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/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/kernel/vmmmgr.C $ */
/* */
/* IBM CONFIDENTIAL */
/* */
/* COPYRIGHT International Business Machines Corp. 2010,2013 */
/* */
/* p1 */
/* */
/* Object Code Only (OCO) source materials */
/* Licensed Internal Code Source Materials */
/* IBM HostBoot Licensed Internal Code */
/* */
/* The source code for this program is not published or otherwise */
/* divested of its trade secrets, irrespective of what has been */
/* deposited with the U.S. Copyright Office. */
/* */
/* Origin: 30 */
/* */
/* IBM_PROLOG_END_TAG */
#include <limits.h>
#include <util/singleton.H>
#include <kernel/vmmmgr.H>
#include <kernel/console.H>
#include <arch/ppc.H>
#include <kernel/ptmgr.H>
#include <kernel/segmentmgr.H>
#include <kernel/basesegment.H>
#include <kernel/stacksegment.H>
#include <kernel/devicesegment.H>
extern void* data_load_address;
VmmManager::VmmManager() : lock()
{
printk("HRMOR = %lX\n", getHRMOR());
}
void VmmManager::init()
{
VmmManager& v = Singleton<VmmManager>::instance();
BaseSegment::init();
StackSegment::init();
for (size_t i = SegmentManager::MMIO_FIRST_SEGMENT_ID;
i < SegmentManager::MMIO_LAST_SEGMENT_ID; ++i)
{
new DeviceSegment(i); // Self-registers with SegmentManager.
}
SegmentManager::initSLB();
v.initPTEs();
v.initSDR1(); /*no effect*/ // BEAM Fix.
};
void VmmManager::init_slb()
{
VmmManager& v = Singleton<VmmManager>::instance();
SegmentManager::initSLB();
v.initSDR1(); /*no effect*/ // BEAM Fix.
}
bool VmmManager::pteMiss(task_t* t, uint64_t effAddr, bool store)
{
return Singleton<VmmManager>::instance()._pteMiss(t, effAddr, store);
}
uint64_t VmmManager::findPhysicalAddress(uint64_t i_vaddr)
{
return Singleton<VmmManager>::instance()._findPhysicalAddress(i_vaddr);
}
void VmmManager::castOutPages(VmmManager::castout_t i_ct)
{
Singleton<VmmManager>::instance()._castOutPages(i_ct);
}
void VmmManager::flushPageTable( void )
{
Singleton<VmmManager>::instance()._flushPageTable();
}
void* VmmManager::devMap(void* ra, uint64_t i_devDataSize, bool i_nonCI)
{
return Singleton<VmmManager>::instance()._devMap(ra, i_devDataSize,
i_nonCI);
}
int VmmManager::devUnmap(void* ea)
{
return Singleton<VmmManager>::instance()._devUnmap(ea);
}
void VmmManager::initPTEs()
{
// Initialize and invalidate the page table
PageTableManager::init();
// There is no need to add PTE entries because the PTE-miss page fault
// handler will add as-needed.
}
void VmmManager::initSDR1()
{
// HTABORG, HTABSIZE = 0 (11 bits, 256k table)
register uint64_t sdr1 = HTABORG();
asm volatile("mtsdr1 %0" :: "r"(sdr1) : "memory");
}
bool VmmManager::_pteMiss(task_t* t, uint64_t effAddr, bool store)
{
lock.lock();
bool rc = SegmentManager::handlePageFault(t, effAddr, store);
lock.unlock();
return rc;
}
int VmmManager::mmAllocBlock(MessageQueue* i_mq,void* i_va,uint64_t i_size)
{
return Singleton<VmmManager>::instance()._mmAllocBlock(i_mq,i_va,i_size);
}
int VmmManager::_mmAllocBlock(MessageQueue* i_mq,void* i_va,uint64_t i_size)
{
lock.lock();
int rc = BaseSegment::mmAllocBlock(i_mq,i_va,i_size);
lock.unlock();
return rc;
}
Spinlock* VmmManager::getLock()
{
return &Singleton<VmmManager>::instance().lock;
}
uint64_t VmmManager::_findPhysicalAddress(uint64_t i_vaddr)
{
uint64_t paddr = 0;
lock.lock();
paddr = SegmentManager::findPhysicalAddress(i_vaddr);
lock.unlock();
return paddr;
}
int VmmManager::mmRemovePages(VmmManager::PAGE_REMOVAL_OPS i_op, void* i_vaddr,
uint64_t i_size, task_t* i_task)
{
return Singleton<VmmManager>::instance()._mmRemovePages(i_op,i_vaddr,
i_size,i_task);
}
int VmmManager::_mmRemovePages(VmmManager::PAGE_REMOVAL_OPS i_op,void* i_vaddr,
uint64_t i_size,task_t* i_task)
{
lock.lock();
int rc = BaseSegment::mmRemovePages(i_op,i_vaddr,i_size,i_task);
lock.unlock();
return rc;
}
int VmmManager::mmSetPermission(void* i_va, uint64_t i_size, uint64_t i_access_type)
{
return Singleton<VmmManager>::instance()._mmSetPermission(i_va, i_size, i_access_type);
}
int VmmManager::_mmSetPermission(void* i_va, uint64_t i_size, uint64_t i_access_type)
{
int rc = 1;
lock.lock();
rc = BaseSegment::mmSetPermission(i_va, i_size, i_access_type);
lock.unlock();
return rc;
}
void VmmManager::_castOutPages(VmmManager::castout_t i_ct)
{
lock.lock();
SegmentManager::castOutPages((uint64_t)i_ct);
lock.unlock();
}
void VmmManager::_flushPageTable( void )
{
lock.lock();
PageTableManager::flush();
lock.unlock();
}
int VmmManager::mmExtend(void)
{
return Singleton<VmmManager>::instance()._mmExtend();
}
int VmmManager::_mmExtend(void)
{
lock.lock();
int rc = BaseSegment::mmExtend();
lock.unlock();
return rc;
}
void* VmmManager::_devMap(void* ra, uint64_t i_devDataSize, bool i_nonCI)
{
void* ea = NULL;
lock.lock();
ea = SegmentManager::devMap(ra, i_devDataSize, i_nonCI);
lock.unlock();
return ea;
}
int VmmManager::_devUnmap(void* ea)
{
int rc = 0;
lock.lock();
rc = SegmentManager::devUnmap(ea);
lock.unlock();
return rc;
}
uint64_t VmmManager::HTABORG()
{
return ((uint32_t)HTABORG_OFFSET + getHRMOR());
}
uint64_t VmmManager::findKernelAddress(uint64_t i_vaddr)
{
//in hypervisor mode the HRMOR is automatically ORed onto
// the address so we need to tell the hardware to ignore it
uint64_t phys = VmmManager::findPhysicalAddress(i_vaddr);
if( static_cast<uint64_t>(-EFAULT) != phys )
{
phys |= FORCE_PHYS_ADDR;
}
return phys;
}
int VmmManager::mmLinearMap(void *i_paddr, uint64_t i_size)
{
return Singleton<VmmManager>::instance()._mmLinearMap(i_paddr, i_size);
}
int VmmManager::_mmLinearMap(void *i_paddr, uint64_t i_size)
{
lock.lock();
int rc = BaseSegment::mmLinearMap(i_paddr, i_size);
lock.unlock();
return rc;
}
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