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/*
* Copyright (c) 2013-2015 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* 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: Rene de Jong
*/
/** @file
* This simplistic flash model is designed to model managed SLC NAND flash.
* This device will need an interface module (such as NVMe or UFS); Note that
* this model only calculates the delay and does not perform the actual
* transaction.
*
* To access the memory, use either readMemory or writeMemory. This will
* schedule an event at the tick where the action will finish. If a callback
* has been given as argument then that function will be called on completion
* of that event. Note that this does not guarantee that there are no other
* actions pending in the flash device.
*
* IMPORTANT: number of planes should be a power of 2.
*/
#include "dev/arm/flash_device.hh"
#include "debug/Drain.hh"
/**
* Create this device
*/
FlashDevice*
FlashDeviceParams::create()
{
return new FlashDevice(this);
}
/**
* Flash Device constructor and destructor
*/
FlashDevice::FlashDevice(const FlashDeviceParams* p):
AbstractNVM(p),
diskSize(0),
blockSize(p->blk_size),
pageSize(p->page_size),
GCActivePercentage(p->GC_active),
readLatency(p->read_lat),
writeLatency(p->write_lat),
eraseLatency(p->erase_lat),
dataDistribution(p->data_distribution),
numPlanes(p->num_planes),
pagesPerBlock(0),
pagesPerDisk(0),
blocksPerDisk(0),
planeMask(numPlanes - 1),
planeEventQueue(numPlanes),
planeEvent(this)
{
/*
* Let 'a' be a power of two of n bits, written such that a-n is the msb
* and a-0 is the lsb. Since it is a power of two, only one bit (a-x,
* with 0 <= x <= n) is set. If we subtract one from this number the bits
* a-(x-1) to a-0 are set and all the other bits are cleared. Hence a
* bitwise AND with those two numbers results in an integer with all bits
* cleared.
*/
if(numPlanes & planeMask)
fatal("Number of planes is not a power of 2 in flash device.\n");
}
/**
* Initiates all the flash functions: initializes the lookup tables, age of
* the device, etc. This can only be done once the disk image is known.
* Thats why it can't be done in the constructor.
*/
void
FlashDevice::initializeFlash(uint64_t disk_size, uint32_t sector_size)
{
diskSize = disk_size * sector_size;
pagesPerBlock = blockSize / pageSize;
pagesPerDisk = diskSize / pageSize;
blocksPerDisk = diskSize / blockSize;
/** Sanity information: check flash configuration */
DPRINTF(FlashDevice, "diskSize: %d Bytes; %d pages per block, %d pages "
"per disk\n", diskSize, pagesPerBlock, pagesPerDisk);
locationTable.resize(pagesPerDisk);
/**Garbage collection related*/
blockValidEntries.resize(blocksPerDisk, 0);
blockEmptyEntries.resize(blocksPerDisk, pagesPerBlock);
/**
* This is a bitmap. Every bit is a page
* unknownPages is a vector of 32 bit integers. If every page was an
* integer, the total size would be pagesPerDisk; since we can map one
* page per bit we need ceil(pagesPerDisk/32) entries. 32 = 1 << 5 hence
* it will do to just shift pagesPerDisk five positions and add one. This
* will allocate one integer to many for this data structure in the worst
* case.
*/
unknownPages.resize((pagesPerDisk >> 5) + 1, 0xFFFFFFFF);
for (uint32_t count = 0; count < pagesPerDisk; count++) {
//setup lookup table + physical aspects
if (dataDistribution == Enums::stripe) {
locationTable[count].page = count / blocksPerDisk;
locationTable[count].block = count % blocksPerDisk;
} else {
locationTable[count].page = count % pagesPerBlock;
locationTable[count].block = count / pagesPerBlock;
}
}
}
FlashDevice::~FlashDevice()
{
DPRINTF(FlashDevice, "Remove FlashDevice\n");
}
/**
* Handles the accesses to the device.
* The function determines when certain actions are scheduled and schedules
* an event that uses the callback function on completion of the action.
*/
void
FlashDevice::accessDevice(uint64_t address, uint32_t amount, Callback *event,
Actions action)
{
DPRINTF(FlashDevice, "Flash calculation for %d bytes in %d pages\n"
, amount, pageSize);
std::vector<Tick> time(numPlanes, 0);
uint64_t logic_page_addr = address / pageSize;
uint32_t plane_address = 0;
/**
* The access will be broken up in a number of page accesses. The number
* of page accesses depends on the amount that needs to be transfered.
* The assumption here is that the interface is completely ignorant of
* the page size and that this model has to figure out all of the
* transaction characteristics.
*/
for (uint32_t count = 0; amount > (count * pageSize); count++) {
uint32_t index = (locationTable[logic_page_addr].block *
pagesPerBlock) + (logic_page_addr % pagesPerBlock);
DPRINTF(FlashDevice, "Index 0x%8x, Block 0x%8x, pages/block %d,"
" logic address 0x%8x\n", index,
locationTable[logic_page_addr].block, pagesPerBlock,
logic_page_addr);
DPRINTF(FlashDevice, "Page %d; %d bytes up to this point\n", count,
(count * pageSize));
plane_address = locationTable[logic_page_addr].block & planeMask;
if (action == ActionRead) {
//lookup
//call accessTimes
time[plane_address] += accessTimes(locationTable[logic_page_addr]
.block, ActionRead);
/*stats*/
stats.readAccess.sample(logic_page_addr);
stats.readLatency.sample(time[plane_address]);
} else { //write
//lookup
//call accessTimes if appropriate, page may be unknown, so lets
//give it the benefit of the doubt
if (getUnknownPages(index))
time[plane_address] += accessTimes
(locationTable[logic_page_addr].block, ActionWrite);
else //A remap is needed
time[plane_address] += remap(logic_page_addr);
/*stats*/
stats.writeAccess.sample(logic_page_addr);
stats.writeLatency.sample(time[plane_address]);
}
/**
* Check if the page is known and used. unknownPages is a bitmap of
* all the pages. It tracks wether we can be sure that the
* information of this page is taken into acount in the model (is it
* considered in blockValidEntries and blockEmptyEntries?). If it has
* been used in the past, then it is known.
*/
if (getUnknownPages(index)) {
clearUnknownPages(index);
--blockEmptyEntries[locationTable[logic_page_addr].block];
++blockValidEntries[locationTable[logic_page_addr].block];
}
stats.fileSystemAccess.sample(address);
++logic_page_addr;
}
/**
* previous part of the function found the times spend in different
* planes, now lets find the maximum to know when to callback the disk
*/
for (uint32_t count = 0; count < numPlanes; count++){
plane_address = (time[plane_address] > time[count]) ? plane_address
: count;
DPRINTF(FlashDevice, "Plane %d is busy for %d ticks\n", count,
time[count]);
if (time[count] != 0) {
struct CallBackEntry cbe;
/**
* If there are no events for this plane, then add the current
* time to the occupation time; otherwise, plan it after the
* last event. If by chance that event is handled in this tick,
* then we would still end up with the same result.
*/
if (planeEventQueue[count].empty())
cbe.time = time[count] + curTick();
else
cbe.time = time[count] +
planeEventQueue[count].back().time;
cbe.function = NULL;
planeEventQueue[count].push_back(cbe);
DPRINTF(FlashDevice, "scheduled at: %ld\n", cbe.time);
if (!planeEvent.scheduled())
schedule(planeEvent, planeEventQueue[count].back().time);
else if (planeEventQueue[count].back().time < planeEvent.when())
reschedule(planeEvent,
planeEventQueue[plane_address].back().time, true);
}
}
//worst case two plane finish at the same time, each triggers an event
//and this callback will be called once. Maybe before the other plane
//could execute its event, but in the same tick.
planeEventQueue[plane_address].back().function = event;
DPRINTF(FlashDevice, "Callback queued for plane %d; %d in queue\n",
plane_address, planeEventQueue[plane_address].size());
DPRINTF(FlashDevice, "first event @ %d\n", planeEvent.when());
}
/**
* When a plane completes its action, this event is triggered. When a
* callback function was associated with that event, it will be called.
*/
void
FlashDevice::actionComplete()
{
DPRINTF(FlashDevice, "Plane action completed\n");
uint8_t plane_address = 0;
uint8_t next_event = 0;
/**Search for a callback that is supposed to happen in this Tick*/
for (plane_address = 0; plane_address < numPlanes; plane_address++) {
if (!planeEventQueue[plane_address].empty()) {
/**
* Invariant: All queued events are scheduled in the present
* or future.
*/
assert(planeEventQueue[plane_address].front().time >= curTick());
if (planeEventQueue[plane_address].front().time == curTick()) {
/**
* To ensure that the follow-up action is executed correctly,
* the callback entry first need to be cleared before it can
* be called.
*/
Callback *temp = planeEventQueue[plane_address].front().
function;
planeEventQueue[plane_address].pop_front();
/**Found a callback, lets make it happen*/
if (temp != NULL) {
DPRINTF(FlashDevice, "Callback, %d\n", plane_address);
temp->process();
}
}
}
}
/** Find when to schedule the planeEvent next */
for (plane_address = 0; plane_address < numPlanes; plane_address++) {
if (!planeEventQueue[plane_address].empty())
if (planeEventQueue[next_event].empty() ||
(planeEventQueue[plane_address].front().time <
planeEventQueue[next_event].front().time))
next_event = plane_address;
}
/**Schedule the next plane that will be ready (if any)*/
if (!planeEventQueue[next_event].empty()) {
DPRINTF(FlashDevice, "Schedule plane: %d\n", plane_address);
reschedule(planeEvent, planeEventQueue[next_event].front().time, true);
}
checkDrain();
DPRINTF(FlashDevice, "returing from flash event\n");
DPRINTF(FlashDevice, "first event @ %d\n", planeEvent.when());
}
/**
* Handles the remapping of the pages. It is a (I hope) sensible statistic
* approach. asumption: garbage collection happens when a clean is needed
* (may become stochastic function).
*/
Tick
FlashDevice::remap(uint64_t logic_page_addr)
{
/**
* Are there any empty left in this Block, or do we need to do an erase
*/
if (blockEmptyEntries[locationTable[logic_page_addr].block] > 0) {
//just a remap
//update tables
--blockEmptyEntries[locationTable[logic_page_addr].block];
//access to this table won't be sequential anymore
locationTable[logic_page_addr].page = pagesPerBlock + 2;
//access new block
Tick time = accessTimes(locationTable[logic_page_addr].block,
ActionWrite);
DPRINTF(FlashDevice, "Remap returns %d ticks\n", time);
return time;
} else {
//calculate how much time GC would have taken
uint32_t block = locationTable[logic_page_addr].block;
Tick time = ((GCActivePercentage *
(accessTimes(block, ActionCopy) +
accessTimes(block, ActionErase)))
/ 100);
//use block as the logical start address of the block
block = locationTable[logic_page_addr].block * pagesPerBlock;
//assumption: clean will improve locality
for (uint32_t count = 0; count < pageSize; count++) {
locationTable[block + count].page = (block + count) %
pagesPerBlock;
++count;
}
blockEmptyEntries[locationTable[logic_page_addr].block] =
pagesPerBlock;
/*stats*/
++stats.totalGCActivations;
DPRINTF(FlashDevice, "Remap with erase action returns %d ticks\n",
time);
return time;
}
}
/**
* Calculates the accesstime per operation needed
*/
Tick
FlashDevice::accessTimes(uint64_t block, Actions action)
{
Tick time = 0;
switch(action) {
case ActionRead: {
/**Just read the page*/
time = readLatency;
} break;
case ActionWrite: {
/**Write the page, and read the result*/
time = writeLatency + readLatency;
} break;
case ActionErase: {
/**Erase and check wether it was successfull*/
time = eraseLatency + readLatency;
} break;
case ActionCopy: {
/**Copy every valid page*/
uint32_t validpages = blockValidEntries[block];
time = validpages * (readLatency + writeLatency);
} break;
default: break;
}
//Used to determine sequential action.
DPRINTF(FlashDevice, "Access returns %d ticks\n", time);
return time;
}
/**
* clearUnknownPages. defines that a page is known and used
* unknownPages is a bitmap of all the pages. It tracks wether we can be sure
* that the information of this page is taken into acount in the model (is it
* considered in blockValidEntries and blockEmptyEntries?). If it has been
* used in the past, then it is known. But it needs to be tracked to make
* decisions about write accesses, and indirectly about copy actions. one
* unknownPage entry is a 32 bit integer. So if we have a page index, then
* that means that we need entry floor(index/32) (index >> 5) and we need to
* select the bit which number is equal to the remainder of index/32
* (index%32). The bit is cleared to make sure that we see it as considered
* in the future.
*/
inline
void
FlashDevice::clearUnknownPages(uint32_t index)
{
unknownPages[index >> 5] &= ~(0x01 << (index % 32));
}
/**
* getUnknownPages. Verify wether a page is known
*/
inline
bool
FlashDevice::getUnknownPages(uint32_t index)
{
return unknownPages[index >> 5] & (0x01 << (index % 32));
}
void
FlashDevice::regStats()
{
using namespace Stats;
std::string fd_name = name() + ".FlashDevice";
// Register the stats
/** Amount of GC activations*/
stats.totalGCActivations
.name(fd_name + ".totalGCActivations")
.desc("Number of Garbage collector activations")
.flags(none);
/** Histogram of address accesses*/
stats.writeAccess
.init(2)
.name(fd_name + ".writeAccessHist")
.desc("Histogram of write addresses")
.flags(pdf);
stats.readAccess
.init(2)
.name(fd_name + ".readAccessHist")
.desc("Histogram of read addresses")
.flags(pdf);
stats.fileSystemAccess
.init(100)
.name(fd_name + ".fileSystemAccessHist")
.desc("Histogram of file system accesses")
.flags(pdf);
/** Histogram of access latencies*/
stats.writeLatency
.init(100)
.name(fd_name + ".writeLatencyHist")
.desc("Histogram of write latency")
.flags(pdf);
stats.readLatency
.init(100)
.name(fd_name + ".readLatencyHist")
.desc("Histogram of read latency")
.flags(pdf);
}
/**
* Serialize; needed to create checkpoints
*/
void
FlashDevice::serialize(CheckpointOut &cp) const
{
SERIALIZE_SCALAR(planeMask);
int unknown_pages_size = unknownPages.size();
SERIALIZE_SCALAR(unknown_pages_size);
for (uint32_t count = 0; count < unknownPages.size(); count++)
SERIALIZE_SCALAR(unknownPages[count]);
int location_table_size = locationTable.size();
SERIALIZE_SCALAR(location_table_size);
for (uint32_t count = 0; count < location_table_size; count++) {
SERIALIZE_SCALAR(locationTable[count].page);
SERIALIZE_SCALAR(locationTable[count].block);
}
int block_valid_entries_size = blockValidEntries.size();
SERIALIZE_SCALAR(block_valid_entries_size);
for (uint32_t count = 0; count < blockValidEntries.size(); count++)
SERIALIZE_SCALAR(blockValidEntries[count]);
int block_empty_entries_size = blockEmptyEntries.size();
SERIALIZE_SCALAR(block_empty_entries_size);
for (uint32_t count = 0; count < blockEmptyEntries.size(); count++)
SERIALIZE_SCALAR(blockEmptyEntries[count]);
};
/**
* Unserialize; needed to restore from checkpoints
*/
void
FlashDevice::unserialize(CheckpointIn &cp)
{
UNSERIALIZE_SCALAR(planeMask);
int unknown_pages_size;
UNSERIALIZE_SCALAR(unknown_pages_size);
unknownPages.resize(unknown_pages_size);
for (uint32_t count = 0; count < unknown_pages_size; count++)
UNSERIALIZE_SCALAR(unknownPages[count]);
int location_table_size;
UNSERIALIZE_SCALAR(location_table_size);
locationTable.resize(location_table_size);
for (uint32_t count = 0; count < location_table_size; count++) {
UNSERIALIZE_SCALAR(locationTable[count].page);
UNSERIALIZE_SCALAR(locationTable[count].block);
}
int block_valid_entries_size;
UNSERIALIZE_SCALAR(block_valid_entries_size);
blockValidEntries.resize(block_valid_entries_size);
for (uint32_t count = 0; count < block_valid_entries_size; count++)
UNSERIALIZE_SCALAR(blockValidEntries[count]);
int block_empty_entries_size;
UNSERIALIZE_SCALAR(block_empty_entries_size);
blockEmptyEntries.resize(block_empty_entries_size);
for (uint32_t count = 0; count < block_empty_entries_size; count++)
UNSERIALIZE_SCALAR(blockEmptyEntries[count]);
};
/**
* Drain; needed to enable checkpoints
*/
DrainState
FlashDevice::drain()
{
if (planeEvent.scheduled()) {
DPRINTF(Drain, "Flash device is draining...\n");
return DrainState::Draining;
} else {
DPRINTF(Drain, "Flash device in drained state\n");
return DrainState::Drained;
}
}
/**
* Checkdrain; needed to enable checkpoints
*/
void
FlashDevice::checkDrain()
{
if (drainState() == DrainState::Draining)
return;
if (planeEvent.when() > curTick()) {
DPRINTF(Drain, "Flash device is still draining\n");
} else {
DPRINTF(Drain, "Flash device is done draining\n");
signalDrainDone();
}
}
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