor resource mask, and the /// 'second' index is an index for a "sub-resource" (i.e. unit). typedef std::pair ResourceRef; // First: a MCProcResourceDesc index identifying a buffered resource. // Second: max number of buffer entries used in this resource. typedef std::pair BufferUsageEntry; /// A resource manager for processor resource units and groups. /// /// This class owns all the ResourceState objects, and it is responsible for /// acting on requests from a Scheduler by updating the internal state of /// ResourceState objects. /// This class doesn't know about instruction itineraries and functional units. /// In future, it can be extended to support itineraries too through the same /// public interface. class ResourceManager { // Set of resources available on the subtarget. // // There is an instance of ResourceState for every resource declared by the // target scheduling model. // // Elements of this vector are ordered by resource kind. In particular, // resource units take precedence over resource groups. // // The index of a processor resource in this vector depends on the value of // its mask (see the description of field ResourceState::ResourceMask). In // particular, it is computed as the position of the most significant bit set // (MSB) in the mask plus one (since we want to ignore the invalid resource // descriptor at index zero). // // Example (little endian): // // Resource | Mask | MSB | Index // ---------+---------+---------+------- // A | 0b00001 | 0b00001 | 1 // | | | // B | 0b00100 | 0b00100 | 3 // | | | // C | 0b10010 | 0b10000 | 5 // // // The same index is also used to address elements within vector `Strategies` // and vector `Resource2Groups`. std::vector> Resources; std::vector> Strategies; // Used to quickly identify groups that own a particular resource unit. std::vector Resource2Groups; // A table that maps processor resource IDs to processor resource masks. SmallVector ProcResID2Mask; // A table that maps resource indices to actual processor resource IDs in the // scheduling model. SmallVector ResIndex2ProcResID; // Keeps track of which resources are busy, and how many cycles are left // before those become usable again. SmallDenseMap BusyResources; // Set of processor resource units available on the target. uint64_t ProcResUnitMask; // Set of processor resource units that are available during this cycle. uint64_t AvailableProcResUnits; // Set of processor resources that are currently reserved. uint64_t ReservedResourceGroups; // Set of unavailable scheduler buffer resources. This is used internally to // speedup `canBeDispatched()` queries. uint64_t AvailableBuffers; // Set of dispatch hazard buffer resources that are currently unavailable. uint64_t ReservedBuffers; // Returns the actual resource unit that will be used. ResourceRef selectPipe(uint64_t ResourceID); void use(const ResourceRef &RR); void release(const ResourceRef &RR); unsigned getNumUnits(uint64_t ResourceID) const; // Overrides the selection strategy for the processor resource with the given // mask. void setCustomStrategyImpl(std::unique_ptr S, uint64_t ResourceMask); public: ResourceManager(const MCSchedModel &SM); virtual ~ResourceManager() = default; // Overrides the selection strategy for the resource at index ResourceID in // the MCProcResourceDesc table. void setCustomStrategy(std::unique_ptr S, unsigned ResourceID) { assert(ResourceID < ProcResID2Mask.size() && "Invalid resource index in input!"); return setCustomStrategyImpl(std::move(S), ProcResID2Mask[ResourceID]); } // Returns RS_BUFFER_AVAILABLE if buffered resources are not reserved, and if // there are enough available slots in the buffers. ResourceStateEvent canBeDispatched(uint64_t ConsumedBuffers) const; // Return the processor resource identifier associated to this Mask. unsigned resolveResourceMask(uint64_t Mask) const; // Acquires a slot from every buffered resource in mask `ConsumedBuffers`. // Units that are dispatch hazards (i.e. BufferSize=0) are marked as reserved. void reserveBuffers(uint64_t ConsumedBuffers); // Releases a slot from every buffered resource in mask `ConsumedBuffers`. // ConsumedBuffers is a bitmask of previously acquired buffers (using method // `reserveBuffers`). Units that are dispatch hazards (i.e. BufferSize=0) are // not automatically unreserved by this method. void releaseBuffers(uint64_t ConsumedBuffers); // Reserve a processor resource. A reserved resource is not available for // instruction issue until it is released. void reserveResource(uint64_t ResourceID); // Release a previously reserved processor resource. void releaseResource(uint64_t ResourceID); // Returns a zero mask if resources requested by Desc are all available during // this cycle. It returns a non-zero mask value only if there are unavailable // processor resources; each bit set in the mask represents a busy processor // resource unit or a reserved processor resource group. uint64_t checkAvailability(const InstrDesc &Desc) const; uint64_t getProcResUnitMask() const { return ProcResUnitMask; } uint64_t getAvailableProcResUnits() const { return AvailableProcResUnits; } void issueInstruction( const InstrDesc &Desc, SmallVectorImpl> &Pipes); void cycleEvent(SmallVectorImpl &ResourcesFreed); #ifndef NDEBUG void dump() const { for (const std::unique_ptr &Resource : Resources) Resource->dump(); } #endif }; } // namespace mca } // namespace llvm #endif // LLVM_MCA_RESOURCE_MANAGER_H