src/mem/cache/prefetch/signature_path.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/signature_path.hh"

 #include <cassert>

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

 SignaturePathPrefetcher::SignaturePathPrefetcher(
     const SignaturePathPrefetcherParams *p)
     : QueuedPrefetcher(p),
       stridesPerPatternEntry(p->strides_per_pattern_entry),
       signatureShift(p->signature_shift),
       signatureBits(p->signature_bits),
       maxCounterValue(p->max_counter_value),
       prefetchConfidenceThreshold(p->prefetch_confidence_threshold),
       lookaheadConfidenceThreshold(p->lookahead_confidence_threshold),
       signatureTable(p->signature_table_assoc, p->signature_table_entries,
                      p->signature_table_indexing_policy,
                      p->signature_table_replacement_policy),
       patternTable(p->pattern_table_assoc, p->pattern_table_entries,
                    p->pattern_table_indexing_policy,
                    p->pattern_table_replacement_policy,
                    PatternEntry(stridesPerPatternEntry))
 {
     fatal_if(prefetchConfidenceThreshold < 0,
         "The prefetch confidence threshold must be greater than 0\n");
     fatal_if(prefetchConfidenceThreshold > 1,
         "The prefetch confidence threshold must be less than 1\n");
     fatal_if(lookaheadConfidenceThreshold < 0,
         "The lookahead confidence threshold must be greater than 0\n");
     fatal_if(lookaheadConfidenceThreshold > 1,
         "The lookahead confidence threshold must be less than 1\n");
 }

 SignaturePathPrefetcher::PatternStrideEntry &
 SignaturePathPrefetcher::PatternEntry::getStrideEntry(stride_t stride,
                                                      uint8_t max_counter_value)
 {
     PatternStrideEntry *pstride_entry = findStride(stride);
     if (pstride_entry == nullptr) {
         // Specific replacement algorithm for this table,
         // pick the entry with the lowest counter value,
         // then decrease the counter of all entries

         // If all counters have the max value, this will be the pick
         PatternStrideEntry *victim_pstride_entry = &(strideEntries[0]);

         uint8_t current_counter = max_counter_value;
         for (auto &entry : strideEntries) {
             if (entry.counter < current_counter) {
                 victim_pstride_entry = &entry;
                 current_counter = entry.counter;
             }
             if (entry.counter > 0) {
                 entry.counter -= 1;
             }
         }
         pstride_entry = victim_pstride_entry;
         pstride_entry->counter = 0;
         pstride_entry->stride = stride;
     }
     return *pstride_entry;
 }

 void
 SignaturePathPrefetcher::addPrefetch(Addr ppn, stride_t last_block,
     stride_t delta, double path_confidence, signature_t signature,
     bool is_secure, std::vector<AddrPriority> &addresses)
 {
     stride_t block = last_block + delta;

     Addr pf_ppn;
     stride_t pf_block;
     if (block < 0) {
         stride_t num_cross_pages = 1 + (-block) / (pageBytes/blkSize);
         if (num_cross_pages > ppn) {
             // target address smaller than page 0, ignore this request;
             return;
         }
         pf_ppn = ppn - num_cross_pages;
         pf_block = block + (pageBytes/blkSize) * num_cross_pages;
         handlePageCrossingLookahead(signature, last_block, delta,
                                     path_confidence);
     } else if (block >= (pageBytes/blkSize)) {
         stride_t num_cross_pages = block / (pageBytes/blkSize);
         if (MaxAddr/pageBytes < (ppn + num_cross_pages)) {
             // target address goes beyond MaxAddr, ignore this request;
             return;
         }
         pf_ppn = ppn + num_cross_pages;
         pf_block = block - (pageBytes/blkSize) * num_cross_pages;
         handlePageCrossingLookahead(signature, last_block, delta,
                                     path_confidence);
     } else {
         pf_ppn = ppn;
         pf_block = block;
     }

     Addr new_addr = pf_ppn * pageBytes;
     new_addr += pf_block * (Addr)blkSize;

     DPRINTF(HWPrefetch, "Queuing prefetch to %#x.\n", new_addr);
     addresses.push_back(AddrPriority(new_addr, 0));
 }

 void
 SignaturePathPrefetcher::handleSignatureTableMiss(stride_t current_block,
     signature_t &new_signature, double &new_conf, stride_t &new_stride)
 {
     new_signature = current_block;
     new_conf = 1.0;
     new_stride = current_block;
 }

 void
 SignaturePathPrefetcher::increasePatternEntryCounter(
         PatternEntry &pattern_entry, PatternStrideEntry &pstride_entry)
 {
     if (pstride_entry.counter < maxCounterValue) {
         pstride_entry.counter += 1;
     }
 }

 void
 SignaturePathPrefetcher::updatePatternTable(Addr signature, stride_t stride)
 {
     assert(stride != 0);
     // The pattern table is indexed by signatures
     PatternEntry &p_entry = getPatternEntry(signature);
     PatternStrideEntry &ps_entry = p_entry.getStrideEntry(stride,
                                                           maxCounterValue);
     increasePatternEntryCounter(p_entry, ps_entry);
 }

 SignaturePathPrefetcher::SignatureEntry &
 SignaturePathPrefetcher::getSignatureEntry(Addr ppn, bool is_secure,
         stride_t block, bool &miss, stride_t &stride,
         double &initial_confidence)
 {
     SignatureEntry* signature_entry = signatureTable.findEntry(ppn, is_secure);
     if (signature_entry != nullptr) {
         signatureTable.accessEntry(signature_entry);
         miss = false;
         stride = block - signature_entry->lastBlock;
     } else {
         signature_entry = signatureTable.findVictim(ppn);
         assert(signature_entry != nullptr);

         // Sets signature_entry->signature, initial_confidence, and stride
         handleSignatureTableMiss(block, signature_entry->signature,
             initial_confidence, stride);

         signatureTable.insertEntry(ppn, is_secure, signature_entry);
         miss = true;
     }
     signature_entry->lastBlock = block;
     return *signature_entry;
 }

 SignaturePathPrefetcher::PatternEntry &
 SignaturePathPrefetcher::getPatternEntry(Addr signature)
 {
     PatternEntry* pattern_entry = patternTable.findEntry(signature, false);
     if (pattern_entry != nullptr) {
         // Signature found
         patternTable.accessEntry(pattern_entry);
     } else {
         // Signature not found
         pattern_entry = patternTable.findVictim(signature);
         assert(pattern_entry != nullptr);

         patternTable.insertEntry(signature, false, pattern_entry);
     }
     return *pattern_entry;
 }

 double
 SignaturePathPrefetcher::calculatePrefetchConfidence(PatternEntry const &sig,
         PatternStrideEntry const &entry) const
 {
     return ((double) entry.counter) / maxCounterValue;
 }

 double
 SignaturePathPrefetcher::calculateLookaheadConfidence(PatternEntry const &sig,
         PatternStrideEntry const &lookahead) const
 {
     double lookahead_confidence;
     if (lookahead.counter == maxCounterValue) {
         /**
          * maximum confidence is 0.95, guaranteeing that
          * current confidence will eventually fall beyond
          * the threshold
          */
         lookahead_confidence = 0.95;
     } else {
         lookahead_confidence = ((double) lookahead.counter / maxCounterValue);
     }
     return lookahead_confidence;
 }

 void
 SignaturePathPrefetcher::calculatePrefetch(const PrefetchInfo &pfi,
                                  std::vector<AddrPriority> &addresses)
 {
     Addr request_addr = pfi.getAddr();
     Addr ppn = request_addr / pageBytes;
     stride_t current_block = (request_addr % pageBytes) / blkSize;
     stride_t stride;
     bool is_secure = pfi.isSecure();
     double initial_confidence = 1.0;

     // Get the SignatureEntry of this page to:
     // - compute the current stride
     // - obtain the current signature of accesses
     bool miss;
     SignatureEntry &signature_entry = getSignatureEntry(ppn, is_secure,
             current_block, miss, stride, initial_confidence);

     if (miss) {
         // No history for this page, can't continue
         return;
     }

     if (stride == 0) {
         // Can't continue with a stride 0
         return;
     }

     // Update the confidence of the current signature
     updatePatternTable(signature_entry.signature, stride);

     // Update the current SignatureEntry signature
     signature_entry.signature =
         updateSignature(signature_entry.signature, stride);

     signature_t current_signature = signature_entry.signature;
     double current_confidence = initial_confidence;
     stride_t current_stride = signature_entry.lastBlock;

     // Look for prefetch candidates while the current path confidence is
     // high enough
     while (current_confidence > lookaheadConfidenceThreshold) {
         // With the updated signature, attempt to generate prefetches
         // - search the PatternTable and select all entries with enough
         //   confidence, these are prefetch candidates
         // - select the entry with the highest counter as the "lookahead"
         PatternEntry *current_pattern_entry =
             patternTable.findEntry(current_signature, false);
         PatternStrideEntry const *lookahead = nullptr;
         if (current_pattern_entry != nullptr) {
             uint8_t max_counter = 0;
             for (auto const &entry : current_pattern_entry->strideEntries) {
                 //select the entry with the maximum counter value as lookahead
                 if (max_counter < entry.counter) {
                     max_counter = entry.counter;
                     lookahead = &entry;
                 }
                 double prefetch_confidence =
                     calculatePrefetchConfidence(*current_pattern_entry, entry);

                 if (prefetch_confidence >= prefetchConfidenceThreshold) {
                     assert(entry.stride != 0);
                     //prefetch candidate
                     addPrefetch(ppn, current_stride, entry.stride,
                                 current_confidence, current_signature,
                                 is_secure, addresses);
                 }
             }
         }

         if (lookahead != nullptr) {
             current_confidence *= calculateLookaheadConfidence(
                     *current_pattern_entry, *lookahead);
             current_signature =
                 updateSignature(current_signature, lookahead->stride);
             current_stride += lookahead->stride;
         } else {
             current_confidence = 0.0;
         }
     }

     auxiliaryPrefetcher(ppn, current_block, is_secure, addresses);
 }

 void
 SignaturePathPrefetcher::auxiliaryPrefetcher(Addr ppn, stride_t current_block,
         bool is_secure, std::vector<AddrPriority> &addresses)
 {
     if (addresses.empty()) {
         // Enable the next line prefetcher if no prefetch candidates are found
         addPrefetch(ppn, current_block, 1, 0.0 /* unused*/, 0 /* unused */,
                     is_secure, addresses);
     }
 }

 SignaturePathPrefetcher*
 SignaturePathPrefetcherParams::create()
 {
     return new SignaturePathPrefetcher(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/signature_path.hh"

	#include <cassert>

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

	SignaturePathPrefetcher::SignaturePathPrefetcher(
	const SignaturePathPrefetcherParams *p)
	: QueuedPrefetcher(p),
	stridesPerPatternEntry(p->strides_per_pattern_entry),
	signatureShift(p->signature_shift),
	signatureBits(p->signature_bits),
	maxCounterValue(p->max_counter_value),
	prefetchConfidenceThreshold(p->prefetch_confidence_threshold),
	lookaheadConfidenceThreshold(p->lookahead_confidence_threshold),
	signatureTable(p->signature_table_assoc, p->signature_table_entries,
	p->signature_table_indexing_policy,
	p->signature_table_replacement_policy),
	patternTable(p->pattern_table_assoc, p->pattern_table_entries,
	p->pattern_table_indexing_policy,
	p->pattern_table_replacement_policy,
	PatternEntry(stridesPerPatternEntry))
	{
	fatal_if(prefetchConfidenceThreshold < 0,
	"The prefetch confidence threshold must be greater than 0\n");
	fatal_if(prefetchConfidenceThreshold > 1,
	"The prefetch confidence threshold must be less than 1\n");
	fatal_if(lookaheadConfidenceThreshold < 0,
	"The lookahead confidence threshold must be greater than 0\n");
	fatal_if(lookaheadConfidenceThreshold > 1,
	"The lookahead confidence threshold must be less than 1\n");
	}

	SignaturePathPrefetcher::PatternStrideEntry &
	SignaturePathPrefetcher::PatternEntry::getStrideEntry(stride_t stride,
	uint8_t max_counter_value)
	{
	PatternStrideEntry *pstride_entry = findStride(stride);
	if (pstride_entry == nullptr) {
	// Specific replacement algorithm for this table,
	// pick the entry with the lowest counter value,
	// then decrease the counter of all entries

	// If all counters have the max value, this will be the pick
	PatternStrideEntry *victim_pstride_entry = &(strideEntries[0]);

	uint8_t current_counter = max_counter_value;
	for (auto &entry : strideEntries) {
	if (entry.counter < current_counter) {
	victim_pstride_entry = &entry;
	current_counter = entry.counter;
	}
	if (entry.counter > 0) {
	entry.counter -= 1;
	}
	}
	pstride_entry = victim_pstride_entry;
	pstride_entry->counter = 0;
	pstride_entry->stride = stride;
	}
	return *pstride_entry;
	}

	void
	SignaturePathPrefetcher::addPrefetch(Addr ppn, stride_t last_block,
	stride_t delta, double path_confidence, signature_t signature,
	bool is_secure, std::vector<AddrPriority> &addresses)
	{
	stride_t block = last_block + delta;

	Addr pf_ppn;
	stride_t pf_block;
	if (block < 0) {
	stride_t num_cross_pages = 1 + (-block) / (pageBytes/blkSize);
	if (num_cross_pages > ppn) {
	// target address smaller than page 0, ignore this request;
	return;
	}
	pf_ppn = ppn - num_cross_pages;
	pf_block = block + (pageBytes/blkSize) * num_cross_pages;
	handlePageCrossingLookahead(signature, last_block, delta,
	path_confidence);
	} else if (block >= (pageBytes/blkSize)) {
	stride_t num_cross_pages = block / (pageBytes/blkSize);
	if (MaxAddr/pageBytes < (ppn + num_cross_pages)) {
	// target address goes beyond MaxAddr, ignore this request;
	return;
	}
	pf_ppn = ppn + num_cross_pages;
	pf_block = block - (pageBytes/blkSize) * num_cross_pages;
	handlePageCrossingLookahead(signature, last_block, delta,
	path_confidence);
	} else {
	pf_ppn = ppn;
	pf_block = block;
	}

	Addr new_addr = pf_ppn * pageBytes;
	new_addr += pf_block * (Addr)blkSize;

	DPRINTF(HWPrefetch, "Queuing prefetch to %#x.\n", new_addr);
	addresses.push_back(AddrPriority(new_addr, 0));
	}

	void
	SignaturePathPrefetcher::handleSignatureTableMiss(stride_t current_block,
	signature_t &new_signature, double &new_conf, stride_t &new_stride)
	{
	new_signature = current_block;
	new_conf = 1.0;
	new_stride = current_block;
	}

	void
	SignaturePathPrefetcher::increasePatternEntryCounter(
	PatternEntry &pattern_entry, PatternStrideEntry &pstride_entry)
	{
	if (pstride_entry.counter < maxCounterValue) {
	pstride_entry.counter += 1;
	}
	}

	void
	SignaturePathPrefetcher::updatePatternTable(Addr signature, stride_t stride)
	{
	assert(stride != 0);
	// The pattern table is indexed by signatures
	PatternEntry &p_entry = getPatternEntry(signature);
	PatternStrideEntry &ps_entry = p_entry.getStrideEntry(stride,
	maxCounterValue);
	increasePatternEntryCounter(p_entry, ps_entry);
	}

	SignaturePathPrefetcher::SignatureEntry &
	SignaturePathPrefetcher::getSignatureEntry(Addr ppn, bool is_secure,
	stride_t block, bool &miss, stride_t &stride,
	double &initial_confidence)
	{
	SignatureEntry* signature_entry = signatureTable.findEntry(ppn, is_secure);
	if (signature_entry != nullptr) {
	signatureTable.accessEntry(signature_entry);
	miss = false;
	stride = block - signature_entry->lastBlock;
	} else {
	signature_entry = signatureTable.findVictim(ppn);
	assert(signature_entry != nullptr);

	// Sets signature_entry->signature, initial_confidence, and stride
	handleSignatureTableMiss(block, signature_entry->signature,
	initial_confidence, stride);

	signatureTable.insertEntry(ppn, is_secure, signature_entry);
	miss = true;
	}
	signature_entry->lastBlock = block;
	return *signature_entry;
	}

	SignaturePathPrefetcher::PatternEntry &
	SignaturePathPrefetcher::getPatternEntry(Addr signature)
	{
	PatternEntry* pattern_entry = patternTable.findEntry(signature, false);
	if (pattern_entry != nullptr) {
	// Signature found
	patternTable.accessEntry(pattern_entry);
	} else {
	// Signature not found
	pattern_entry = patternTable.findVictim(signature);
	assert(pattern_entry != nullptr);

	patternTable.insertEntry(signature, false, pattern_entry);
	}
	return *pattern_entry;
	}

	double
	SignaturePathPrefetcher::calculatePrefetchConfidence(PatternEntry const &sig,
	PatternStrideEntry const &entry) const
	{
	return ((double) entry.counter) / maxCounterValue;
	}

	double
	SignaturePathPrefetcher::calculateLookaheadConfidence(PatternEntry const &sig,
	PatternStrideEntry const &lookahead) const
	{
	double lookahead_confidence;
	if (lookahead.counter == maxCounterValue) {
	/**
	* maximum confidence is 0.95, guaranteeing that
	* current confidence will eventually fall beyond
	* the threshold
	*/
	lookahead_confidence = 0.95;
	} else {
	lookahead_confidence = ((double) lookahead.counter / maxCounterValue);
	}
	return lookahead_confidence;
	}

	void
	SignaturePathPrefetcher::calculatePrefetch(const PrefetchInfo &pfi,
	std::vector<AddrPriority> &addresses)
	{
	Addr request_addr = pfi.getAddr();
	Addr ppn = request_addr / pageBytes;
	stride_t current_block = (request_addr % pageBytes) / blkSize;
	stride_t stride;
	bool is_secure = pfi.isSecure();
	double initial_confidence = 1.0;

	// Get the SignatureEntry of this page to:
	// - compute the current stride
	// - obtain the current signature of accesses
	bool miss;
	SignatureEntry &signature_entry = getSignatureEntry(ppn, is_secure,
	current_block, miss, stride, initial_confidence);

	if (miss) {
	// No history for this page, can't continue
	return;
	}

	if (stride == 0) {
	// Can't continue with a stride 0
	return;
	}

	// Update the confidence of the current signature
	updatePatternTable(signature_entry.signature, stride);

	// Update the current SignatureEntry signature
	signature_entry.signature =
	updateSignature(signature_entry.signature, stride);

	signature_t current_signature = signature_entry.signature;
	double current_confidence = initial_confidence;
	stride_t current_stride = signature_entry.lastBlock;

	// Look for prefetch candidates while the current path confidence is
	// high enough
	while (current_confidence > lookaheadConfidenceThreshold) {
	// With the updated signature, attempt to generate prefetches
	// - search the PatternTable and select all entries with enough
	// confidence, these are prefetch candidates
	// - select the entry with the highest counter as the "lookahead"
	PatternEntry *current_pattern_entry =
	patternTable.findEntry(current_signature, false);
	PatternStrideEntry const *lookahead = nullptr;
	if (current_pattern_entry != nullptr) {
	uint8_t max_counter = 0;
	for (auto const &entry : current_pattern_entry->strideEntries) {
	//select the entry with the maximum counter value as lookahead
	if (max_counter < entry.counter) {
	max_counter = entry.counter;
	lookahead = &entry;
	}
	double prefetch_confidence =
	calculatePrefetchConfidence(*current_pattern_entry, entry);

	if (prefetch_confidence >= prefetchConfidenceThreshold) {
	assert(entry.stride != 0);
	//prefetch candidate
	addPrefetch(ppn, current_stride, entry.stride,
	current_confidence, current_signature,
	is_secure, addresses);
	}
	}
	}

	if (lookahead != nullptr) {
	current_confidence *= calculateLookaheadConfidence(
	current_pattern_entry, lookahead);
	current_signature =
	updateSignature(current_signature, lookahead->stride);
	current_stride += lookahead->stride;
	} else {
	current_confidence = 0.0;
	}
	}

	auxiliaryPrefetcher(ppn, current_block, is_secure, addresses);
	}

	void
	SignaturePathPrefetcher::auxiliaryPrefetcher(Addr ppn, stride_t current_block,
	bool is_secure, std::vector<AddrPriority> &addresses)
	{
	if (addresses.empty()) {
	// Enable the next line prefetcher if no prefetch candidates are found
	addPrefetch(ppn, current_block, 1, 0.0 /* unused/, 0 / unused */,
	is_secure, addresses);
	}
	}

	SignaturePathPrefetcher*
	SignaturePathPrefetcherParams::create()
	{
	return new SignaturePathPrefetcher(this);
	}