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/*
* Copyright (c) 2011-2014, 2017-2018 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: Dam Sunwoo
* Matt Horsnell
* Andreas Sandberg
*/
#ifndef __ARCH_ARM_PMU_HH__
#define __ARCH_ARM_PMU_HH__
#include <map>
#include <memory>
#include <vector>
#include "arch/arm/isa_device.hh"
#include "arch/arm/registers.hh"
#include "arch/arm/system.hh"
#include "base/cprintf.hh"
#include "cpu/base.hh"
#include "debug/PMUVerbose.hh"
#include "sim/eventq.hh"
#include "sim/sim_object.hh"
#include "sim/system.hh"
class ArmPMUParams;
class Platform;
class ThreadContext;
class ArmInterruptPin;
namespace ArmISA {
/**
* Model of an ARM PMU version 3
*
* This class implements a subset of the ARM PMU v3 specification as
* described in the ARMv8 reference manual. It supports most of the
* features of the PMU, however the following features are known to be
* missing:
*
* <ul>
* <li>Event filtering (e.g., from different privilege levels).
* <li>Access controls (the PMU currently ignores the execution level).
* <li>The chain counter (event no. 0x1E) is unimplemented.
* </ul>
*
* The PMU itself does not implement any events, in merely provides an
* interface for the configuration scripts to hook up probes that
* drive events. Configuration scripts should call addEventProbe() to
* configure custom events or high-level methods to configure
* architected events. The Python implementation of addEventProbe()
* automatically delays event type registration until after
* instantiation.
*
* In order to support CPU switching and some combined counters (e.g.,
* memory references synthesized from loads and stores), the PMU
* allows multiple probes per event type. When creating a system that
* switches between CPU models that share the same PMU, PMU events for
* all of the CPU models can be registered with the PMU.
*
* @see The ARM Architecture Refererence Manual (DDI 0487A)
*
*/
class PMU : public SimObject, public ArmISA::BaseISADevice {
public:
PMU(const ArmPMUParams *p);
~PMU();
void addEventProbe(unsigned int id, SimObject *obj, const char *name);
void addSoftwareIncrementEvent(unsigned int id);
void registerEvent(uint32_t id);
public: // SimObject and related interfaces
void serialize(CheckpointOut &cp) const override;
void unserialize(CheckpointIn &cp) override;
void drainResume() override;
void regProbeListeners() override;
public: // ISA Device interface
void setThreadContext(ThreadContext *tc) override;
/**
* Set a register within the PMU.
*
* @param misc_reg Register number (see miscregs.hh)
* @param val Value to store
*/
void setMiscReg(int misc_reg, RegVal val) override;
/**
* Read a register within the PMU.
*
* @param misc_reg Register number (see miscregs.hh)
* @return Register value.
*/
RegVal readMiscReg(int misc_reg) override;
protected: // PMU register types and constants
BitUnion32(PMCR_t)
// PMU Enable
Bitfield<0> e;
// Event counter reset
Bitfield<1> p;
// Cycle counter reset
Bitfield<2> c;
// Cycle counter divider enable
Bitfield<3> d;
// Export enable
Bitfield<4> x;
// Disable PMCCNTR when event counting is prohibited
Bitfield<5> dp;
// Long Cycle counter enable
Bitfield<6> lc;
// Number of event counters implemented
Bitfield<15, 11> n;
// Implementation ID
Bitfield<23, 16> idcode;
// Implementer code
Bitfield<31, 24> imp;
EndBitUnion(PMCR_t)
BitUnion32(PMSELR_t)
// Performance counter selector
Bitfield<4, 0> sel;
EndBitUnion(PMSELR_t)
BitUnion32(PMEVTYPER_t)
Bitfield<15, 0> evtCount;
// Secure EL3 filtering
Bitfield<26> m;
// Non-secure EL2 mode filtering
Bitfield<27> nsh;
// Non-secure EL0 mode filtering
Bitfield<28> nsu;
// Non-secure EL1 mode filtering
Bitfield<29> nsk;
// EL0 filtering
Bitfield<30> u;
// EL1 filtering
Bitfield<31> p;
EndBitUnion(PMEVTYPER_t)
/**
* Counter ID within the PMU.
*
* This value is typically used to index into various registers
* controlling interrupts and overflows. The value normally in the
* [0, 31] range, where 31 refers to the cycle counter.
*/
typedef unsigned int CounterId;
/** Cycle Count Register Number */
static const CounterId PMCCNTR = 31;
/**
* Event type ID.
*
* See the PMU documentation for a list of architected IDs.
*/
typedef unsigned int EventTypeId;
protected: /* High-level register and interrupt handling */
RegVal readMiscRegInt(int misc_reg);
/**
* PMCR write handling
*
* The PMCR register needs special handling since writing to it
* changes PMU-global state (e.g., resets all counters).
*
* @param val New PMCR value
*/
void setControlReg(PMCR_t val);
/**
* Reset all event counters excluding the cycle counter to zero.
*/
void resetEventCounts();
/**
* Deliver a PMU interrupt to the GIC
*/
void raiseInterrupt();
/**
* Clear a PMU interrupt.
*/
void clearInterrupt();
/**
* Get the value of a performance counter.
*
* This method returns the value of a general purpose performance
* counter or the fixed-function cycle counter. Non-existing
* counters are treated as constant '0'.
*
* @return Value of the performance counter, 0 if the counter does
* not exist.
*/
uint64_t getCounterValue(CounterId id) const {
return isValidCounter(id) ? getCounter(id).getValue() : 0;
}
/**
* Set the value of a performance counter.
*
* This method sets the value of a general purpose performance
* counter or the fixed-function cycle counter. Writes to
* non-existing counters are ignored.
*/
void setCounterValue(CounterId id, uint64_t val);
/**
* Get the type and filter settings of a counter (PMEVTYPER)
*
* This method implements a read from a PMEVTYPER register. It
* returns the type value and filter settings of a general purpose
* performance counter or the cycle counter. Non-existing counters
* are treated as constant '0'.
*
* @param id Counter ID within the PMU.
* @return Performance counter type ID.
*/
PMEVTYPER_t getCounterTypeRegister(CounterId id) const;
/**
* Set the type and filter settings of a performance counter
* (PMEVTYPER)
*
* This method implements a write to a PMEVTYPER register. It sets
* the type value and filter settings of a general purpose
* performance counter or the cycle counter. Writes to
* non-existing counters are ignored. The method automatically
* updates the probes used by the counter if it is enabled.
*
* @param id Counter ID within the PMU.
* @param type Performance counter type and filter configuration..
*/
void setCounterTypeRegister(CounterId id, PMEVTYPER_t type);
/**
* Used for writing the Overflow Flag Status Register (SET/CLR)
*
* This method implements a write to the PMOVSSET/PMOVSCLR registers.
* It is capturing change of state in the register bits so that
* the overflow interrupt can be raised/cleared as a side effect
* of the write.
*
* @param new_val New value of the Overflow Status Register
*/
void setOverflowStatus(RegVal new_val);
protected: /* Probe handling and counter state */
struct CounterState;
/**
* Event definition base class
*/
struct PMUEvent {
PMUEvent() {}
virtual ~PMUEvent() {}
/**
* attach this event to a given counter
*
* @param a pointer to the counter where to attach this event
*/
void attachEvent(PMU::CounterState *user);
/**
* detach this event from a given counter
*
* @param a pointer to the counter where to detach this event from
*/
void detachEvent(PMU::CounterState *user);
/**
* notify an event increment of val units, all the attached counters'
* value is incremented by val units.
*
* @param the quantity by which to increment the attached counter
* values
*/
virtual void increment(const uint64_t val);
/**
* Enable the current event
*/
virtual void enable() = 0;
/**
* Disable the current event
*/
virtual void disable() = 0;
/**
* Method called immediately before a counter access in order for
* the associated event to update its state (if required)
*/
virtual void updateAttachedCounters() {}
protected:
/** set of counters using this event **/
std::set<PMU::CounterState*> userCounters;
};
struct RegularEvent : public PMUEvent {
typedef std::pair<SimObject*, std::string> EventTypeEntry;
void addMicroarchitectureProbe(SimObject* object,
std::string name) {
panic_if(!object,"malformed probe-point"
" definition with name %s\n", name);
microArchitectureEventSet.emplace(object, name);
}
protected:
struct RegularProbe: public ProbeListenerArgBase<uint64_t>
{
RegularProbe(RegularEvent *parent, SimObject* obj,
std::string name)
: ProbeListenerArgBase(obj->getProbeManager(), name),
parentEvent(parent) {}
RegularProbe() = delete;
void notify(const uint64_t &val);
protected:
RegularEvent *parentEvent;
};
/** The set of events driving the event value **/
std::set<EventTypeEntry> microArchitectureEventSet;
/** Set of probe listeners tapping onto each of the input micro-arch
* events which compose this pmu event
*/
std::vector<std::unique_ptr<RegularProbe>> attachedProbePointList;
void enable() override;
void disable() override;
};
class SWIncrementEvent : public PMUEvent
{
void enable() override {}
void disable() override {}
public:
/**
* write on the sw increment register inducing an increment of the
* counters with this event selected according to the bitfield written.
*
* @param the bitfield selecting the counters to increment.
*/
void write(uint64_t val);
};
/**
* Obtain the event of a given id
*
* @param the id of the event to obtain
* @return a pointer to the event with id eventId
*/
PMUEvent* getEvent(uint64_t eventId);
/** State of a counter within the PMU. **/
struct CounterState : public Serializable {
CounterState(PMU &pmuReference, uint64_t counter_id)
: eventId(0), filter(0), enabled(false),
overflow64(false), sourceEvent(nullptr),
counterId(counter_id), value(0), resetValue(false),
pmu(pmuReference) {}
void serialize(CheckpointOut &cp) const override;
void unserialize(CheckpointIn &cp) override;
/**
* Add an event count to the counter and check for overflow.
*
* @param delta Number of events to add to the counter.
* @return the quantity remaining until a counter overflow occurs.
*/
uint64_t add(uint64_t delta);
bool isFiltered() const;
/**
* Detach the counter from its event
*/
void detach();
/**
* Attach this counter to an event
*
* @param the event to attach the counter to
*/
void attach(PMUEvent* event);
/**
* Obtain the counter id
*
* @return the pysical counter id
*/
uint64_t getCounterId() const{
return counterId;
}
/**
* rReturn the counter value
*
* @return the counter value
*/
uint64_t getValue() const;
/**
* overwrite the value of the counter
*
* @param the new counter value
*/
void setValue(uint64_t val);
public: /* Serializable state */
/** Counter event ID */
EventTypeId eventId;
/** Filtering settings (evtCount is unused) */
PMEVTYPER_t filter;
/** Is the counter enabled? */
bool enabled;
/** Is this a 64-bit counter? */
bool overflow64;
protected: /* Configuration */
/** PmuEvent currently in use (if any) **/
PMUEvent *sourceEvent;
/** id of the counter instance **/
uint64_t counterId;
/** Current value of the counter */
uint64_t value;
/** Flag keeping track if the counter has been reset **/
bool resetValue;
PMU &pmu;
template <typename ...Args>
void debugCounter(const char* mainString, Args &...args) const {
std::string userString = csprintf(mainString, args...);
warn("[counterId = %d, eventId = %d, sourceEvent = 0x%x] %s",
counterId, eventId, sourceEvent, userString.c_str());
}
};
/**
* Is this a valid counter ID?
*
* @param id ID of counter within the PMU.
*
* @return true if counter is within the allowed range or the
* cycle counter, false otherwise.
*/
bool isValidCounter(CounterId id) const {
return id < counters.size() || id == PMCCNTR;
}
/**
* Return the state of a counter.
*
* @param id ID of counter within the PMU.
* @return Reference to a CounterState instance representing the
* counter.
*/
CounterState &getCounter(CounterId id) {
assert(isValidCounter(id));
return id == PMCCNTR ? cycleCounter : counters[id];
}
/**
* Return the state of a counter.
*
* @param id ID of counter within the PMU.
* @return Reference to a CounterState instance representing the
* counter.
*/
const CounterState &getCounter(CounterId id) const {
assert(isValidCounter(id));
return id == PMCCNTR ? cycleCounter : counters[id];
}
/**
* Depending on counter configuration, add or remove the probes
* driving the counter.
*
* Look at the state of a counter and (re-)attach the probes
* needed to drive a counter if it is currently active. All probes
* for the counter are detached if the counter is inactive.
*
* @param id ID of counter within the PMU.
* @param ctr Reference to the counter's state
*/
void updateCounter(CounterState &ctr);
/**
* Check if a counter's settings allow it to be counted.
*
* @param ctr Counter state instance representing this counter.
* @return false if the counter is active, true otherwise.
*/
bool isFiltered(const CounterState &ctr) const;
/**
* Call updateCounter() for each counter in the PMU if the
* counter's state has changed..
*
* @see updateCounter()
*/
void updateAllCounters();
protected: /* State that needs to be serialized */
/** Performance Monitor Count Enable Register */
RegVal reg_pmcnten;
/** Performance Monitor Control Register */
PMCR_t reg_pmcr;
/** Performance Monitor Selection Register */
PMSELR_t reg_pmselr;
/** Performance Monitor Interrupt Enable Register */
RegVal reg_pminten;
/** Performance Monitor Overflow Status Register */
RegVal reg_pmovsr;
/**
* Performance counter ID register
*
* These registers contain a bitmask of available architected
* counters.
*/
uint64_t reg_pmceid0;
uint64_t reg_pmceid1;
/** Remainder part when the clock counter is divided by 64 */
unsigned clock_remainder;
/** The number of regular event counters **/
uint64_t maximumCounterCount;
/** State of all general-purpose counters supported by PMU */
std::vector<CounterState> counters;
/** State of the cycle counter */
CounterState cycleCounter;
/** The id of the counter hardwired to the cpu cycle counter **/
const uint64_t cycleCounterEventId;
/** The event that implements the software increment **/
SWIncrementEvent *swIncrementEvent;
protected: /* Configuration and constants */
/** Constant (configuration-dependent) part of the PMCR */
PMCR_t reg_pmcr_conf;
/** PMCR write mask when accessed from the guest */
static const RegVal reg_pmcr_wr_mask;
/** Performance monitor interrupt number */
ArmInterruptPin *const interrupt;
/**
* List of event types supported by this PMU.
*/
std::map<EventTypeId, PMUEvent*> eventMap;
};
} // namespace ArmISA
#endif