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/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/kernel/misc.C $ */
/* */
/* OpenPOWER HostBoot Project */
/* */
/* Contributors Listed Below - COPYRIGHT 2011,2016 */
/* [+] International Business Machines Corp. */
/* */
/* */
/* Licensed under the Apache License, Version 2.0 (the "License"); */
/* you may not use this file except in compliance with the License. */
/* You may obtain a copy of the License at */
/* */
/* http://www.apache.org/licenses/LICENSE-2.0 */
/* */
/* Unless required by applicable law or agreed to in writing, software */
/* distributed under the License is distributed on an "AS IS" BASIS, */
/* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or */
/* implied. See the License for the specific language governing */
/* permissions and limitations under the License. */
/* */
/* IBM_PROLOG_END_TAG */
#include <kernel/misc.H>
#include <kernel/cpumgr.H>
#include <kernel/cpuid.H>
#include <kernel/console.H>
#include <kernel/barrier.H>
#include <kernel/scheduler.H>
#include <assert.h>
#include <kernel/terminate.H>
#include <kernel/hbterminatetypes.H>
#include <sys/mm.h>
#include <errno.h>
#include <kernel/pagemgr.H>
#include <kernel/vmmmgr.H> // INITIAL_MEM_SIZE
#include <kernel/memstate.H>
#include <kernel/intmsghandler.H>
#include <kernel/hbdescriptor.H>
#include <kernel/ipc.H>
#include <kernel/timemgr.H>
#include <util/singleton.H>
#include <kernel/doorbell.H>
extern "C"
void kernel_shutdown(size_t, uint64_t, uint64_t, uint64_t,
uint64_t, uint64_t) NO_RETURN;
extern HB_Descriptor kernel_hbDescriptor;
KernelIpc::start_payload_data_area_t KernelIpc::start_payload_data_area;
namespace KernelMisc
{
uint64_t g_payload_base = 0;
uint64_t g_payload_entry = 0;
uint64_t g_payload_data = 0;
uint64_t g_masterHBInstance = 0xfffffffffffffffful;
void shutdown()
{
// Update scratch SPR for shutdown status.
cpu_t* c = CpuManager::getCurrentCPU();
register uint64_t status = CpuManager::getShutdownStatus();
if (c->master)
{
// If good shutdown requested print out status
if(status == SHUTDOWN_STATUS_GOOD)
{
printk("Shutdown Requested. Status = 0x%lx\n", status);
}
// Shtudown was called due to error.. print out plid of the
// errorlog that caused the failure
else
{
printk("Shutdown Requested. PLID = %lx (due to failure)\n",
status);
}
// Call to set the Core Scratch Reg 0 with the status
updateScratchReg(MMIO_SCRATCH_PROGRESS_CODE, status);
}
// If the Shutdown was called with a status of GOOD then
// perform a regular shutdown, otherwise assume we have an
// error with a status value of the plid and perform a TI.
if(status == SHUTDOWN_STATUS_GOOD)
{
// See magic_instruction_callback() in
// src/build/debug/simics-debug-framework.py
// for exactly how this is handled.
MAGIC_INSTRUCTION(MAGIC_SHUTDOWN);
// Check for a valid payload address.
if ((0 == g_payload_base) && (0 == g_payload_entry))
{
// We really don't know what we're suppose to do now, so just
// sleep all the processors.
if (c->master)
{
printk("No payload... nap'ing all threads.\n");
}
// Clear LPCR values that wakes up from nap. LPCR[49, 50, 51]
setLPCR(getLPCR() & (~0x0000000000007000));
while(1)
{
nap();
}
}
else
{
static Barrier* l_barrier = new Barrier(CpuManager::getCpuCount());
static uint64_t l_lowestPIR = 0xfffffffffffffffful;
if (c->master)
{
printk("Preparing to enter payload...%lx:%lx\n",
g_payload_base, g_payload_entry);
}
// Need to identify the thread with the lowest PIR because it needs
// to be the last one to jump to PHYP.
uint64_t l_pir = getPIR();
do
{
uint64_t currentPIR = l_lowestPIR;
if (l_pir > currentPIR)
{
break;
}
if (__sync_bool_compare_and_swap(&l_lowestPIR,
currentPIR, l_pir))
{
break;
}
} while(1);
l_barrier->wait();
// only set this to valid PIR if local master
// otherwise leave as default;
uint64_t local_master_pir = 0xfffffffffffffffful;
// Find the start_payload_data_area on the master node
uint64_t hrmor_base = KernelIpc::ipc_data_area.hrmor_base;
uint64_t this_hb_instance =
l_lowestPIR/KERNEL_MAX_SUPPORTED_CPUS_PER_NODE;
uint64_t hrmor_offset =
getHRMOR() - (this_hb_instance * hrmor_base);
uint64_t dest_hrmor =
(g_masterHBInstance * hrmor_base) + hrmor_offset;
uint64_t start_payload_data_area_address =
reinterpret_cast<uint64_t>
(&KernelIpc::start_payload_data_area);
start_payload_data_area_address += dest_hrmor;
start_payload_data_area_address |= 0x8000000000000000ul;
KernelIpc::start_payload_data_area_t * p_spda =
reinterpret_cast<KernelIpc::start_payload_data_area_t*>
(start_payload_data_area_address);
if (c->master)
{
local_master_pir = getPIR();
// Reset the memory state register so that the dump tools
// don't attempt to dump all of memory once payload runs.
KernelMemState::setMemScratchReg(
KernelMemState::MEM_CONTAINED_NR,
KernelMemState::NO_MEM);
// add this nodes cpu_count to the system cpu_count
__sync_add_and_fetch(&(p_spda->cpu_count),
CpuManager::getCpuCount());
// set lowest system PIR based on local lowest PIR
do
{
uint64_t currentPIR = p_spda->lowest_PIR;
if (l_lowestPIR > currentPIR)
{
break;
}
if (__sync_bool_compare_and_swap(&p_spda->lowest_PIR,
currentPIR, l_lowestPIR))
{
break;
}
} while(1);
}
kernel_shutdown(p_spda->node_count,
g_payload_base,
g_payload_entry,
g_payload_data,
local_master_pir, //master PIR if local master
start_payload_data_area_address);
}
}
else
{
// Got a nonzero status value indicating we had a shutdown request
// with a PLID and there force need to do TI. The plid info was
// written to the data area earlier in CpuManager::requestShutdown
// First indicate to the FSP that we're done by clearing out the
// "hostboot_done" register. We need to do this since this is the
// power off path.
setHbScratchStatus(HB_SHUTDOWN);
terminateExecuteTI();
}
}
void setHbScratchStatus(enum HbRunning i_status)
{
if(i_status == HB_RUNNING)
{
const char * hostboot_string = "hostboot";
updateScratchReg(MMIO_SCRATCH_HOSTBOOT_ACTIVE,
*reinterpret_cast<const uint64_t*>(hostboot_string));
}
else
{
updateScratchReg(MMIO_SCRATCH_HOSTBOOT_ACTIVE,0);
}
}
void WinkleCore::masterPreWork()
{
printk("Winkle threads - ");
// Save away the current timebase. All threads are in this object
// now so they're not going to be using the time for anything else.
iv_timebase = getTB() + TimeManager::convertSecToTicks(1,0);
if (true == iv_fusedCores)
{
uint64_t l_numThreads = CpuManager::getThreadCount();
cpu_t * l_cput = CpuManager::getCurrentCPU();
// creates cpu_t structure in advance for new threads
// (should be next set of cpuIds past master core)
for ( uint64_t l_threadNum = l_numThreads;
(l_threadNum < (l_numThreads *2));
l_threadNum++ )
{
Singleton<CpuManager>::instance().startCPU(l_cput->cpu +
l_threadNum);
}
// Tell SIMICS we expect more threads (one more core)
// to appear after doing the 'stop' instruction.
MAGIC_INSTRUCTION(MAGIC_SIMICS_FUSEDCOREWAKE);
} // end if fused core mode
}
extern "C" void kernel_execute_stop(task_t* t);
void WinkleCore::activeMainWork()
{
cpu_t* cpu = CpuManager::getCurrentCPU();
printk("%d.", static_cast<int>(cpu->cpu));
// Return current task to run-queue so it isn't lost.
cpu->scheduler->returnRunnable();
TaskManager::setCurrentTask(cpu->idle_task);
// Clear LPCR values that wakes up from winkle. LPCR[49, 50, 51]
// Otherwise, there may be an interrupt pending or something that
// prevents us from fully entering winkle.
setLPCR(getLPCR() & (~0x0000000000007000));
// Deactivate CPU from kernel.
cpu->winkled = true;
CpuManager::deactivateCPU(cpu);
// Create kernel save area and store ptr in bottom of kernel stack.
task_t* saveArea = new task_t();
saveArea->context.msr_mask = 0xD030; // EE, ME, PR, IR, DR.
*(reinterpret_cast<task_t**>(cpu->kernel_stack_bottom)) = saveArea;
// Set register to indicate we want a 'stop 15' to occur (state loss)
uint64_t l_psscr_saved = getPSSCR();
setPSSCR( 0x00000000003F00FF );
// Execute winkle.
kernel_execute_stop(saveArea);
// Re-activate CPU in kernel and re-init VMM SPRs.
setPSSCR(l_psscr_saved);
delete saveArea;
cpu->winkled = false;
CpuManager::activateCPU(cpu);
VmmManager::init_slb();
if(cpu->master)
{
// NOTE: The cpu_t structures for theads 1:3 were created
// during init (CpuManager::init).
// Start with a base PIR of thread 0 + 1 (Thread 1) as thread 0
// doesn't need to be woken up as it is already running.
uint64_t l_pir = getPIR() + 1;
for(size_t i = 0; i < CpuManager::getThreadCount()-1; i++)
{
// NOTE: The deferred work container verifies master core
// threads 1-3 wake up so a direct doorbell can be sent. For
// threads on other cores send_doorbell_wakeup() is used.
doorbell_send(l_pir + i);
}
}
// Select a new task if not the master CPU. Master CPU will resume
// the code that called cpu_master_winkle().
if (!cpu->master)
{
cpu->scheduler->setNextRunnable();
}
}
void WinkleCore::masterPostWork()
{
printk(" - Awake!\n");
// Restore timebase.
setTB(iv_timebase);
// Restore memory state register.
updateScratchReg(MMIO_SCRATCH_MEMORY_STATE,
kernel_hbDescriptor.kernelMemoryState);
// Set scratch register to indicate Hostboot is [still] active.
setHbScratchStatus(HB_RUNNING);
// Restore caller of cpu_master_winkle().
iv_caller->state = TASK_STATE_RUNNING;
TaskManager::setCurrentTask(iv_caller);
//Issue sbe master workaround
InterruptMsgHdlr::issueSbeMboxWA();
}
void WinkleCore::nonactiveMainWork()
{
// Race condition that should not occur...
//
// Attempted to winkle the master and another thread came online in
// the process.
kassert(false);
}
void WinkleAll::masterPreWork()
{
printk("Winkle all - ");
// Save away the current timebase. All threads are in this object
// now so they're not going to be using the time for anything else.
iv_timebase = getTB() + TimeManager::convertSecToTicks(1,0);
}
void WinkleAll::activeMainWork()
{
cpu_t* cpu = CpuManager::getCurrentCPU();
// Return current task to run-queue so it isn't lost.
cpu->scheduler->returnRunnable();
TaskManager::setCurrentTask(cpu->idle_task);
// Clear LPCR values that wakes up from winkle. LPCR[49, 50, 51]
// Otherwise, there may be an interrupt pending or something that
// prevents us from fully entering winkle.
setLPCR(getLPCR() & (~0x0000000000007000));
// Deactivate CPU from kernel.
cpu->winkled = true;
CpuManager::deactivateCPU(cpu);
// Create kernel save area and store ptr in bottom of kernel stack.
task_t* saveArea = new task_t();
saveArea->context.msr_mask = 0xD030; // EE, ME, PR, IR, DR.
*(reinterpret_cast<task_t**>(cpu->kernel_stack_bottom)) = saveArea;
// Set register to indicate we want a 'stop 15' to ocur (state loss)
uint64_t l_psscr_saved = getPSSCR();
setPSSCR( 0x00000000003F00FF );
// Execute winkle.
kernel_execute_stop(saveArea);
// Re-activate CPU in kernel and re-init VMM SPRs.
setPSSCR(l_psscr_saved);
delete saveArea;
cpu->winkled = false;
CpuManager::activateCPU(cpu);
VmmManager::init_slb();
// Wake up all the other threads.
if(__sync_bool_compare_and_swap(&iv_firstThread, 0, 1))
{
for(uint64_t i = 0; i < KERNEL_MAX_SUPPORTED_CPUS_PER_NODE *
KERNEL_MAX_SUPPORTED_NODES; i++)
{
cpu_t* slave = CpuManager::getCpu(i);
if ((NULL != slave) && (slave != cpu))
{
if (slave->winkled)
{
InterruptMsgHdlr::sendThreadWakeupMsg(i);
}
}
}
};
// Sync timebase.
if (getTB() < iv_timebase)
{
setTB(iv_timebase);
}
// Select a new task if not the master CPU. Master CPU will resume
// the code that called cpu_master_winkle().
if (!cpu->master)
{
cpu->scheduler->setNextRunnable();
}
}
void WinkleAll::masterPostWork()
{
printk("Awake!\n");
// Restore memory state register.
updateScratchReg(MMIO_SCRATCH_MEMORY_STATE,
kernel_hbDescriptor.kernelMemoryState);
// Set scratch register to indicate Hostboot is [still] active.
setHbScratchStatus(HB_RUNNING);
// Restore caller of cpu_all_winkle().
iv_caller->state = TASK_STATE_RUNNING;
TaskManager::setCurrentTask(iv_caller);
}
void WinkleAll::nonactiveMainWork()
{
// Race condition that should not occur...
//
// Attempted to winkle the threads and another thread came online in
// the process.
kassert(false);
}
int expand_half_cache()
{
static bool executed = false;
if (executed) // Why are we being called a second time?
{
return -EFAULT;
}
uint64_t startAddr = 512*KILOBYTE;
uint64_t endAddr = 1*MEGABYTE;
size_t cache_columns = 0;
switch(CpuID::getCpuType())
{
case CORE_POWER8_MURANO:
case CORE_POWER8_VENICE:
case CORE_POWER8_NAPLES:
case CORE_POWER9_NIMBUS:
case CORE_POWER9_CUMULUS:
cache_columns = 4;
break;
default:
kassert(false);
break;
}
for (size_t i = 0; i < cache_columns; i++)
{
size_t offset = i * MEGABYTE;
populate_cache_lines(
reinterpret_cast<uint64_t*>(startAddr + offset),
reinterpret_cast<uint64_t*>(endAddr + offset));
PageManager::addMemory(startAddr + offset,
(512*KILOBYTE)/PAGESIZE);
}
executed = true;
KernelMemState::setMemScratchReg(KernelMemState::MEM_CONTAINED_L3,
KernelMemState::HALF_CACHE);
return 0;
}
int expand_full_cache(uint64_t i_expandSize)
{
static bool executed = false;
if (executed) // Why are we being called a second time?
{
return -EFAULT;
}
uint64_t* startAddr = NULL;
uint64_t* endAddr = NULL;
switch(CpuID::getCpuType())
{
case CORE_POWER8_MURANO:
case CORE_POWER8_VENICE:
case CORE_POWER8_NAPLES:
case CORE_POWER9_NIMBUS:
case CORE_POWER9_CUMULUS:
startAddr = reinterpret_cast<uint64_t*>
( VmmManager::INITIAL_MEM_SIZE ) ;
endAddr = reinterpret_cast<uint64_t*>(i_expandSize);
break;
default:
kassert(false);
break;
}
if (startAddr != NULL)
{
populate_cache_lines(startAddr, endAddr);
// Increment the start address by a page size to make a gap
// in memory that Hostboot will later populate with
// the OCC Bootloader image.
// see src/usr/occ/occ.C::loadnStartAllOccs()
startAddr += PAGESIZE;
size_t pages = (reinterpret_cast<uint64_t>(endAddr) -
reinterpret_cast<uint64_t>(startAddr)) / PAGESIZE;
PageManager::addMemory(reinterpret_cast<uint64_t>(startAddr),
pages);
}
executed = true;
KernelMemState::setMemScratchReg(KernelMemState::MEM_CONTAINED_L3,
(i_expandSize == VMM_BASE_BLOCK_SIZE)
? KernelMemState::FULL_CACHE
: KernelMemState::REDUCED_CACHE);
return 0;
}
void populate_cache_lines(uint64_t* i_start, uint64_t* i_end)
{
size_t cache_line_size = getCacheLineWords();
while(i_start != i_end)
{
dcbz(i_start);
i_start += cache_line_size;
}
}
void updateScratchReg(MMIO_Scratch_Register scratch_addr,
uint64_t data)
{
uint64_t l_scratch_addr = static_cast<uint64_t>(scratch_addr);
switch(CpuID::getCpuType())
{
case CORE_POWER8_MURANO:
case CORE_POWER8_VENICE:
case CORE_POWER8_NAPLES:
l_scratch_addr = l_scratch_addr + 0x40;
break;
case CORE_POWER9_NIMBUS:
case CORE_POWER9_CUMULUS:
case CORE_UNKNOWN:
default:
// See EX07.EC.CC.PCC0.COMMON.SPR_COMMON.SCOMC in scomdef for
// info on this offset - MODE_CX_SCOMC: 0000xxx = SCRATCH xx SPR
// It's 0 for P9 so just pass through scratch reg offset
break;
}
writeScratchReg(l_scratch_addr, data);
};
};
namespace KernelMemState
{
void setMemScratchReg(MemLocation i_location,
MemSize i_size)
{
mem_location l_MemData;
l_MemData.memMode = i_location;
l_MemData.reserved = 0;
l_MemData.memSize = i_size;
isync();
kernel_hbDescriptor.kernelMemoryState = l_MemData.Scratch6Data;
KernelMisc::updateScratchReg(MMIO_SCRATCH_MEMORY_STATE,
l_MemData.Scratch6Data);
lwsync();
}
};
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