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726 lines
26 KiB
726 lines
26 KiB
#pragma once
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#include <iostream>
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#include <unordered_map>
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#include <shared_mutex>
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#include <mutex>
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#include <memory>
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#include <sched.h>
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#include <numa.h>
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#include <numaif.h>
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#include <dml/dml.hpp>
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namespace dml {
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inline const std::string StatusCodeToString(const dml::status_code code) {
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switch (code) {
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case dml::status_code::ok: return "ok";
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case dml::status_code::false_predicate: return "false predicate";
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case dml::status_code::partial_completion: return "partial completion";
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case dml::status_code::nullptr_error: return "nullptr error";
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case dml::status_code::bad_size: return "bad size";
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case dml::status_code::bad_length: return "bad length";
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case dml::status_code::inconsistent_size: return "inconsistent size";
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case dml::status_code::dualcast_bad_padding: return "dualcast bad padding";
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case dml::status_code::bad_alignment: return "bad alignment";
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case dml::status_code::buffers_overlapping: return "buffers overlapping";
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case dml::status_code::delta_delta_empty: return "delta delta empty";
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case dml::status_code::batch_overflow: return "batch overflow";
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case dml::status_code::execution_failed: return "execution failed";
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case dml::status_code::unsupported_operation: return "unsupported operation";
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case dml::status_code::queue_busy: return "queue busy";
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case dml::status_code::error: return "unknown error";
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case dml::status_code::config_error: return "config error";
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default: return "unhandled error";
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}
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}
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}
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namespace dsacache {
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class Cache;
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/*
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* Class Description:
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* Holds all required information on one cache entry and is used
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* both internally by the Cache and externally by the user.
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*
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* Important Usage Notes:
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* The pointer is only updated in WaitOnCompletion() which
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* therefore must be called by the user at some point in order
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* to use the cached data. Using this class as T for
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* std::shared_ptr<T> is not recommended as references are
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* already counted internally.
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*
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* Cache Lifetime:
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* As long as the instance is referenced, the pointer it stores
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* is guaranteed to be either nullptr or pointing to a valid copy.
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*
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* Implementation Detail:
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* Performs self-reference counting with a shared atomic integer.
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* Therefore on creating a copy the reference count is increased
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* and with the destructor it is deacresed. If the last copy is
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* destroyed the actual underlying data is freed and all shared
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* variables deleted.
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*
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* Notes on Thread Safety:
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* Class is thread safe in any possible state and performs
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* reference counting and deallocation itself entirely atomically.
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*/
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class CacheData {
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public:
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using dml_handler = dml::handler<dml::mem_copy_operation, std::allocator<uint8_t>>;
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private:
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// data source and size of the block
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uint8_t* src_;
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size_t size_;
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// global reference counting object
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std::atomic<int32_t>* active_;
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// global cache-location pointer
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std::atomic<uint8_t*>* cache_;
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// object-local incomplete cache location pointer
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// which is only available in the first instance
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uint8_t* incomplete_cache_;
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// dml handler vector pointer which is only
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// available in the first instance
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std::unique_ptr<std::vector<dml_handler>> handlers_;
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// deallocates the global cache-location
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// and invalidates it
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void Deallocate();
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// checks whether there are at least two
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// valid references to this object which
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// is done as the cache always has one
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// internally to any living instance
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bool Active() const;
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friend Cache;
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public:
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CacheData(uint8_t* data, const size_t size);
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CacheData(const CacheData& other);
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~CacheData();
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// waits on completion of caching operations
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// for this task and is safe to be called in
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// any state of the object
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void WaitOnCompletion();
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// returns the cache data location for this
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// instance which is valid as long as the
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// instance is alive - !!! this may also
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// yield a nullptr !!!
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uint8_t* GetDataLocation() const;
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};
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/*
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* Class Description:
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* Class will handle access to data through internal copies.
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* These are obtained via work submission to the Intel DSA which takes
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* care of asynchronously duplicating the data. The user will define
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* where these copies lie and which system nodes will perform the copy.
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* This is done through policy functions set during initialization.
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*
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* Placement Policy:
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* The Placement Policy Function decides on which node a particular
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* entry is to be placed, given the current executing node and the
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* data source node and data size. This in turn means that for one
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* datum, multiple cached copies may exist at one time.
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*
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* Cache Lifetime:
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* When accessing the cache, a CacheData-object will be returned.
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* As long as this object lives, the pointer which it holds is
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* guaranteed to be either nullptr or a valid copy. When destroyed
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* the entry is marked for deletion which is only carried out
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* when system memory pressure drives an automated cache flush.
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*
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* Restrictions:
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* - Overlapping Pointers may lead to undefined behaviour during
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* manual cache invalidation which should not be used if you
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* intend to have these types of pointers
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* - Cache Invalidation may only be performed manually and gives
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* no ordering guarantees. Therefore, it is the users responsibility
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* to ensure that results after invalidation have been generated
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* using the latest state of data. The cache is best suited
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* to static data.
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*
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* Notes on Thread Safety:
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* - Cache is completely thread-safe after initialization
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* - CacheData-class will handle deallocation of data itself by
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* performing self-reference-counting atomically and only
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* deallocating if the last reference is destroyed
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* - The internal cache state has one lock which is either
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* acquired shared for reading the state (upon accessing an already
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* cached element) or unique (accessing a new element, flushing, invalidating)
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* - Waiting on copy completion is done over an atomic-wait in copies
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* of the original CacheData-instance
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* - Overall this class may experience performance issues due to the use
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* of locking (in any configuration), lock contention (worsens with higher
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* core count, node count and utilization) and atomics (worse in the same
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* situations as lock contention)
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*
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* Improving Performance:
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* When data is never shared between threads or memory size for the cache is
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* not an issue you may consider having one Cache-instance per thread and removing
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* the lock in Cache and modifying the reference counting and waiting mechanisms
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* of CacheData accordingly (although this is high effort and will yield little due
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* to the atomics not being shared among cores/nodes).
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* Otherwise, one Cache-instance per node could also be considered. This will allow
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* the placement policy function to be barebones and reduces the lock contention and
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* synchronization impact of the atomic variables.
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*/
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class Cache {
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public:
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// cache policy is defined as a type here to allow flexible usage of the cacher
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// given a numa destination node (where the data will be needed), the numa source
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// node (current location of the data) and the data size, this function should
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// return optimal cache placement
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// dst node and returned value can differ if the system, for example, has HBM
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// attached accessible directly to node n under a different node id m
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typedef int (CachePolicy)(const int numa_dst_node, const int numa_src_node, const size_t data_size);
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// copy policy specifies the copy-executing nodes for a given task
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// which allows flexibility in assignment for optimizing raw throughput
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// or choosing a conservative usage policy
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typedef std::vector<int> (CopyPolicy)(const int numa_dst_node, const int numa_src_node, const size_t data_size);
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private:
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// mutex for accessing the cache state map
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std::shared_mutex cache_mutex_;
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// map from [dst-numa-node,map2]
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// map2 from [data-ptr,cache-structure]
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std::unordered_map<uint8_t, std::unordered_map<uint8_t*, CacheData>> cache_state_;
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CachePolicy* cache_policy_function_ = nullptr;
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CopyPolicy* copy_policy_function_ = nullptr;
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// function used to submit a copy task on a specific node to the dml
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// engine on that node - will change the current threads node assignment
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// to achieve this so take care to restore this
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dml::handler<dml::mem_copy_operation, std::allocator<uint8_t>> ExecuteCopy(
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const uint8_t* src, uint8_t* dst, const size_t size, const int node
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) const;
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// allocates the required memory on the destination node
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// and then submits task to the dml library for processing
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// and attaches the handlers to the cache data structure
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void SubmitTask(CacheData* task, const int dst_node, const int src_node);
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// querries the policy functions for the given data and size
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// to obtain destination cache node, also returns the datas
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// source node for further usage
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// output may depend on the calling threads node assignment
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// as this is set as the "optimal placement" node
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void GetCacheNode(uint8_t* src, const size_t size, int* OUT_DST_NODE, int* OUT_SRC_NODE) const;
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// allocates memory of size "size" on the numa node "node"
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// and returns nullptr if this is not possible, also may
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// try to flush the cache of the requested node to
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// alleviate encountered shortage
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uint8_t* AllocOnNode(const size_t size, const int node);
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// checks whether the cache contains an entry for
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// the given data in the given memory node and
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// returns it, otherwise returns nullptr
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std::unique_ptr<CacheData> GetFromCache(uint8_t* src, const size_t size, const int dst_node);
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public:
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Cache(const Cache& other) = delete;
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// initializes the cache with the two policy functions
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// only after this is it safe to use in a threaded environment
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void Init(CachePolicy* cache_policy_function, CopyPolicy* copy_policy_function);
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// function to perform data access through the cache
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std::unique_ptr<CacheData> Access(uint8_t* data, const size_t size);
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// flushes the cache of inactive entries
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// if node is -1 then the whole cache is
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// checked and otherwise the specified
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// node - no checks on node validity
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void Flush(const int node = -1);
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// forces out all entries from the
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// cache and therefore will also "forget"
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// still-in-use entries, these will still
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// be properly deleted, but the cache
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// will be fresh - use for testing
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void Clear();
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void Invalidate(uint8_t* data);
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};
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}
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inline void dsacache::Cache::Clear() {
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std::unique_lock<std::shared_mutex> lock(cache_mutex_);
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cache_state_.clear();
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Init(cache_policy_function_, copy_policy_function_);
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}
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inline void dsacache::Cache::Init(CachePolicy* cache_policy_function, CopyPolicy* copy_policy_function) {
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cache_policy_function_ = cache_policy_function;
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copy_policy_function_ = copy_policy_function;
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// initialize numa library
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numa_available();
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// obtain all available nodes
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// and those we may allocate
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// memory on
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const int nodes_max = numa_num_configured_nodes();
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const bitmask* valid_nodes = numa_get_mems_allowed();
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// prepare the cache state with entries
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// for all given nodes
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for (int node = 0; node < nodes_max; node++) {
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if (numa_bitmask_isbitset(valid_nodes, node)) {
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cache_state_.insert({node,{}});
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}
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}
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}
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inline std::unique_ptr<dsacache::CacheData> dsacache::Cache::Access(uint8_t* data, const size_t size) {
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// get destination numa node for the cache
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int dst_node = -1;
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int src_node = -1;
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GetCacheNode(data, size, &dst_node, &src_node);
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// TODO: at this point it could be beneficial to check whether
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// TODO: the given destination node is present as an entry
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// TODO: in the cache state to see if it is valid
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// check whether the data is already cached
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std::unique_ptr<CacheData> task = GetFromCache(data, size, dst_node);
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if (task != nullptr) {
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return std::move(task);
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}
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// at this point the requested data is not present in cache
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// and we create a caching task for it
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task = std::make_unique<CacheData>(data, size);
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{
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std::unique_lock<std::shared_mutex> lock(cache_mutex_);
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const auto state = cache_state_[dst_node].emplace(task->src_, *task);
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// if state.second is false then no insertion took place
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// which means that concurrently whith this thread
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// some other thread must have accessed the same
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// resource in which case we return the other
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// threads data cache structure
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if (!state.second) {
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std::cout << "[!] Found another cache instance for 0x" << std::hex << (uint64_t)task->src_ << std::dec << std::endl;
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return std::move(std::make_unique<CacheData>(state.first->second));
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}
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}
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SubmitTask(task.get(), dst_node, src_node);
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return std::move(task);
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}
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inline uint8_t* dsacache::Cache::AllocOnNode(const size_t size, const int node) {
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// allocate data on this node and flush the unused parts of the
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// cache if the operation fails and retry once
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// TODO: smarter flush strategy could keep some stuff cached
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// check currently free memory to see if the data fits
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long long int free_space = 0;
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numa_node_size64(node, &free_space);
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if (free_space < size) {
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std::cout << "[!] Memory shortage when allocating " << size << "B on node " << node << std::endl;
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// dst node lacks memory space so we flush the cache for this
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// node hoping to free enough currently unused entries to make
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// the second allocation attempt successful
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Flush(node);
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// re-test by getting the free space and checking again
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numa_node_size64(node, &free_space);
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if (free_space < size) {
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std::cout << "[x] Memory shortage after flush when allocating " << size << "B on node " << node << std::endl;
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return nullptr;
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}
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}
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uint8_t* dst = reinterpret_cast<uint8_t*>(numa_alloc_onnode(size, node));
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if (dst == nullptr) {
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std::cout << "[x] Allocation try failed for " << size << "B on node " << node << std::endl;
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return nullptr;
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}
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return dst;
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}
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inline void dsacache::Cache::SubmitTask(CacheData* task, const int dst_node, const int src_node) {
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uint8_t* dst = AllocOnNode(task->size_, dst_node);
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if (dst == nullptr) {
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std::cout << "[x] Allocation failed so we can not cache" << std::endl;
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return;
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}
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task->incomplete_cache_ = dst;
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// querry copy policy function for the nodes to use for the copy
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const std::vector<int> executing_nodes = copy_policy_function_(dst_node, src_node, task->size_);
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const size_t task_count = executing_nodes.size();
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// each task will copy one fair part of the total size
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// and in case the total size is not a factor of the
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// given task count the last node must copy the remainder
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const size_t size = task->size_ / task_count;
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const size_t last_size = size + task->size_ % task_count;
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// save the current numa node mask to restore later
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// as executing the copy task will place this thread
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// on a different node
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bitmask* nodemask = numa_get_run_node_mask();
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for (uint32_t i = 0; i < task_count; i++) {
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const size_t local_size = i + 1 == task_count ? size : last_size;
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const size_t local_offset = i * size;
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const uint8_t* local_src = task->src_ + local_offset;
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uint8_t* local_dst = dst + local_offset;
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task->handlers_->emplace_back(ExecuteCopy(local_src, local_dst, local_size, executing_nodes[i]));
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}
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// restore the previous nodemask
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numa_run_on_node_mask(nodemask);
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numa_free_nodemask(nodemask);
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}
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inline dml::handler<dml::mem_copy_operation, std::allocator<uint8_t>> dsacache::Cache::ExecuteCopy(
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const uint8_t* src, uint8_t* dst, const size_t size, const int node
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) const {
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dml::const_data_view srcv = dml::make_view(src, size);
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dml::data_view dstv = dml::make_view(dst, size);
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numa_run_on_node(node);
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return dml::submit<dml::automatic>(dml::mem_copy.block_on_fault(), srcv, dstv);
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}
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inline void dsacache::Cache::GetCacheNode(uint8_t* src, const size_t size, int* OUT_DST_NODE, int* OUT_SRC_NODE) const {
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// obtain numa node of current thread to determine where the data is needed
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const int current_cpu = sched_getcpu();
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const int current_node = numa_node_of_cpu(current_cpu);
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// obtain node that the given data pointer is allocated on
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*OUT_SRC_NODE = -1;
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get_mempolicy(OUT_SRC_NODE, NULL, 0, (void*)src, MPOL_F_NODE | MPOL_F_ADDR);
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// querry cache policy function for the destination numa node
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*OUT_DST_NODE = cache_policy_function_(current_node, *OUT_SRC_NODE, size);
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}
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inline void dsacache::Cache::Flush(const int node) {
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// this lambda is used because below we have two code paths that
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// flush nodes, either one single or all successively
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const auto FlushNode = [](std::unordered_map<uint8_t*,CacheData>& map) {
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// begin at the front of the map
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auto it = map.begin();
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// loop until we reach the end of the map
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while (it != map.end()) {
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// if the iterator points to an inactive element
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// then we may erase it
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if (it->second.Active() == false) {
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// erase the iterator from the map
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map.erase(it);
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// as the erasure invalidated out iterator
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// we must start at the beginning again
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it = map.begin();
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}
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else {
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// if element is active just move over to the next one
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it++;
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}
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}
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};
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{
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// we require exclusive lock as we modify the cache state
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std::unique_lock<std::shared_mutex> lock(cache_mutex_);
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// node == -1 means that cache on all nodes should be flushed
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if (node == -1) {
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for (auto& nc : cache_state_) {
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FlushNode(nc.second);
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}
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}
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else {
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FlushNode(cache_state_[node]);
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}
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}
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}
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|
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inline std::unique_ptr<dsacache::CacheData> dsacache::Cache::GetFromCache(uint8_t* src, const size_t size, const int dst_node) {
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// the best situation is if this data is already cached
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// which we check in an unnamed block in which the cache
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// is locked for reading to prevent another thread
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// from marking the element we may find as unused and
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// clearing it
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|
|
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// lock the cache state in shared-mode because we read
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|
|
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std::shared_lock<std::shared_mutex> lock(cache_mutex_);
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|
|
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// search for the data in our cache state structure at the given node
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|
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const auto search = cache_state_[dst_node].find(src);
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|
|
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// if the data is in our structure we continue
|
|
|
|
if (search != cache_state_[dst_node].end()) {
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|
|
|
// now check whether the sizes match
|
|
|
|
if (search->second.size_ >= size) {
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// return a unique copy of the entry which uses the object
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// lifetime and destructor to safely handle deallocation
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|
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|
return std::move(std::make_unique<CacheData>(search->second));
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|
}
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else {
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|
// if the sizes missmatch then we clear the current entry from cache
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|
// which will cause its deletion only after the last possible outside
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|
// reference is also destroyed
|
|
|
|
cache_state_[dst_node].erase(search);
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|
}
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|
}
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|
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|
return nullptr;
|
|
}
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|
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|
void dsacache::Cache::Invalidate(uint8_t* data) {
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// as the cache is modified we must obtain a unique writers lock
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|
|
|
std::unique_lock<std::shared_mutex> lock(cache_mutex_);
|
|
|
|
// loop through all per-node-caches available
|
|
|
|
for (auto node : cache_state_) {
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|
// search for an entry for the given data pointer
|
|
|
|
auto search = node.second.find(data);
|
|
|
|
if (search != node.second.end()) {
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|
// if the data is represented in-cache
|
|
// then it will be erased to re-trigger
|
|
// caching on next access
|
|
|
|
node.second.erase(search);
|
|
}
|
|
}
|
|
}
|
|
|
|
inline dsacache::CacheData::CacheData(uint8_t* data, const size_t size) {
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|
src_ = data;
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|
size_ = size;
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|
active_ = new std::atomic<int32_t>(1);
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|
cache_ = new std::atomic<uint8_t*>();
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|
incomplete_cache_ = nullptr;
|
|
handlers_ = std::make_unique<std::vector<dml_handler>>();
|
|
}
|
|
|
|
inline dsacache::CacheData::CacheData(const dsacache::CacheData& other) {
|
|
// we copy the ptr to the global atomic reference counter
|
|
// and increase the amount of active references
|
|
|
|
active_ = other.active_;
|
|
const int current_active = active_->fetch_add(1);
|
|
|
|
// source and size will be copied too
|
|
// as well as the reference to the global
|
|
// atomic cache pointer
|
|
|
|
src_ = other.src_;
|
|
size_ = other.size_;
|
|
cache_ = other.cache_;
|
|
|
|
// incomplete cache and handlers will not
|
|
// be copied because only the first instance
|
|
// will wait on the completion of handlers
|
|
|
|
incomplete_cache_ = nullptr;
|
|
handlers_ = nullptr;
|
|
}
|
|
|
|
inline dsacache::CacheData::~CacheData() {
|
|
// if this is the first instance of this cache structure
|
|
// and it has not been waited on and is now being destroyed
|
|
// we must wait on completion here to ensure the cache
|
|
// remains in a valid state
|
|
|
|
if (handlers_ != nullptr) {
|
|
WaitOnCompletion();
|
|
}
|
|
|
|
// due to fetch_sub returning the preivously held value
|
|
// we must subtract one locally to get the current value
|
|
|
|
const int32_t v = active_->fetch_sub(1) - 1;
|
|
|
|
// if the returned value is zero or lower
|
|
// then we must execute proper deletion
|
|
// as this was the last reference
|
|
|
|
if (v <= 0) {
|
|
Deallocate();
|
|
|
|
delete active_;
|
|
delete cache_;
|
|
}
|
|
}
|
|
|
|
inline void dsacache::CacheData::Deallocate() {
|
|
// although deallocate should only be called from
|
|
// a safe context to do so, it can not hurt to
|
|
// defensively perform the operation atomically
|
|
|
|
uint8_t* cache_local = cache_->exchange(nullptr);
|
|
if (cache_local != nullptr) numa_free(cache_local, size_);
|
|
|
|
// if the cache was never waited for then incomplete_cache_
|
|
// may still contain a valid pointer which has to be freed
|
|
|
|
if (incomplete_cache_ != nullptr) numa_free(incomplete_cache_, size_);
|
|
}
|
|
|
|
inline uint8_t* dsacache::CacheData::GetDataLocation() const {
|
|
return cache_->load();
|
|
}
|
|
|
|
inline bool dsacache::CacheData::Active() const {
|
|
// this entry is active if more than one
|
|
// reference exists to it, as the Cache
|
|
// will always keep one internally until
|
|
// the entry is cleared from cache
|
|
|
|
return active_->load() > 1;
|
|
}
|
|
|
|
inline void dsacache::CacheData::WaitOnCompletion() {
|
|
// the cache data entry can be in two states
|
|
// either it is the original one which has not
|
|
// been waited for in which case the handlers
|
|
// are non-null or it is not
|
|
|
|
if (handlers_ == nullptr) {
|
|
// when no handlers are attached to this cache entry we wait on a
|
|
// value change for the cache structure from nullptr to non-null
|
|
// which will either go through immediately if the cache is valid
|
|
// already or wait until the handler-owning thread notifies us
|
|
|
|
cache_->wait(nullptr);
|
|
}
|
|
else {
|
|
// when the handlers are non-null there are some DSA task handlers
|
|
// available on which we must wait here
|
|
|
|
// abort is set if any operation encountered an error
|
|
|
|
bool abort = false;
|
|
|
|
for (auto& handler : *handlers_) {
|
|
auto result = handler.get();
|
|
|
|
if (result.status != dml::status_code::ok) {
|
|
std::cerr << "[x] Encountered bad status code for operation: " << dml::StatusCodeToString(result.status) << std::endl;
|
|
|
|
// if one of the copy tasks failed we abort the whole task
|
|
// after all operations are completed on it
|
|
|
|
abort = true;
|
|
}
|
|
}
|
|
|
|
// the handlers are cleared after all have completed
|
|
|
|
handlers_ = nullptr;
|
|
|
|
// now we act depending on whether an abort has been
|
|
// called for which signals operation incomplete
|
|
|
|
if (abort) {
|
|
// store nullptr in the cache location
|
|
|
|
cache_->store(nullptr);
|
|
|
|
// then free the now incomplete cache
|
|
|
|
// TODO: it would be possible to salvage the
|
|
// TODO: operation at this point but this
|
|
// TODO: is quite complicated so we just abort
|
|
|
|
numa_free(incomplete_cache_, size_);
|
|
}
|
|
else {
|
|
// incomplete cache is now safe to use and therefore we
|
|
// swap it with the global cache state of this entry
|
|
// and notify potentially waiting threads
|
|
|
|
cache_->store(incomplete_cache_);
|
|
}
|
|
|
|
// as a last step all waiting threads must
|
|
// be notified (copies of this will wait on value
|
|
// change of the cache) and the incomplete cache
|
|
// is cleared to nullptr as it is not incomplete
|
|
|
|
cache_->notify_all();
|
|
incomplete_cache_ = nullptr;
|
|
}
|
|
}
|