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authorAndreas Hansson <andreas.hansson@arm.com>2014-10-16 05:50:01 -0400
committerAndreas Hansson <andreas.hansson@arm.com>2014-10-16 05:50:01 -0400
commit6d4866383feac65beaf8ac5fa18557569e25481d (patch)
tree12a14640394d45802982a9afafb046c8ad7de689 /src
parentedc77fc03cc2f9ef0fb17a34a998b2b957904c93 (diff)
downloadgem5-6d4866383feac65beaf8ac5fa18557569e25481d.tar.xz
mem: Modernise PhysicalMemory with C++11 features
Bring the PhysicalMemory up-to-date by making use of range-based for loops and vector intialisation where possible.
Diffstat (limited to 'src')
-rw-r--r--src/mem/physical.cc106
-rw-r--r--src/mem/physical.hh14
2 files changed, 57 insertions, 63 deletions
diff --git a/src/mem/physical.cc b/src/mem/physical.cc
index 398d0530f..8eacfccb1 100644
--- a/src/mem/physical.cc
+++ b/src/mem/physical.cc
@@ -1,5 +1,5 @@
/*
- * Copyright (c) 2012 ARM Limited
+ * Copyright (c) 2012, 2014 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
@@ -64,34 +64,37 @@ PhysicalMemory::PhysicalMemory(const string& _name,
{
// add the memories from the system to the address map as
// appropriate
- for (vector<AbstractMemory*>::const_iterator m = _memories.begin();
- m != _memories.end(); ++m) {
+ for (const auto& m : _memories) {
// only add the memory if it is part of the global address map
- if ((*m)->isInAddrMap()) {
- memories.push_back(*m);
+ if (m->isInAddrMap()) {
+ memories.push_back(m);
// calculate the total size once and for all
- size += (*m)->size();
+ size += m->size();
// add the range to our interval tree and make sure it does not
// intersect an existing range
- if (addrMap.insert((*m)->getAddrRange(), *m) == addrMap.end())
- fatal("Memory address range for %s is overlapping\n",
- (*m)->name());
+ fatal_if(addrMap.insert(m->getAddrRange(), m) == addrMap.end(),
+ "Memory address range for %s is overlapping\n",
+ m->name());
} else {
- DPRINTF(AddrRanges,
- "Skipping memory %s that is not in global address map\n",
- (*m)->name());
// this type of memory is used e.g. as reference memory by
// Ruby, and they also needs a backing store, but should
// not be part of the global address map
+ DPRINTF(AddrRanges,
+ "Skipping memory %s that is not in global address map\n",
+ m->name());
+
+ // sanity check
+ fatal_if(m->getAddrRange().interleaved(),
+ "Memory %s that is not in the global address map cannot "
+ "be interleaved\n", m->name());
// simply do it independently, also note that this kind of
// memories are allowed to overlap in the logic address
// map
- vector<AbstractMemory*> unmapped_mems;
- unmapped_mems.push_back(*m);
- createBackingStore((*m)->getAddrRange(), unmapped_mems);
+ vector<AbstractMemory*> unmapped_mems{m};
+ createBackingStore(m->getAddrRange(), unmapped_mems);
}
}
@@ -100,29 +103,27 @@ PhysicalMemory::PhysicalMemory(const string& _name,
// memories
vector<AddrRange> intlv_ranges;
vector<AbstractMemory*> curr_memories;
- for (AddrRangeMap<AbstractMemory*>::const_iterator r = addrMap.begin();
- r != addrMap.end(); ++r) {
+ for (const auto& r : addrMap) {
// simply skip past all memories that are null and hence do
// not need any backing store
- if (!r->second->isNull()) {
+ if (!r.second->isNull()) {
// if the range is interleaved then save it for now
- if (r->first.interleaved()) {
+ if (r.first.interleaved()) {
// if we already got interleaved ranges that are not
// part of the same range, then first do a merge
// before we add the new one
if (!intlv_ranges.empty() &&
- !intlv_ranges.back().mergesWith(r->first)) {
+ !intlv_ranges.back().mergesWith(r.first)) {
AddrRange merged_range(intlv_ranges);
createBackingStore(merged_range, curr_memories);
intlv_ranges.clear();
curr_memories.clear();
}
- intlv_ranges.push_back(r->first);
- curr_memories.push_back(r->second);
+ intlv_ranges.push_back(r.first);
+ curr_memories.push_back(r.second);
} else {
- vector<AbstractMemory*> single_memory;
- single_memory.push_back(r->second);
- createBackingStore(r->first, single_memory);
+ vector<AbstractMemory*> single_memory{r.second};
+ createBackingStore(r.first, single_memory);
}
}
}
@@ -139,8 +140,8 @@ void
PhysicalMemory::createBackingStore(AddrRange range,
const vector<AbstractMemory*>& _memories)
{
- if (range.interleaved())
- panic("Cannot create backing store for interleaved range %s\n",
+ panic_if(range.interleaved(),
+ "Cannot create backing store for interleaved range %s\n",
range.to_string());
// perform the actual mmap
@@ -162,20 +163,18 @@ PhysicalMemory::createBackingStore(AddrRange range,
backingStore.push_back(make_pair(range, pmem));
// point the memories to their backing store
- for (vector<AbstractMemory*>::const_iterator m = _memories.begin();
- m != _memories.end(); ++m) {
+ for (const auto& m : _memories) {
DPRINTF(AddrRanges, "Mapping memory %s to backing store\n",
- (*m)->name());
- (*m)->setBackingStore(pmem);
+ m->name());
+ m->setBackingStore(pmem);
}
}
PhysicalMemory::~PhysicalMemory()
{
// unmap the backing store
- for (vector<pair<AddrRange, uint8_t*> >::iterator s = backingStore.begin();
- s != backingStore.end(); ++s)
- munmap((char*)s->second, s->first.size());
+ for (auto& s : backingStore)
+ munmap((char*)s.second, s.first.size());
}
bool
@@ -184,7 +183,7 @@ PhysicalMemory::isMemAddr(Addr addr) const
// see if the address is within the last matched range
if (!rangeCache.contains(addr)) {
// lookup in the interval tree
- AddrRangeMap<AbstractMemory*>::const_iterator r = addrMap.find(addr);
+ const auto& r = addrMap.find(addr);
if (r == addrMap.end()) {
// not in the cache, and not in the tree
return false;
@@ -206,23 +205,22 @@ PhysicalMemory::getConfAddrRanges() const
// be called more than once the iteration should not be a problem
AddrRangeList ranges;
vector<AddrRange> intlv_ranges;
- for (AddrRangeMap<AbstractMemory*>::const_iterator r = addrMap.begin();
- r != addrMap.end(); ++r) {
- if (r->second->isConfReported()) {
+ for (const auto& r : addrMap) {
+ if (r.second->isConfReported()) {
// if the range is interleaved then save it for now
- if (r->first.interleaved()) {
+ if (r.first.interleaved()) {
// if we already got interleaved ranges that are not
// part of the same range, then first do a merge
// before we add the new one
if (!intlv_ranges.empty() &&
- !intlv_ranges.back().mergesWith(r->first)) {
+ !intlv_ranges.back().mergesWith(r.first)) {
ranges.push_back(AddrRange(intlv_ranges));
intlv_ranges.clear();
}
- intlv_ranges.push_back(r->first);
+ intlv_ranges.push_back(r.first);
} else {
// keep the current range
- ranges.push_back(r->first);
+ ranges.push_back(r.first);
}
}
}
@@ -241,7 +239,7 @@ PhysicalMemory::access(PacketPtr pkt)
{
assert(pkt->isRequest());
Addr addr = pkt->getAddr();
- AddrRangeMap<AbstractMemory*>::const_iterator m = addrMap.find(addr);
+ const auto& m = addrMap.find(addr);
assert(m != addrMap.end());
m->second->access(pkt);
}
@@ -251,7 +249,7 @@ PhysicalMemory::functionalAccess(PacketPtr pkt)
{
assert(pkt->isRequest());
Addr addr = pkt->getAddr();
- AddrRangeMap<AbstractMemory*>::const_iterator m = addrMap.find(addr);
+ const auto& m = addrMap.find(addr);
assert(m != addrMap.end());
m->second->functionalAccess(pkt);
}
@@ -263,13 +261,11 @@ PhysicalMemory::serialize(ostream& os)
vector<Addr> lal_addr;
vector<int> lal_cid;
- for (vector<AbstractMemory*>::iterator m = memories.begin();
- m != memories.end(); ++m) {
- const list<LockedAddr>& locked_addrs = (*m)->getLockedAddrList();
- for (list<LockedAddr>::const_iterator l = locked_addrs.begin();
- l != locked_addrs.end(); ++l) {
- lal_addr.push_back(l->addr);
- lal_cid.push_back(l->contextId);
+ for (auto& m : memories) {
+ const list<LockedAddr>& locked_addrs = m->getLockedAddrList();
+ for (const auto& l : locked_addrs) {
+ lal_addr.push_back(l.addr);
+ lal_cid.push_back(l.contextId);
}
}
@@ -282,10 +278,9 @@ PhysicalMemory::serialize(ostream& os)
unsigned int store_id = 0;
// store each backing store memory segment in a file
- for (vector<pair<AddrRange, uint8_t*> >::iterator s = backingStore.begin();
- s != backingStore.end(); ++s) {
+ for (auto& s : backingStore) {
nameOut(os, csprintf("%s.store%d", name(), store_id));
- serializeStore(os, store_id++, s->first, s->second);
+ serializeStore(os, store_id++, s.first, s.second);
}
}
@@ -345,8 +340,7 @@ PhysicalMemory::unserialize(Checkpoint* cp, const string& section)
arrayParamIn(cp, section, "lal_addr", lal_addr);
arrayParamIn(cp, section, "lal_cid", lal_cid);
for(size_t i = 0; i < lal_addr.size(); ++i) {
- AddrRangeMap<AbstractMemory*>::const_iterator m =
- addrMap.find(lal_addr[i]);
+ const auto& m = addrMap.find(lal_addr[i]);
m->second->addLockedAddr(LockedAddr(lal_addr[i], lal_cid[i]));
}
diff --git a/src/mem/physical.hh b/src/mem/physical.hh
index 02fefb478..51ec1cbd3 100644
--- a/src/mem/physical.hh
+++ b/src/mem/physical.hh
@@ -37,11 +37,11 @@
* Authors: Andreas Hansson
*/
-#ifndef __PHYSICAL_MEMORY_HH__
-#define __PHYSICAL_MEMORY_HH__
+#ifndef __MEM_PHYSICAL_HH__
+#define __MEM_PHYSICAL_HH__
#include "base/addr_range_map.hh"
-#include "mem/port.hh"
+#include "mem/packet.hh"
/**
* Forward declaration to avoid header dependencies.
@@ -57,7 +57,7 @@ class AbstractMemory;
* system backingstore used by the memories in the simulated guest
* system. When the system is created, the physical memory allocates
* the backing store based on the address ranges that are populated in
- * the system, and does so indepentent of how those map to actual
+ * the system, and does so independent of how those map to actual
* memory controllers. Thus, the physical memory completely abstracts
* the mapping of the backing store of the host system and the address
* mapping in the guest system. This enables us to arbitrarily change
@@ -86,7 +86,7 @@ class PhysicalMemory : public Serializable
// The physical memory used to provide the memory in the simulated
// system
- std::vector<std::pair<AddrRange, uint8_t*> > backingStore;
+ std::vector<std::pair<AddrRange, uint8_t*>> backingStore;
// Prevent copying
PhysicalMemory(const PhysicalMemory&);
@@ -162,7 +162,7 @@ class PhysicalMemory : public Serializable
*
* @return Pointers to the memory backing store
*/
- std::vector<std::pair<AddrRange, uint8_t*> > getBackingStore() const
+ std::vector<std::pair<AddrRange, uint8_t*>> getBackingStore() const
{ return backingStore; }
/**
@@ -218,4 +218,4 @@ class PhysicalMemory : public Serializable
};
-#endif //__PHYSICAL_MEMORY_HH__
+#endif //__MEM_PHYSICAL_HH__