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d062a82f112640436fdb99f21884363557cede9b
gem5/src/arch/arm/fastmodel/iris/thread_context.cc
Gabe Black d062a82f11 fastmodel: Implement flattened int reg reading and writing. 
Because the fast models (or at least the one we've looked at) give
access to the integer registers mostly based on the current view of
those registers, it does its own flattening and prevents accessing most
of the raw storage locations without this extra level of mapping. To
store to the flattened locations, we need to unflatten the indexes and
in one case shift the mode so that we get the right values.

Some registers which have irrelevant values for fast model (the "PC"
which is actually diverted elsewhere, the zero register, microcode
registers, and the "dummy" register), and those are left out of the
mapping so that they return 0 and blow up gem5 when someone attempts to
set them.

Change-Id: Ia2d315d5ca4c8a65b17ad52beff3a366ca8b3d46
Reviewed-on: https://gem5-review.googlesource.com/c/public/gem5/+/23791
Tested-by: kokoro <noreply+kokoro@google.com>
Reviewed-by: Giacomo Travaglini <giacomo.travaglini@arm.com>
Reviewed-by: Chun-Chen TK Hsu <chunchenhsu@google.com>
Maintainer: Gabe Black <gabeblack@google.com>
2020-02-06 01:07:16 +00:00

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/*
* Copyright 2019 Google, Inc.
*
* 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: Gabe Black
*/
#include "arch/arm/fastmodel/iris/thread_context.hh"
#include <utility>
#include "iris/detail/IrisCppAdapter.h"
#include "iris/detail/IrisObjects.h"
#include "mem/fs_translating_port_proxy.hh"
#include "mem/se_translating_port_proxy.hh"
namespace Iris
{
void
ThreadContext::initFromIrisInstance(const ResourceMap &resources)
{
bool enabled = false;
call().perInstanceExecution_getState(_instId, enabled);
_status = enabled ? Active : Suspended;
suspend();
call().memory_getMemorySpaces(_instId, memorySpaces);
call().memory_getUsefulAddressTranslations(_instId, translations);
typedef ThreadContext Self;
iris::EventSourceInfo evSrcInfo;
client.registerEventCallback<Self, &Self::breakpointHit>(
this, "ec_IRIS_BREAKPOINT_HIT",
"Handle hitting a breakpoint", "Iris::ThreadContext");
call().event_getEventSource(_instId, evSrcInfo, "IRIS_BREAKPOINT_HIT");
call().eventStream_create(_instId, breakpointEventStreamId,
evSrcInfo.evSrcId, client.getInstId());
for (auto it = bps.begin(); it != bps.end(); it++)
installBp(it);
}
iris::ResourceId
ThreadContext::extractResourceId(
const ResourceMap &resources, const std::string &name)
{
return resources.at(name).rscId;
}
void
ThreadContext::extractResourceMap(
ResourceIds &ids, const ResourceMap &resources,
const IdxNameMap &idx_names)
{
for (const auto &idx_name: idx_names) {
int idx = idx_name.first;
const std::string &name = idx_name.second;
if (idx >= ids.size())
ids.resize(idx + 1, iris::IRIS_UINT64_MAX);
ids[idx] = extractResourceId(resources, name);
}
}
void
ThreadContext::maintainStepping()
{
Tick now = 0;
while (true) {
if (comInstEventQueue.empty()) {
// Set to 0 to deactivate stepping.
call().step_setup(_instId, 0, "instruction");
break;
}
Tick next = comInstEventQueue.nextTick();
if (!now)
now = getCurrentInstCount();
if (next <= now) {
comInstEventQueue.serviceEvents(now);
// Start over now that comInstEventQueue has likely changed.
continue;
}
// Set to the number of instructions still to step through.
Tick remaining = next - now;
call().step_setup(_instId, remaining, "instruction");
break;
}
}
ThreadContext::BpInfoIt
ThreadContext::getOrAllocBp(Addr pc)
{
auto pc_it = bps.find(pc);
if (pc_it != bps.end())
return pc_it;
auto res = bps.emplace(std::make_pair(pc, new BpInfo(pc)));
panic_if(!res.second, "Inserting breakpoint failed.");
return res.first;
}
void
ThreadContext::installBp(BpInfoIt it)
{
BpId id;
Addr pc = it->second->pc;
auto space_id = getBpSpaceId(pc);
call().breakpoint_set_code(_instId, id, pc, space_id, 0, true);
it->second->id = id;
}
void
ThreadContext::uninstallBp(BpInfoIt it)
{
call().breakpoint_delete(_instId, it->second->id);
it->second->clearId();
}
void
ThreadContext::delBp(BpInfoIt it)
{
panic_if(!it->second->empty(),
"BP info still had events associated with it.");
if (it->second->validId())
uninstallBp(it);
bps.erase(it);
}
iris::IrisErrorCode
ThreadContext::instanceRegistryChanged(
uint64_t esId, const iris::IrisValueMap &fields, uint64_t time,
uint64_t sInstId, bool syncEc, std::string &error_message_out)
{
const std::string &event = fields.at("EVENT").getString();
const iris::InstanceId id = fields.at("INST_ID").getU64();
const std::string &name = fields.at("INST_NAME").getString();
if (name != "component." + _irisPath)
return iris::E_ok;
if (event == "added")
_instId = id;
else if (event == "removed")
_instId = iris::IRIS_UINT64_MAX;
else
panic("Unrecognized event type %s", event);
return iris::E_ok;
}
iris::IrisErrorCode
ThreadContext::phaseInitLeave(
uint64_t esId, const iris::IrisValueMap &fields, uint64_t time,
uint64_t sInstId, bool syncEc, std::string &error_message_out)
{
std::vector<iris::ResourceInfo> resources;
call().resource_getList(_instId, resources);
ResourceMap resourceMap;
for (auto &resource: resources)
resourceMap[resource.name] = resource;
initFromIrisInstance(resourceMap);
return iris::E_ok;
}
iris::IrisErrorCode
ThreadContext::simulationTimeEvent(
uint64_t esId, const iris::IrisValueMap &fields, uint64_t time,
uint64_t sInstId, bool syncEc, std::string &error_message_out)
{
if (fields.at("RUNNING").getAsBool()) {
// If this is just simulation time starting up, don't do anything.
return iris::E_ok;
}
// If simulation time has stopped for any reason, IRIS helpfully clears
// all stepping counters and we need to set them back. We might also need
// to service events based on the current number of executed instructions.
maintainStepping();
// Restart simulation time to make sure things progress once we give
// control back.
call().simulationTime_run(iris::IrisInstIdSimulationEngine);
return iris::E_ok;
}
iris::IrisErrorCode
ThreadContext::breakpointHit(
uint64_t esId, const iris::IrisValueMap &fields, uint64_t time,
uint64_t sInstId, bool syncEc, std::string &error_message_out)
{
Addr pc = fields.at("PC").getU64();
auto it = getOrAllocBp(pc);
auto e_it = it->second->events.begin();
while (e_it != it->second->events.end()) {
PCEvent *e = *e_it;
// Advance e_it here since e might remove itself from the list.
e_it++;
e->process(this);
}
return iris::E_ok;
}
ThreadContext::ThreadContext(
BaseCPU *cpu, int id, System *system, ::BaseTLB *dtb, ::BaseTLB *itb,
iris::IrisConnectionInterface *iris_if, const std::string &iris_path) :
_cpu(cpu), _threadId(id), _system(system), _dtb(dtb), _itb(itb),
_irisPath(iris_path), vecRegs(ArmISA::NumVecRegs),
vecPredRegs(ArmISA::NumVecPredRegs),
comInstEventQueue("instruction-based event queue"),
client(iris_if, "client." + iris_path)
{
iris::InstanceInfo info;
auto ret_code = noThrow().instanceRegistry_getInstanceInfoByName(
info, "component." + iris_path);
if (ret_code == iris::E_ok) {
// The iris instance registry already new about this path.
_instId = info.instId;
} else {
// This path doesn't (yet) exist. Set the ID to something invalid.
_instId = iris::IRIS_UINT64_MAX;
}
typedef ThreadContext Self;
iris::EventSourceInfo evSrcInfo;
client.registerEventCallback<Self, &Self::instanceRegistryChanged>(
this, "ec_IRIS_INSTANCE_REGISTRY_CHANGED",
"Install the iris instance ID", "Iris::ThreadContext");
call().event_getEventSource(iris::IrisInstIdGlobalInstance, evSrcInfo,
"IRIS_INSTANCE_REGISTRY_CHANGED");
regEventStreamId = iris::IRIS_UINT64_MAX;
static const std::vector<std::string> fields =
{ "EVENT", "INST_ID", "INST_NAME" };
call().eventStream_create(iris::IrisInstIdGlobalInstance, regEventStreamId,
evSrcInfo.evSrcId, client.getInstId(), &fields);
client.registerEventCallback<Self, &Self::phaseInitLeave>(
this, "ec_IRIS_SIM_PHASE_INIT_LEAVE",
"Initialize register contexts", "Iris::ThreadContext");
call().event_getEventSource(iris::IrisInstIdSimulationEngine, evSrcInfo,
"IRIS_SIM_PHASE_INIT_LEAVE");
initEventStreamId = iris::IRIS_UINT64_MAX;
call().eventStream_create(
iris::IrisInstIdSimulationEngine, initEventStreamId,
evSrcInfo.evSrcId, client.getInstId());
client.registerEventCallback<Self, &Self::simulationTimeEvent>(
this, "ec_IRIS_SIMULATION_TIME_EVENT",
"Handle simulation time stopping for breakpoints or stepping",
"Iris::ThreadContext");
call().event_getEventSource(iris::IrisInstIdSimulationEngine, evSrcInfo,
"IRIS_SIMULATION_TIME_EVENT");
timeEventStreamId = iris::IRIS_UINT64_MAX;
call().eventStream_create(
iris::IrisInstIdSimulationEngine, timeEventStreamId,
evSrcInfo.evSrcId, client.getInstId());
breakpointEventStreamId = iris::IRIS_UINT64_MAX;
}
ThreadContext::~ThreadContext()
{
call().eventStream_destroy(
iris::IrisInstIdSimulationEngine, initEventStreamId);
initEventStreamId = iris::IRIS_UINT64_MAX;
client.unregisterEventCallback("ec_IRIS_SIM_PHASE_INIT_LEAVE");
call().eventStream_destroy(
iris::IrisInstIdGlobalInstance, regEventStreamId);
regEventStreamId = iris::IRIS_UINT64_MAX;
client.unregisterEventCallback("ec_IRIS_INSTANCE_REGISTRY_CHANGED");
call().eventStream_destroy(
iris::IrisInstIdGlobalInstance, timeEventStreamId);
timeEventStreamId = iris::IRIS_UINT64_MAX;
client.unregisterEventCallback("ec_IRIS_SIMULATION_TIME_EVENT");
}
bool
ThreadContext::schedule(PCEvent *e)
{
auto it = getOrAllocBp(e->pc());
it->second->events.push_back(e);
if (_instId != iris::IRIS_UINT64_MAX && !it->second->validId())
installBp(it);
return true;
}
bool
ThreadContext::remove(PCEvent *e)
{
auto it = getOrAllocBp(e->pc());
it->second->events.remove(e);
if (it->second->empty())
delBp(it);
return true;
}
bool
ThreadContext::translateAddress(Addr &paddr, iris::MemorySpaceId p_space,
Addr vaddr, iris::MemorySpaceId v_space)
{
iris::MemoryAddressTranslationResult result;
auto ret = noThrow().memory_translateAddress(
_instId, result, v_space, vaddr, p_space);
if (ret != iris::E_ok) {
// Check if there was a legal translation between these two spaces.
// If so, something else went wrong.
for (auto &trans: translations)
if (trans.inSpaceId == v_space && trans.outSpaceId == p_space)
return false;
panic("No legal translation IRIS address translation found.");
}
if (result.address.empty())
return false;
if (result.address.size() > 1) {
warn("Multiple mappings for address %#x.", vaddr);
return false;
}
paddr = result.address[0];
return true;
}
void
ThreadContext::scheduleInstCountEvent(Event *event, Tick count)
{
Tick now = getCurrentInstCount();
comInstEventQueue.schedule(event, count);
if (count <= now)
call().simulationTime_stop(iris::IrisInstIdSimulationEngine);
else
maintainStepping();
}
void
ThreadContext::descheduleInstCountEvent(Event *event)
{
comInstEventQueue.deschedule(event);
maintainStepping();
}
Tick
ThreadContext::getCurrentInstCount()
{
uint64_t count;
auto ret = call().step_getStepCounterValue(_instId, count, "instruction");
panic_if(ret != iris::E_ok, "Failed to get instruction count.");
return count;
}
void
ThreadContext::initMemProxies(::ThreadContext *tc)
{
if (FullSystem) {
assert(!physProxy && !virtProxy);
physProxy.reset(new PortProxy(_cpu->getSendFunctional(),
_cpu->cacheLineSize()));
virtProxy.reset(new FSTranslatingPortProxy(tc));
} else {
assert(!virtProxy);
virtProxy.reset(new SETranslatingPortProxy(
_cpu->getSendFunctional(), getProcessPtr(),
SETranslatingPortProxy::NextPage));
}
}
ThreadContext::Status
ThreadContext::status() const
{
return _status;
}
void
ThreadContext::setStatus(Status new_status)
{
if (new_status == Active) {
if (_status != Active)
call().perInstanceExecution_setState(_instId, true);
} else {
if (_status == Active)
call().perInstanceExecution_setState(_instId, false);
}
_status = new_status;
}
ArmISA::PCState
ThreadContext::pcState() const
{
ArmISA::CPSR cpsr = readMiscRegNoEffect(ArmISA::MISCREG_CPSR);
ArmISA::PCState pc;
pc.thumb(cpsr.t);
pc.nextThumb(pc.thumb());
pc.jazelle(cpsr.j);
pc.nextJazelle(cpsr.j);
pc.aarch64(!cpsr.width);
pc.nextAArch64(!cpsr.width);
pc.illegalExec(false);
iris::ResourceReadResult result;
call().resource_read(_instId, result, pcRscId);
Addr addr = result.data.at(0);
if (cpsr.width && cpsr.t)
addr = addr & ~0x1;
pc.set(addr);
return pc;
}
void
ThreadContext::pcState(const ArmISA::PCState &val)
{
Addr pc = val.pc();
ArmISA::CPSR cpsr = readMiscRegNoEffect(ArmISA::MISCREG_CPSR);
if (cpsr.width && cpsr.t)
pc = pc | 0x1;
iris::ResourceWriteResult result;
call().resource_write(_instId, result, pcRscId, pc);
}
Addr
ThreadContext::instAddr() const
{
return pcState().instAddr();
}
Addr
ThreadContext::nextInstAddr() const
{
return pcState().nextInstAddr();
}
RegVal
ThreadContext::readMiscRegNoEffect(RegIndex misc_reg) const
{
iris::ResourceReadResult result;
call().resource_read(_instId, result, miscRegIds.at(misc_reg));
return result.data.at(0);
}
void
ThreadContext::setMiscRegNoEffect(RegIndex misc_reg, const RegVal val)
{
iris::ResourceWriteResult result;
call().resource_write(_instId, result, miscRegIds.at(misc_reg), val);
}
RegVal
ThreadContext::readIntReg(RegIndex reg_idx) const
{
ArmISA::CPSR cpsr = readMiscRegNoEffect(ArmISA::MISCREG_CPSR);
iris::ResourceReadResult result;
if (cpsr.width)
call().resource_read(_instId, result, intReg32Ids.at(reg_idx));
else
call().resource_read(_instId, result, intReg64Ids.at(reg_idx));
return result.data.at(0);
}
void
ThreadContext::setIntReg(RegIndex reg_idx, RegVal val)
{
ArmISA::CPSR cpsr = readMiscRegNoEffect(ArmISA::MISCREG_CPSR);
iris::ResourceWriteResult result;
if (cpsr.width)
call().resource_write(_instId, result, intReg32Ids.at(reg_idx), val);
else
call().resource_write(_instId, result, intReg64Ids.at(reg_idx), val);
}
/*
* The 64 bit version of registers gives us a pre-flattened view of the reg
* file, no matter what mode we're in or if we're currently 32 or 64 bit.
*/
RegVal
ThreadContext::readIntRegFlat(RegIndex idx) const
{
if (idx >= flattenedIntIds.size())
return 0;
iris::ResourceId res_id = flattenedIntIds.at(idx);
if (res_id == iris::IRIS_UINT64_MAX)
return 0;
iris::ResourceReadResult result;
call().resource_read(_instId, result, res_id);
return result.data.at(0);
}
void
ThreadContext::setIntRegFlat(RegIndex idx, uint64_t val)
{
iris::ResourceId res_id =
(idx >= flattenedIntIds.size()) ? iris::IRIS_UINT64_MAX :
flattenedIntIds.at(idx);
panic_if(res_id == iris::IRIS_UINT64_MAX,
"Int reg %d is not supported by fast model.", idx);
iris::ResourceWriteResult result;
call().resource_write(_instId, result, flattenedIntIds.at(idx), val);
}
RegVal
ThreadContext::readCCRegFlat(RegIndex idx) const
{
if (idx >= ccRegIds.size())
return 0;
iris::ResourceReadResult result;
call().resource_read(_instId, result, ccRegIds.at(idx));
return result.data.at(0);
}
void
ThreadContext::setCCRegFlat(RegIndex idx, RegVal val)
{
panic_if(idx >= ccRegIds.size(),
"CC reg %d is not supported by fast model.", idx);
iris::ResourceWriteResult result;
call().resource_write(_instId, result, ccRegIds.at(idx), val);
}
const ArmISA::VecRegContainer &
ThreadContext::readVecReg(const RegId &reg_id) const
{
const RegIndex idx = reg_id.index();
// Ignore accesses to registers which aren't architected. gem5 defines a
// few extra registers which it uses internally in the implementation of
// some instructions.
if (idx >= vecRegIds.size())
return vecRegs.at(idx);
ArmISA::VecRegContainer &reg = vecRegs.at(idx);
iris::ResourceReadResult result;
call().resource_read(_instId, result, vecRegIds.at(idx));
size_t data_size = result.data.size() * (sizeof(*result.data.data()));
size_t size = std::min(data_size, reg.SIZE);
memcpy(reg.raw_ptr<void>(), (void *)result.data.data(), size);
return reg;
}
const ArmISA::VecRegContainer &
ThreadContext::readVecRegFlat(RegIndex idx) const
{
return readVecReg(RegId(VecRegClass, idx));
}
const ArmISA::VecPredRegContainer &
ThreadContext::readVecPredReg(const RegId &reg_id) const
{
RegIndex idx = reg_id.index();
if (idx >= vecPredRegIds.size())
return vecPredRegs.at(idx);
ArmISA::VecPredRegContainer &reg = vecPredRegs.at(idx);
iris::ResourceReadResult result;
call().resource_read(_instId, result, vecPredRegIds.at(idx));
size_t offset = 0;
size_t num_bits = reg.NUM_BITS;
uint8_t *bytes = (uint8_t *)result.data.data();
while (num_bits > 8) {
reg.set_bits(offset, 8, *bytes);
offset += 8;
num_bits -= 8;
bytes++;
}
if (num_bits)
reg.set_bits(offset, num_bits, *bytes);
return reg;
}
const ArmISA::VecPredRegContainer &
ThreadContext::readVecPredRegFlat(RegIndex idx) const
{
return readVecPredReg(RegId(VecPredRegClass, idx));
}
} // namespace Iris
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