src/mem/cache/prefetch/irregular_stream_buffer.cc - testing/jenkins-gem5-prod - Git at Google

 /**
  * Copyright (c) 2018 Metempsy Technology Consulting
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met: redistributions of source code must retain the above copyright
  * notice, this list of conditions and the following disclaimer;
  * redistributions in binary form must reproduce the above copyright
  * notice, this list of conditions and the following disclaimer in the
  * documentation and/or other materials provided with the distribution;
  * neither the name of the copyright holders nor the names of its
  * contributors may be used to endorse or promote products derived from
  * this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
  * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
  * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  *
  * Authors: Javier Bueno
  */

 #include "mem/cache/prefetch/irregular_stream_buffer.hh"

 #include "debug/HWPrefetch.hh"
 #include "mem/cache/prefetch/associative_set_impl.hh"
 #include "params/IrregularStreamBufferPrefetcher.hh"

 IrregularStreamBufferPrefetcher::IrregularStreamBufferPrefetcher(
     const IrregularStreamBufferPrefetcherParams *p)
     : QueuedPrefetcher(p), maxCounterValue(p->max_counter_value),
         chunkSize(p->chunk_size),
         prefetchCandidatesPerEntry(p->prefetch_candidates_per_entry),
         degree(p->degree),
         trainingUnit(p->training_unit_assoc, p->training_unit_entries,
                      p->training_unit_indexing_policy,
                      p->training_unit_replacement_policy),
         psAddressMappingCache(p->address_map_cache_assoc,
                               p->address_map_cache_entries,
                               p->ps_address_map_cache_indexing_policy,
                               p->ps_address_map_cache_replacement_policy,
                               AddressMappingEntry(prefetchCandidatesPerEntry)),
         spAddressMappingCache(p->address_map_cache_assoc,
                               p->address_map_cache_entries,
                               p->sp_address_map_cache_indexing_policy,
                               p->sp_address_map_cache_replacement_policy,
                               AddressMappingEntry(prefetchCandidatesPerEntry)),
         structuralAddressCounter(0)
 {
     assert(isPowerOf2(prefetchCandidatesPerEntry));
 }

 void
 IrregularStreamBufferPrefetcher::calculatePrefetch(const PrefetchInfo &pfi,
     std::vector<AddrPriority> &addresses)
 {
     // This prefetcher requires a PC
     if (!pfi.hasPC()) {
         return;
     }
     bool is_secure = pfi.isSecure();
     Addr pc = pfi.getPC();
     Addr addr = blockIndex(pfi.getAddr());

     // Training, if the entry exists, then we found a correlation between
     // the entry lastAddress (named as correlated_addr_A) and the address of
     // the current access (named as correlated_addr_B)
     TrainingUnitEntry *entry = trainingUnit.findEntry(pc, is_secure);
     bool correlated_addr_found = false;
     Addr correlated_addr_A = 0;
     Addr correlated_addr_B = 0;
     if (entry != nullptr && entry->lastAddressSecure == is_secure) {
         trainingUnit.accessEntry(entry);
         correlated_addr_found = true;
         correlated_addr_A = entry->lastAddress;
         correlated_addr_B = addr;
     } else {
         entry = trainingUnit.findVictim(pc);
         assert(entry != nullptr);

         trainingUnit.insertEntry(pc, is_secure, entry);
     }
     // Update the entry
     entry->lastAddress = addr;
     entry->lastAddressSecure = is_secure;

     if (correlated_addr_found) {
         // If a correlation was found, update the Physical-to-Structural
         // table accordingly
         AddressMapping &mapping_A = getPSMapping(correlated_addr_A, is_secure);
         AddressMapping &mapping_B = getPSMapping(correlated_addr_B, is_secure);
         if (mapping_A.counter > 0 && mapping_B.counter > 0) {
             // Entry for A and B
             if (mapping_B.address == (mapping_A.address + 1)) {
                 if (mapping_B.counter < maxCounterValue) {
                     mapping_B.counter += 1;
                 }
             } else {
                 if (mapping_B.counter == 1) {
                     // counter would hit 0, reassign address
                     mapping_B.counter = 1;
                     mapping_B.address = mapping_A.address + 1;
                     addStructuralToPhysicalEntry(mapping_B.address, is_secure,
                             correlated_addr_B);
                 } else {
                     mapping_B.counter -= 1;
                 }
             }
         } else {
             if (mapping_A.counter == 0) {
                 // if A is not valid, generate a new structural address
                 mapping_A.counter = 1;
                 mapping_A.address = structuralAddressCounter;
                 structuralAddressCounter += chunkSize;
                 addStructuralToPhysicalEntry(mapping_A.address,
                         is_secure, correlated_addr_A);
             }
             mapping_B.counter = 1;
             mapping_B.address = mapping_A.address + 1;
             // update SP-AMC
             addStructuralToPhysicalEntry(mapping_B.address, is_secure,
                     correlated_addr_B);
         }
     }

     // Use the PS mapping to predict future accesses using the current address
     // - Look for the structured address
     // - if it exists, use it to generate prefetches for the subsequent
     //   addresses in ascending order, as many as indicated by the degree
     //   (given the structured address S, prefetch S+1, S+2, .. up to S+degree)
     Addr amc_address = addr / prefetchCandidatesPerEntry;
     Addr map_index   = addr % prefetchCandidatesPerEntry;
     AddressMappingEntry *ps_am = psAddressMappingCache.findEntry(amc_address,
                                                                  is_secure);
     if (ps_am != nullptr) {
         AddressMapping &mapping = ps_am->mappings[map_index];
         if (mapping.counter > 0) {
             Addr sp_address = mapping.address / prefetchCandidatesPerEntry;
             Addr sp_index   = mapping.address % prefetchCandidatesPerEntry;
             AddressMappingEntry *sp_am =
                 spAddressMappingCache.findEntry(sp_address, is_secure);
             assert(sp_am != nullptr);
             for (unsigned d = 1;
                     d <= degree && (sp_index + d) < prefetchCandidatesPerEntry;
                     d += 1)
             {
                 AddressMapping &spm = sp_am->mappings[sp_index + d];
                 //generate prefetch
                 if (spm.counter > 0) {
                     Addr pf_addr = spm.address << lBlkSize;
                     addresses.push_back(AddrPriority(pf_addr, 0));
                 }
             }
         }
     }
 }

 IrregularStreamBufferPrefetcher::AddressMapping&
 IrregularStreamBufferPrefetcher::getPSMapping(Addr paddr, bool is_secure)
 {
     Addr amc_address = paddr / prefetchCandidatesPerEntry;
     Addr map_index   = paddr % prefetchCandidatesPerEntry;
     AddressMappingEntry *ps_entry =
         psAddressMappingCache.findEntry(amc_address, is_secure);
     if (ps_entry != nullptr) {
         // A PS-AMC line already exists
         psAddressMappingCache.accessEntry(ps_entry);
     } else {
         ps_entry = psAddressMappingCache.findVictim(amc_address);
         assert(ps_entry != nullptr);

         psAddressMappingCache.insertEntry(amc_address, is_secure, ps_entry);
     }
     return ps_entry->mappings[map_index];
 }

 void
 IrregularStreamBufferPrefetcher::addStructuralToPhysicalEntry(
     Addr structural_address, bool is_secure, Addr physical_address)
 {
     Addr amc_address = structural_address / prefetchCandidatesPerEntry;
     Addr map_index   = structural_address % prefetchCandidatesPerEntry;
     AddressMappingEntry *sp_entry =
         spAddressMappingCache.findEntry(amc_address, is_secure);
     if (sp_entry != nullptr) {
         spAddressMappingCache.accessEntry(sp_entry);
     } else {
         sp_entry = spAddressMappingCache.findVictim(amc_address);
         assert(sp_entry != nullptr);

         spAddressMappingCache.insertEntry(amc_address, is_secure, sp_entry);
     }
     AddressMapping &mapping = sp_entry->mappings[map_index];
     mapping.address = physical_address;
     mapping.counter = 1;
 }

 IrregularStreamBufferPrefetcher*
 IrregularStreamBufferPrefetcherParams::create()
 {
     return new IrregularStreamBufferPrefetcher(this);
 }
	/**
	* Copyright (c) 2018 Metempsy Technology Consulting
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met: redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer;
	* redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution;
	* neither the name of the copyright holders nor the names of its
	* contributors may be used to endorse or promote products derived from
	* this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*
	* Authors: Javier Bueno
	*/

	#include "mem/cache/prefetch/irregular_stream_buffer.hh"

	#include "debug/HWPrefetch.hh"
	#include "mem/cache/prefetch/associative_set_impl.hh"
	#include "params/IrregularStreamBufferPrefetcher.hh"

	IrregularStreamBufferPrefetcher::IrregularStreamBufferPrefetcher(
	const IrregularStreamBufferPrefetcherParams *p)
	: QueuedPrefetcher(p), maxCounterValue(p->max_counter_value),
	chunkSize(p->chunk_size),
	prefetchCandidatesPerEntry(p->prefetch_candidates_per_entry),
	degree(p->degree),
	trainingUnit(p->training_unit_assoc, p->training_unit_entries,
	p->training_unit_indexing_policy,
	p->training_unit_replacement_policy),
	psAddressMappingCache(p->address_map_cache_assoc,
	p->address_map_cache_entries,
	p->ps_address_map_cache_indexing_policy,
	p->ps_address_map_cache_replacement_policy,
	AddressMappingEntry(prefetchCandidatesPerEntry)),
	spAddressMappingCache(p->address_map_cache_assoc,
	p->address_map_cache_entries,
	p->sp_address_map_cache_indexing_policy,
	p->sp_address_map_cache_replacement_policy,
	AddressMappingEntry(prefetchCandidatesPerEntry)),
	structuralAddressCounter(0)
	{
	assert(isPowerOf2(prefetchCandidatesPerEntry));
	}

	void
	IrregularStreamBufferPrefetcher::calculatePrefetch(const PrefetchInfo &pfi,
	std::vector<AddrPriority> &addresses)
	{
	// This prefetcher requires a PC
	if (!pfi.hasPC()) {
	return;
	}
	bool is_secure = pfi.isSecure();
	Addr pc = pfi.getPC();
	Addr addr = blockIndex(pfi.getAddr());

	// Training, if the entry exists, then we found a correlation between
	// the entry lastAddress (named as correlated_addr_A) and the address of
	// the current access (named as correlated_addr_B)
	TrainingUnitEntry *entry = trainingUnit.findEntry(pc, is_secure);
	bool correlated_addr_found = false;
	Addr correlated_addr_A = 0;
	Addr correlated_addr_B = 0;
	if (entry != nullptr && entry->lastAddressSecure == is_secure) {
	trainingUnit.accessEntry(entry);
	correlated_addr_found = true;
	correlated_addr_A = entry->lastAddress;
	correlated_addr_B = addr;
	} else {
	entry = trainingUnit.findVictim(pc);
	assert(entry != nullptr);

	trainingUnit.insertEntry(pc, is_secure, entry);
	}
	// Update the entry
	entry->lastAddress = addr;
	entry->lastAddressSecure = is_secure;

	if (correlated_addr_found) {
	// If a correlation was found, update the Physical-to-Structural
	// table accordingly
	AddressMapping &mapping_A = getPSMapping(correlated_addr_A, is_secure);
	AddressMapping &mapping_B = getPSMapping(correlated_addr_B, is_secure);
	if (mapping_A.counter > 0 && mapping_B.counter > 0) {
	// Entry for A and B
	if (mapping_B.address == (mapping_A.address + 1)) {
	if (mapping_B.counter < maxCounterValue) {
	mapping_B.counter += 1;
	}
	} else {
	if (mapping_B.counter == 1) {
	// counter would hit 0, reassign address
	mapping_B.counter = 1;
	mapping_B.address = mapping_A.address + 1;
	addStructuralToPhysicalEntry(mapping_B.address, is_secure,
	correlated_addr_B);
	} else {
	mapping_B.counter -= 1;
	}
	}
	} else {
	if (mapping_A.counter == 0) {
	// if A is not valid, generate a new structural address
	mapping_A.counter = 1;
	mapping_A.address = structuralAddressCounter;
	structuralAddressCounter += chunkSize;
	addStructuralToPhysicalEntry(mapping_A.address,
	is_secure, correlated_addr_A);
	}
	mapping_B.counter = 1;
	mapping_B.address = mapping_A.address + 1;
	// update SP-AMC
	addStructuralToPhysicalEntry(mapping_B.address, is_secure,
	correlated_addr_B);
	}
	}

	// Use the PS mapping to predict future accesses using the current address
	// - Look for the structured address
	// - if it exists, use it to generate prefetches for the subsequent
	// addresses in ascending order, as many as indicated by the degree
	// (given the structured address S, prefetch S+1, S+2, .. up to S+degree)
	Addr amc_address = addr / prefetchCandidatesPerEntry;
	Addr map_index = addr % prefetchCandidatesPerEntry;
	AddressMappingEntry *ps_am = psAddressMappingCache.findEntry(amc_address,
	is_secure);
	if (ps_am != nullptr) {
	AddressMapping &mapping = ps_am->mappings[map_index];
	if (mapping.counter > 0) {
	Addr sp_address = mapping.address / prefetchCandidatesPerEntry;
	Addr sp_index = mapping.address % prefetchCandidatesPerEntry;
	AddressMappingEntry *sp_am =
	spAddressMappingCache.findEntry(sp_address, is_secure);
	assert(sp_am != nullptr);
	for (unsigned d = 1;
	d <= degree && (sp_index + d) < prefetchCandidatesPerEntry;
	d += 1)
	{
	AddressMapping &spm = sp_am->mappings[sp_index + d];
	//generate prefetch
	if (spm.counter > 0) {
	Addr pf_addr = spm.address << lBlkSize;
	addresses.push_back(AddrPriority(pf_addr, 0));
	}
	}
	}
	}
	}

	IrregularStreamBufferPrefetcher::AddressMapping&
	IrregularStreamBufferPrefetcher::getPSMapping(Addr paddr, bool is_secure)
	{
	Addr amc_address = paddr / prefetchCandidatesPerEntry;
	Addr map_index = paddr % prefetchCandidatesPerEntry;
	AddressMappingEntry *ps_entry =
	psAddressMappingCache.findEntry(amc_address, is_secure);
	if (ps_entry != nullptr) {
	// A PS-AMC line already exists
	psAddressMappingCache.accessEntry(ps_entry);
	} else {
	ps_entry = psAddressMappingCache.findVictim(amc_address);
	assert(ps_entry != nullptr);

	psAddressMappingCache.insertEntry(amc_address, is_secure, ps_entry);
	}
	return ps_entry->mappings[map_index];
	}

	void
	IrregularStreamBufferPrefetcher::addStructuralToPhysicalEntry(
	Addr structural_address, bool is_secure, Addr physical_address)
	{
	Addr amc_address = structural_address / prefetchCandidatesPerEntry;
	Addr map_index = structural_address % prefetchCandidatesPerEntry;
	AddressMappingEntry *sp_entry =
	spAddressMappingCache.findEntry(amc_address, is_secure);
	if (sp_entry != nullptr) {
	spAddressMappingCache.accessEntry(sp_entry);
	} else {
	sp_entry = spAddressMappingCache.findVictim(amc_address);
	assert(sp_entry != nullptr);

	spAddressMappingCache.insertEntry(amc_address, is_secure, sp_entry);
	}
	AddressMapping &mapping = sp_entry->mappings[map_index];
	mapping.address = physical_address;
	mapping.counter = 1;
	}

	IrregularStreamBufferPrefetcher*
	IrregularStreamBufferPrefetcherParams::create()
	{
	return new IrregularStreamBufferPrefetcher(this);
	}