// Copyright (c) 2008-2009 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "Eclipse Public License v1.0"
// which accompanies this distribution, and is available
// at the URL "http://www.eclipse.org/legal/epl-v10.html".
//
// Initial Contributors:
// Nokia Corporation - initial contribution.
//
// Contributors:
//
// Description:
// e32\nkernsmp\arm\ncutils.cia
//
//
#include <e32cia.h>
#include <arm.h>
#include <arm_gic.h>
extern TSpinLock BTraceLock;
extern "C" {
extern TUint32 CrashStateOut;
extern SFullArmRegSet DefaultRegSet;
}
//#define __DBG_MON_FAULT__
//#define __RAM_LOADED_CODE__
//#define __EARLY_DEBUG__
#ifdef _DEBUG
#define ASM_KILL_LINK(rp,rs) asm("mov "#rs", #0xdf ");\
asm("orr "#rs", "#rs", "#rs", lsl #8 ");\
asm("orr "#rs", "#rs", "#rs", lsl #16 ");\
asm("str "#rs", ["#rp"] ");\
asm("str "#rs", ["#rp", #4] ");
#else
#define ASM_KILL_LINK(rp,rs)
#endif
#ifdef __PRI_LIST_MACHINE_CODED__
/** Return the priority of the highest priority item present on a priority list.
@return The highest priority present or -1 if the list is empty.
*/
EXPORT_C __NAKED__ TInt TPriListBase::HighestPriority()
{
asm("ldr r2, [r0, #4] "); // r2=iPresent MSW
asm("ldr r1, [r0, #0] "); // r1=iPresent LSW
CLZ(0,2); // r0=31-MSB(r2)
asm("subs r0, r0, #32 "); // r0=-1-MSB(r2), 0 if r2=0
CLZcc(CC_EQ,0,1); // if r2=0, r0=31-MSB(r1)
asm("rsb r0, r0, #31 "); // r0=highest priority
__JUMP(,lr);
}
/** Find the highest priority item present on a priority list.
If multiple items at the same priority are present, return the first to be
added in chronological order.
@return a pointer to the item or NULL if the list is empty.
*/
EXPORT_C __NAKED__ TPriListLink* TPriListBase::First()
{
asm("ldr r2, [r0, #4] "); // r2=iPresent MSW
asm("ldr r1, [r0], #8 "); // r1=iPresent LSW, r0=&iQueue[0]
CLZ(3,2); // r3=31-MSB(r2)
asm("subs r3, r3, #32 "); // r3=-1-MSB(r2), 0 if r2=0
CLZcc(CC_EQ,3,1); // if r2=0, r3=31-MSB(r1)
asm("rsbs r3, r3, #31 "); // r3=highest priority
asm("ldrpl r0, [r0, r3, lsl #2] "); // if r3>=0 list is nonempty, r0->first entry
asm("movmi r0, #0 "); // if r3<0 list empty, return NULL
__JUMP(,lr);
}
/** Add an item to a priority list.
@param aLink = a pointer to the item - must not be NULL
*/
EXPORT_C __NAKED__ void TPriListBase::Add(TPriListLink* /*aLink*/)
{
asm("ldrb r2, [r1, #8]" ); // r2=priority of aLink
asm("add ip, r0, #8 "); // ip=&iQueue[0]
asm("ldr r3, [ip, r2, lsl #2]! "); // r3->first entry at this priority
asm("cmp r3, #0 "); // is this first entry at this priority?
asm("bne pri_list_add_1 "); // branch if not
asm("str r1, [ip] "); // if queue originally empty, iQueue[pri]=aThread
asm("ldrb ip, [r0, r2, lsr #3]! "); // ip=relevant byte of present mask, r0->same
asm("and r2, r2, #7 ");
asm("mov r3, #1 ");
asm("str r1, [r1, #0] "); // aThread->next=aThread
asm("orr ip, ip, r3, lsl r2 "); // ip |= 1<<(pri&7)
asm("str r1, [r1, #4] "); // aThread->iPrev=aThread
asm("strb ip, [r0] "); // update relevant byte of present mask
__JUMP(,lr);
asm("pri_list_add_1: ");
asm("ldr ip, [r3, #4] "); // if nonempty, ip=last
asm("str r1, [r3, #4] "); // first->prev=aThread
asm("stmia r1, {r3,ip} "); // aThread->next=r3=first, aThread->prev=ip=last
asm("str r1, [ip, #0] "); // last->next=aThread
__JUMP(,lr);
}
/** Removes an item from a priority list.
@param aLink A pointer to the item - this must not be NULL.
*/
EXPORT_C __NAKED__ void TPriListBase::Remove(TPriListLink* /*aLink*/)
{
asm("ldmia r1, {r2,r3} "); // r2=aLink->iNext, r3=aLink->iPrev
ASM_KILL_LINK(r1,r12);
asm("subs r12, r1, r2 "); // check if more threads at this priority, r12=0 if not
asm("bne 1f "); // branch if there are more at same priority
asm("ldrb r2, [r1, #%a0]" : : "i" _FOFF(NThread, iPriority)); // r2=thread priority
asm("add r1, r0, #%a0" : : "i" _FOFF(TPriListBase, iQueue)); // r1->iQueue[0]
asm("str r12, [r1, r2, lsl #2] "); // iQueue[priority]=NULL
asm("ldrb r1, [r0, r2, lsr #3] "); // r1=relevant byte in present mask
asm("and r3, r2, #7 "); // r3=priority & 7
asm("mov r12, #1 ");
asm("bic r1, r1, r12, lsl r3 "); // clear bit in present mask
asm("strb r1, [r0, r2, lsr #3] "); // update relevant byte in present mask
__JUMP(,lr);
asm("1: "); // get here if there are other threads at same priority
asm("ldrb r12, [r1, #%a0]" : : "i" _FOFF(NThread, iPriority)); // r12=thread priority
asm("add r0, r0, #%a0" : : "i" _FOFF(TPriListBase, iQueue)); // r0=&iQueue[0]
asm("str r3, [r2, #4] "); // next->prev=prev
asm("ldr r12, [r0, r12, lsl #2]! "); // r12=iQueue[priority], r0=&iQueue[priority]
asm("str r2, [r3, #0] "); // and prev->next=next
asm("cmp r12, r1 "); // if aThread was first...
asm("streq r2, [r0, #0] "); // iQueue[priority]=aThread->next
__JUMP(,lr); // finished
}
/** Change the priority of an item on a priority list
@param aLink = pointer to the item to act on - must not be NULL
@param aNewPriority = new priority for the item
*/
EXPORT_C __NAKED__ void TPriListBase::ChangePriority(TPriListLink* /*aLink*/, TInt /*aNewPriority*/)
{
asm("ldrb r3, [r1, #8] "); // r3=old priority
asm("stmfd sp!, {r4-r6,lr} ");
asm("cmp r3, r2 ");
asm("ldmeqfd sp!, {r4-r6,pc} "); // if old priority=new, finished
asm("ldmia r1, {r4,r12} "); // r4=next, r12=prev
asm("ldmia r0!, {r6,lr} "); // lr:r6=present mask, r0=&iQueue[0]
asm("subs r5, r4, r1 "); // check if aLink is only one at that priority, r5=0 if it is
asm("beq change_pri_1 "); // branch if it is
asm("ldr r5, [r0, r3, lsl #2] "); // r5=iQueue[old priority]
asm("str r4, [r12, #0] "); // prev->next=next
asm("str r12, [r4, #4] "); // next->prev=prev
asm("cmp r5, r1 "); // was aLink first?
asm("streq r4, [r0, r3, lsl #2] "); // if it was, iQueue[old priority]=aLink->next
asm("b change_pri_2 ");
asm("change_pri_1: ");
asm("str r5, [r0, r3, lsl #2] "); // if empty, set iQueue[old priority]=NULL
asm("mov r12, #0x80000000 ");
asm("rsbs r3, r3, #31 "); // r3=31-priority
asm("bicmi lr, lr, r12, ror r3 "); // if pri>31, clear bit is MS word
asm("bicpl r6, r6, r12, ror r3 "); // if pri<=31, clear bit in LS word
asm("change_pri_2: ");
asm("ldr r4, [r0, r2, lsl #2] "); // r4=iQueue[new priority]
asm("strb r2, [r1, #8] "); // store new priority
asm("cmp r4, #0 "); // new priority queue empty?
asm("bne change_pri_3 "); // branch if not
asm("str r1, [r0, r2, lsl #2] "); // if new priority queue was empty, iQueue[new p]=aLink
asm("mov r12, #0x80000000 ");
asm("str r1, [r1, #0] "); // aLink->next=aLink
asm("rsbs r2, r2, #31 "); // r2=31-priority
asm("str r1, [r1, #4] "); // aLink->prev=aLink
asm("orrmi lr, lr, r12, ror r2 "); // if pri>31, set bit is MS word
asm("orrpl r6, r6, r12, ror r2 "); // if pri<=31, set bit in LS word
asm("stmdb r0!, {r6,lr} "); // store present mask and restore r0
asm("ldmfd sp!, {r4-r6,pc} ");
asm("change_pri_3: ");
asm("ldr r12, [r4, #4] "); // r12->last link at this priority
asm("str r1, [r4, #4] "); // first->prev=aLink
asm("str r1, [r12, #0] "); // old last->next=aLink
asm("stmia r1, {r4,r12} "); // aLink->next=r3=first, aLink->prev=r12=old last
asm("stmdb r0!, {r6,lr} "); // store present mask and restore r0
asm("ldmfd sp!, {r4-r6,pc} ");
}
#endif
__NAKED__ void initialiseState(TInt /*aCpu*/, TSubScheduler* /*aSS*/)
{
SET_RWNO_TID(,r1);
__ASM_CLI_MODE(MODE_ABT);
asm("str sp, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_AbtStackTop));
asm("mvn r3, #0 ");
asm("str r3, [sp, #%a0]" : : "i" _FOFF(SFullArmRegSet, iExcCode));
asm("str r3, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_IrqNestCount));
__ASM_CLI_MODE(MODE_UND);
asm("str sp, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_UndStackTop));
__ASM_CLI_MODE(MODE_FIQ);
asm("str sp, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_FiqStackTop));
__ASM_CLI_MODE(MODE_IRQ);
asm("str sp, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_IrqStackTop));
__ASM_CLI_MODE(MODE_SVC);
asm("ldr r2, __TheScheduler ");
asm("ldr r3, [r2, #%a0]" : : "i" _FOFF(TScheduler, i_ScuAddr));
asm("str r3, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_ScuAddr));
asm("ldr r3, [r2, #%a0]" : : "i" _FOFF(TScheduler, i_GicDistAddr));
asm("str r3, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_GicDistAddr));
asm("ldr r3, [r2, #%a0]" : : "i" _FOFF(TScheduler, i_GicCpuIfcAddr));
asm("str r3, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_GicCpuIfcAddr));
asm("ldr r3, [r2, #%a0]" : : "i" _FOFF(TScheduler, i_LocalTimerAddr));
asm("str r3, [r1, #%a0]" : : "i" _FOFF(TSubScheduler, i_LocalTimerAddr));
asm("mov r3, #0 ");
SET_RWRO_TID(,r3);
SET_RWRW_TID(,r3);
__JUMP(,lr);
asm("__TheScheduler: ");
asm(".word TheScheduler ");
}
__NAKED__ TUint32 __mpid()
{
asm("mrc p15, 0, r0, c0, c0, 5 ");
__JUMP(,lr);
}
/** @internalTechnology
Called to indicate that the system has crashed and all CPUs should be
halted and should dump their registers.
*/
__NAKED__ void NKern::NotifyCrash(const TAny* /*a0*/, TInt /*a1*/)
{
asm("stmfd sp!, {r0-r1} "); // save parameters
GET_RWNO_TID(,r0);
asm("cmp r0, #0 ");
asm("ldreq r0, __SS0 ");
asm("ldr r0, [r0, #%a0]" : : "i" _FOFF(TSubScheduler,i_Regs));
asm("cmp r0, #0 ");
asm("ldreq r0, __DefaultRegs ");
asm("ldr r1, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet, iExcCode));
asm("cmp r1, #0 "); // context already saved?
asm("bge state_already_saved "); // skip if so
asm("mov r1, lr ");
asm("bl " CSM_ZN3Arm9SaveStateER14SFullArmRegSet );
asm("str r1, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet, iN.iR15));
asm("ldmia sp!, {r2-r3} "); // original R0,R1
asm("stmia r0, {r2-r3} "); // save original R0,R1
asm("add r1, r0, #%a0" : : "i" _FOFF(SFullArmRegSet, iExcCode));
asm("mov r4, r0 "); // save pointer to i_Regs
asm("stmib r1, {r2-r3} "); // save a0, a1 in iCrashArgs
asm("mov r1, #13 "); // r1 = regnum
asm("mrs r2, cpsr "); // r2 = mode
asm("bl " CSM_ZN3Arm3RegER14SFullArmRegSetim ); // r0 = pointer to exception mode R13
asm("str sp, [r0] "); // save correct original value for exception mode R13
asm("b state_save_complete ");
asm("state_already_saved: ");
asm("ldmia sp!, {r2-r3} "); // original R0,R1
asm("add r1, r0, #%a0" : : "i" _FOFF(SFullArmRegSet, iExcCode));
asm("ldr r4, [r1, #4]! ");
asm("cmp r4, #0 ");
asm("stmeqia r1, {r2-r3} "); // save a0, a1 in iCrashArgs, provided iCrashArgs not already set
asm("mov r4, r0 "); // save pointer to i_Regs
asm("state_save_complete: ");
__ASM_CLI_MODE(MODE_FIQ); // mode_fiq, interrupts off
GET_RWNO_TID(,r0);
asm("ldr r1, __CrashState ");
asm("cmp r0, #0 ");
asm("moveq r2, #1 ");
asm("streq r2, [r1] ");
asm("beq skip_other_cores "); // If subscheduler not yet set, don't bother with other cores
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(TSubScheduler, iCpuMask));
asm("ldr r5, [r0, #%a0]" : : "i" _FOFF(TSubScheduler, i_GicCpuIfcAddr));
// asm("ldr r4, [r0, #%a0]" : : "i" _FOFF(TSubScheduler,i_Regs));
asm("bic sp, sp, #4 "); // align stack to multiple of 8
__DATA_MEMORY_BARRIER_Z__(r6);
asm("1: ");
LDREX(3,1);
asm("orr r5, r3, r2 ");
STREX(12,5,1); // set bit in CrashState for this CPU
asm("cmp r12, #0 ");
asm("bne 1b ");
__DATA_MEMORY_BARRIER__(r6);
asm("cmp r3, #0 "); // were we first to crash?
asm("beq first_to_crash "); // branch if so
// we weren't first to crash, so wait here for a crash IPI
// disable all interrupts except for CRASH_IPI
GET_RWNO_TID(,r0);
asm("ldr r0, [r0, #%a0]" : : "i" _FOFF(TSubScheduler, i_GicCpuIfcAddr));
asm("mov r1, #0 ");
asm("1: ");
asm("add r1, r1, #1 ");
asm("str r1, [r0, #%a0]" : : "i" _FOFF(GicCpuIfc, iPriMask));
__DATA_SYNC_BARRIER__(r6);
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(GicCpuIfc, iPriMask));
asm("cmp r2, #0 ");
asm("beq 1b "); // loop until priority mask is nonzero
asm("2: ");
__ASM_STI_MODE(MODE_ABT);
ARM_WFE;
asm("b 2b "); // loop until we get a CRASH_IPI
// This CPU was first to crash
asm("first_to_crash: ");
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(TSubScheduler, iScheduler));
asm("ldr r7, __CrashStateOut ");
asm("ldr r3, [r2, #%a0]" : : "i" _FOFF(TScheduler, iActiveCpus1));
asm("str r3, [r7] "); // mask of CPUs pending
asm("ldr r5, [r0, #%a0]" : : "i" _FOFF(TSubScheduler, i_GicDistAddr));
asm("ldr r1, __CrashIPIWord ");
__DATA_SYNC_BARRIER_Z__(r6);
asm("str r1, [r5, #%a0]" : : "i" _FOFF(GicDistributor, iSoftIrq)); // send CRASH_IPI to all other CPUs
__DATA_SYNC_BARRIER__(r6);
asm("skip_other_cores: ");
asm("mov r0, #0 ");
asm("mov r1, #0 ");
asm("mov r2, #0 ");
asm("bl NKCrashHandler "); // call NKCrashHandler(0,0,0)
__DATA_SYNC_BARRIER__(r6);
GET_RWNO_TID(,r0);
asm("cmp r0, #0 ");
asm("beq skip_other_cores2 "); // If subscheduler not yet set, don't bother with other cores
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(TSubScheduler, iCpuMask));
asm("7: ");
LDREX(1,7);
asm("bic r1, r1, r2 ");
STREX(3,1,7); // atomic { CrashStateOut &= ~iCpuMask; }
asm("cmp r3, #0 ");
asm("bne 7b ");
asm("1: ");
asm("ldr r1, [r7] ");
asm("cmp r1, #0 "); // wait for all CPUs to acknowledge
asm("beq 2f ");
asm("adds r6, r6, #1 ");
asm("bne 1b "); // if not ACKed after 2^32 iterations give up waiting
asm("2: ");
__DATA_MEMORY_BARRIER_Z__(r0);
asm("skip_other_cores2: ");
asm("mov r0, #1 ");
asm("ldr r1, [r4, #%a0] " : : "i" _FOFF(SFullArmRegSet,iN.iR0)); // original R0 = a0 parameter
asm("ldr r2, [r4, #%a0] " : : "i" _FOFF(SFullArmRegSet,iN.iR1)); // original R1 = a1 parameter
asm("bl NKCrashHandler "); // call NKCrashHandler(1,a0,a1) - shouldn't return
// shouldn't get back here
__ASM_CRASH();
asm("__CrashState: ");
asm(".word %a0" : : "i" ((TInt)&CrashState));
asm("__CrashStateOut: ");
asm(".word CrashStateOut ");
asm("__CrashIPIWord: ");
asm(".word %a0" : : "i" ( (TInt)GIC_IPI_OTHERS(CRASH_IPI_VECTOR) ));
asm("__SS0: ");
asm(".word %a0" : : "i" ((TInt)&TheSubSchedulers[0]));
asm("__DefaultRegs: ");
asm(".word %a0" : : "i" ((TInt)&DefaultRegSet));
}
#ifdef __USE_BTRACE_LOCK__
#define __ASM_ACQUIRE_BTRACE_LOCK(regs) \
asm("stmfd sp!, " regs); \
asm("ldr r0, __BTraceLock "); \
asm("bl " CSM_ZN9TSpinLock11LockIrqSaveEv ); \
asm("mov r4, r0 "); \
asm("ldmfd sp!, " regs)
#define __ASM_RELEASE_BTRACE_LOCK() \
asm("stmfd sp!, {r0-r1} "); \
asm("ldr r0, __BTraceLock "); \
asm("mov r1, r4 "); \
asm("bl " CSM_ZN9TSpinLock16UnlockIrqRestoreEi ); \
asm("ldmfd sp!, {r0-r1} ")
#else
#define __ASM_ACQUIRE_BTRACE_LOCK(regs)
#define __ASM_RELEASE_BTRACE_LOCK()
#endif
__NAKED__ EXPORT_C TBool BTrace::Out(TUint32 a0, TUint32 a1, TUint32 a2, TUint32 a3)
{
asm("stmdb sp!, {r2,r3,r4,lr}");
__ASM_ACQUIRE_BTRACE_LOCK("{r0-r1}");
asm("ldr r12, __BTraceData");
asm("and r2, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("mov r3, r1"); // r3 = a1 (ready for call to handler)
asm("ldrb r2, [r12, r2, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("ldr r12, [r12, #%a0]" : : "i" _FOFF(SBTraceData,iHandler));
asm("adr lr, 9f");
asm("cmp r2, #0");
asm("moveq r0, #0");
__JUMP(ne, r12);
asm("9: ");
__ASM_RELEASE_BTRACE_LOCK();
__POPRET("r2,r3,r4,");
}
__NAKED__ EXPORT_C TBool BTrace::OutN(TUint32 a0, TUint32 a1, TUint32 a2, const TAny* aData, TInt aDataSize)
{
asm("stmdb sp!, {r2,r3,r4,lr}");
__ASM_ACQUIRE_BTRACE_LOCK("{r0-r3}");
asm("ldr r12, __BTraceData");
asm("and r2, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("ldr r14, [sp, #16]"); // r14 = aDataSize
asm("ldrb r2, [r12, r2, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("ldr r12, [r12, #%a0]" : : "i" _FOFF(SBTraceData,iHandler));
asm("cmp r2, #0");
asm("moveq r0, #0");
asm("beq 0f ");
asm("cmp r14, #%a0" : : "i" ((TInt)KMaxBTraceDataArray));
asm("movhi r14, #%a0" : : "i" ((TInt)KMaxBTraceDataArray));
asm("orrhi r0, r0, #%a0" : : "i" ((TInt)(BTrace::ERecordTruncated<<(BTrace::EFlagsIndex*8))));
asm("add r0, r0, r14");
asm("subs r14, r14, #1");
asm("ldrhs r2, [r3]"); // get first word of aData is aDataSize!=0
asm("mov r3, r1"); // r3 = a1 (ready for call to handler)
asm("cmp r14, #4");
asm("strlo r2, [sp, #4]"); // replace aData with first word if aDataSize is 1-4
asm("mov lr, pc");
__JUMP(, r12);
asm("0: ");
__ASM_RELEASE_BTRACE_LOCK();
__POPRET("r2,r3,r4,");
}
__NAKED__ EXPORT_C TBool BTrace::OutX(TUint32 a0, TUint32 a1, TUint32 a2, TUint32 a3)
{
asm("stmdb sp!, {r2,r3,r4,lr}");
__ASM_ACQUIRE_BTRACE_LOCK("{r0-r1}");
asm("ldr r12, __BTraceData");
asm("and r2, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("mov r3, r1"); // r3 = a1 (ready for call to handler)
asm("ldrb r2, [r12, r2, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("mrs r14, cpsr ");
asm("ldr r12, [r12, #%a0]" : : "i" _FOFF(SBTraceData,iHandler));
asm("cmp r2, #0"); // check category filter
asm("moveq r0, #0");
asm("beq 0f "); // if category disabled, exit now
__ASM_CLI();
asm("and r2, r14, #0x0f ");
asm("cmp r2, #3 ");
asm("movhi r2, #2 "); // r2 = context ID = 1 for FIQ, 2 for IRQ/ABT/UND/SYS
asm("bne 1f ");
GET_RWNO_TID(,r1);
asm("movs r2, r1 "); // r2 = context ID = 0 for early boot, no threads
asm("beq 1f ");
asm("ldrb r2, [r1, #%a0]" : : "i" _FOFF(TSubScheduler,iInIDFC));
asm("cmp r2, #0 ");
asm("ldreq r2, [r1, #%a0]" : : "i" _FOFF(TSubScheduler,iCurrentThread));
asm("movne r2, #3 "); // r2 = context ID = 3 for IDFC = NThread pointer for thread
asm("1: ");
asm("msr cpsr, r14 ");
asm("mov lr, pc");
__JUMP(, r12);
asm("0: ");
__ASM_RELEASE_BTRACE_LOCK();
__POPRET("r2,r3,r4,");
}
__NAKED__ EXPORT_C TBool BTrace::OutNX(TUint32 a0, TUint32 a1, TUint32 a2, const TAny* aData, TInt aDataSize)
{
asm("stmdb sp!, {r2,r3,r4,lr}");
__ASM_ACQUIRE_BTRACE_LOCK("{r0-r3}");
asm("ldr r12, __BTraceData");
asm("and r2, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("ldr r14, [sp, #16]"); // r14 = aDataSize
asm("ldrb r2, [r12, r2, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("ldr r12, [r12, #%a0]" : : "i" _FOFF(SBTraceData,iHandler));
asm("cmp r2, #0"); // check category filter
asm("moveq r0, #0");
asm("beq 0f "); // if category disabled, exit now
asm("cmp r14, #%a0" : : "i" ((TInt)KMaxBTraceDataArray));
asm("movhi r14, #%a0" : : "i" ((TInt)KMaxBTraceDataArray));
asm("orrhi r0, r0, #%a0" : : "i" ((TInt)(BTrace::ERecordTruncated<<(BTrace::EFlagsIndex*8))));
asm("add r0, r0, r14");
asm("subs r14, r14, #1");
asm("ldrhs r2, [r3]"); // get first word of aData is aDataSize!=0
asm("mov r3, r1"); // r3 = a1 (ready for call to handler)
asm("cmp r14, #4");
asm("strlo r2, [sp, #4]"); // replace aData with first word if aDataSize is 1-4
asm("mrs r14, cpsr ");
__ASM_CLI();
asm("and r2, r14, #0x0f ");
asm("cmp r2, #3 ");
asm("movhi r2, #2 "); // r2 = context ID = 1 for FIQ, 2 for IRQ/ABT/UND/SYS
asm("bne 1f ");
GET_RWNO_TID(,r1);
asm("movs r2, r1 "); // r2 = context ID = 0 for early boot, no threads
asm("beq 1f ");
asm("ldrb r2, [r1, #%a0]" : : "i" _FOFF(TSubScheduler,iInIDFC));
asm("cmp r2, #0 ");
asm("ldreq r2, [r1, #%a0]" : : "i" _FOFF(TSubScheduler,iCurrentThread));
asm("movne r2, #3 "); // r2 = context ID = 3 for IDFC = NThread pointer for thread
asm("1: ");
asm("msr cpsr, r14 ");
asm("mov lr, pc");
__JUMP(, r12);
asm("0: ");
__ASM_RELEASE_BTRACE_LOCK();
__POPRET("r2,r3,r4,");
}
__NAKED__ EXPORT_C TBool BTrace::OutBig(TUint32 a0, TUint32 a1, const TAny* aData, TInt aDataSize)
{
asm("stmdb sp!, {r4,lr}");
asm("ldr r12, __BTraceData");
asm("str lr, [sp, #-4]! "); // PC
asm("and r14, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("ldrb r14, [r12, r14, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("cmp r14, #0"); // check category filter
asm("addeq sp, sp, #4 ");
asm("moveq r0, #0 ");
asm("beq 0f "); // if category disabled, exit now
asm("mrs r14, cpsr ");
__ASM_CLI();
asm("and r12, r14, #0x0f ");
asm("cmp r12, #3 ");
asm("movhi r12, #2 "); // r12 = context ID = 1 for FIQ, 2 for IRQ/ABT/UND/SYS
asm("bne 1f ");
GET_RWNO_TID(,r12);
asm("cmp r12, #0 "); // r2 = context ID = 0 for early boot, no threads
asm("beq 1f ");
asm("ldrb r12, [r12, #%a0]" : : "i" _FOFF(TSubScheduler,iInIDFC));
asm("cmp r12, #0 ");
GET_RWNO_TID(eq,r12);
asm("ldreq r12, [r12, #%a0]" : : "i" _FOFF(TSubScheduler,iCurrentThread));
asm("movne r12, #3 "); // r12 = context ID = 3 for IDFC = NThread pointer for thread
asm("1: ");
asm("msr cpsr, r14 ");
asm("str r12, [sp, #-4]! "); // context ID
asm("bl " CSM_ZN6BTrace8DoOutBigEmmPKvimm);
asm("add sp, sp, #8");
asm("0: ");
__POPRET("r4,");
asm("__BTraceLock: ");
asm(".word %a0" : : "i" ((TInt)&BTraceLock));
asm("__BTraceData: ");
asm(".word BTraceData ");
}
__NAKED__ EXPORT_C TBool BTrace::OutFiltered(TUint32 a0, TUint32 a1, TUint32 a2, TUint32 a3)
{
// fall through to OutFilteredX...
}
__NAKED__ EXPORT_C TBool BTrace::OutFilteredX(TUint32 a0, TUint32 a1, TUint32 a2, TUint32 a3)
{
asm("stmdb sp!, {r2,r3,r4,lr}");
asm("ldr r12, __BTraceData");
asm("and r2, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("mov r3, r1"); // r3 = a1 (ready for call to handler)
asm("ldrb r2, [r12, r2, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("cmp r2, #0");
asm("moveq r0, #0");
asm("beq 9f ");
// r0=header, r1=a1=secondary filter UID, r2=unused, r3=a1, r12->SBTraceData
// if trace enabled return r0,r1,r3 unmodified, r2=context value r12->handler, Z=0
// if trace disabled return r0=0 Z=1
asm("bl btrace_check_filter2 ");
asm("beq 9f ");
__ASM_ACQUIRE_BTRACE_LOCK("{r0,r2,r3,r12}");
asm("adr lr, 1f ");
__JUMP(, r12);
asm("1: ");
__ASM_RELEASE_BTRACE_LOCK();
asm("9: ");
__POPRET("r2,r3,r4,");
asm("btrace_check_filter2: ");
asm("stmfd sp!, {r0,r1,r3,r4,r12,lr} ");
asm("mov r0, r12 ");
asm("bl CheckFilter2__11SBTraceDataUl ");
asm("cmp r0, #0 ");
asm("beq 0f ");
asm("mrs r14, cpsr ");
__ASM_CLI();
asm("and r2, r14, #0x0f ");
asm("cmp r2, #3 ");
asm("movhi r2, #2 "); // r2 = context ID = 1 for FIQ, 2 for IRQ/ABT/UND/SYS
asm("bne 1f ");
GET_RWNO_TID(,r4);
asm("movs r2, r4 "); // r2 = context ID = 0 for early boot, no threads
asm("beq 1f ");
asm("ldrb r2, [r4, #%a0]" : : "i" _FOFF(TSubScheduler,iInIDFC));
asm("cmp r2, #0 ");
asm("ldreq r2, [r4, #%a0]" : : "i" _FOFF(TSubScheduler,iCurrentThread));
asm("movne r2, #3 "); // r2 = context ID = 3 for IDFC = NThread pointer for thread
asm("1: ");
asm("msr cpsr, r14 ");
asm("0: ");
asm("ldmfd sp!, {r0,r1,r3,r4,r12,lr} ");
asm("moveq r0, #0 ");
asm("ldrne r12, [r12, #%a0]" : : "i" _FOFF(SBTraceData,iHandler));
__JUMP(,lr);
}
__NAKED__ EXPORT_C TBool BTrace::OutFilteredN(TUint32 a0, TUint32 a1, TUint32 a2, const TAny* aData, TInt aDataSize)
{
// fall through to OutFilteredNX...
}
__NAKED__ EXPORT_C TBool BTrace::OutFilteredNX(TUint32 a0, TUint32 a1, TUint32 a2, const TAny* aData, TInt aDataSize)
{
asm("stmdb sp!, {r2,r3,r4,lr}");
asm("ldr r12, __BTraceData");
asm("and r2, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("ldrb r2, [r12, r2, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("cmp r2, #0");
asm("moveq r0, #0");
asm("beq 9f ");
// r0=header, r1=a1=secondary filter UID, r2=unused, r3=aData, r12->SBTraceData
// if trace enabled return r0,r1,r3 unmodified, r2=context value r12->handler, Z=0
// if trace disabled return r0=0 Z=1
asm("bl btrace_check_filter2 ");
asm("beq 9f ");
__ASM_ACQUIRE_BTRACE_LOCK("{r0-r3,r11,r12}");
asm("ldr r14, [sp, #16] "); // r14 = aDataSize
asm("cmp r14, #%a0" : : "i" ((TInt)KMaxBTraceDataArray));
asm("movhi r14, #%a0" : : "i" ((TInt)KMaxBTraceDataArray));
asm("orrhi r0, r0, #%a0" : : "i" ((TInt)(BTrace::ERecordTruncated<<(BTrace::EFlagsIndex*8))));
asm("add r0, r0, r14 ");
asm("subs r14, r14, #1 ");
asm("ldrhs r3, [r3] "); // get first word of aData if aDataSize!=0
asm("cmp r14, #4 ");
asm("strlo r3, [sp, #4] "); // replace aData with first word if aDataSize is 1-4
asm("mov r3, r1 "); // r3 = a1 (ready for call to handler)
asm("adr lr, 1f ");
__JUMP(, r12);
asm("1: ");
__ASM_RELEASE_BTRACE_LOCK();
asm("9: ");
__POPRET("r2,r3,r4,");
}
__NAKED__ EXPORT_C TBool BTrace::OutFilteredBig(TUint32 a0, TUint32 a1, const TAny* aData, TInt aDataSize)
{
asm("stmdb sp!, {r4,lr} ");
asm("ldr r12, __BTraceData ");
asm("stmfd sp!, {r2,lr} "); // save aData, PC
asm("and r14, r0, #%a0" : : "i" ((TInt)(0xff<<(BTrace::ECategoryIndex*8))));
asm("ldrb r14, [r12, r14, lsr #%a0]" : : "i" ((TInt)(BTrace::ECategoryIndex*8)));
asm("cmp r14, #0 "); // check category filter
asm("blne btrace_check_filter2 "); // if enabled, check secondary filter
asm("addeq sp, sp, #8 ");
asm("moveq r0, #0 ");
asm("beq 9f "); // if category or secondary filter disabled, exit now
asm("mov r12, r2 ");
asm("ldr r2, [sp, #0] "); // restore aData into r2
asm("str r12, [sp, #0] "); // Context ID
asm("bl " CSM_ZN6BTrace8DoOutBigEmmPKvimm);
asm("add sp, sp, #8 ");
asm("9: ");
__POPRET("r4,");
}
/******************************************************************************/
/** Save all the ARM registers
@internalTechnology
*/
__NAKED__ void Arm::SaveState(SFullArmRegSet&)
{
asm("stmia r0, {r0-r14}^ "); // save R0-R7, R8_usr-R14_usr
asm("str lr, [r0, #60]! "); // save R15
asm("mrs r1, cpsr ");
asm("str r1, [r0, #4]! "); // save CPSR
asm("bic r2, r1, #0x1f ");
asm("orr r2, r2, #0xd3 "); // mode_svc, all interrupts off
asm("msr cpsr, r2 ");
asm("stmib r0!, {r13,r14} "); // save R13_svc, R14_svc
asm("mrs r3, spsr ");
asm("str r3, [r0, #4]! "); // save SPSR_svc
asm("bic r2, r1, #0x1f ");
asm("orr r2, r2, #0xd7 "); // mode_abt, all interrupts off
asm("msr cpsr, r2 ");
asm("stmib r0!, {r13,r14} "); // save R13_abt, R14_abt
asm("mrs r3, spsr ");
asm("str r3, [r0, #4]! "); // save SPSR_abt
asm("bic r2, r1, #0x1f ");
asm("orr r2, r2, #0xdb "); // mode_und, all interrupts off
asm("msr cpsr, r2 ");
asm("stmib r0!, {r13,r14} "); // save R13_und, R14_und
asm("mrs r3, spsr ");
asm("str r3, [r0, #4]! "); // save SPSR_und
asm("bic r2, r1, #0x1f ");
asm("orr r2, r2, #0xd2 "); // mode_irq, all interrupts off
asm("msr cpsr, r2 ");
asm("stmib r0!, {r13,r14} "); // save R13_irq, R14_irq
asm("mrs r3, spsr ");
asm("str r3, [r0, #4]! "); // save SPSR_irq
asm("bic r2, r1, #0x1f ");
asm("orr r2, r2, #0xd1 "); // mode_fiq, all interrupts off
asm("msr cpsr, r2 ");
asm("stmib r0!, {r8-r14} "); // save R8_fiq ... R14_fiq
asm("mrs r3, spsr ");
asm("str r3, [r0, #4]! "); // save SPSR_fiq
asm("bic r2, r1, #0x1f ");
asm("orr r2, r2, #0xd3 "); // mode_svc, all interrupts off
asm("msr cpsr, r2 ");
asm("mov r4, #0 ");
asm("mov r5, #0 ");
asm("mov r6, #0 ");
asm("mov r7, #0 ");
asm("mov r8, #0 ");
asm("mov r9, #0 ");
asm("mov r10, #0 ");
asm("mov r11, #0 ");
// monitor mode - skip for now
asm("mov r3, #0 ");
asm("stmib r0!, {r4-r6} "); // R13_mon, R14_mon, SPSR_mon
// zero spare words
asm("mov r3, #0 ");
asm("stmib r0!, {r4-r11} ");
asm("add r0, r0, #4 "); // r0 = &a.iA
#ifdef __CPU_ARMV7
asm("mrc p14, 6, r3, c1, c0, 0 ");
#else
asm("mov r3, #0 ");
#endif
asm("str r3, [r0], #4 "); // TEEHBR
#ifdef __CPU_HAS_COPROCESSOR_ACCESS_REG
GET_CAR(,r3);
#else
asm("mov r3, #0 ");
#endif
asm("str r3, [r0], #4 "); // CPACR
// skip SCR, SDER, NSACR, PMCR, MVBAR for now
asm("mov r3, #0 ");
asm("stmia r0!, {r4-r8} "); // SCR, SDER, NSACR, PMCR, MVBAR
// zero spare words
asm("mov r3, #0 ");
asm("stmia r0!, {r3-r11} "); // r0 = &a.iB[0]
// just fill in iB[0]
#ifdef __CPU_HAS_MMU
asm("mrc p15, 0, r3, c1, c0, 0 ");
asm("str r3, [r0], #4 "); // SCTLR
#ifdef __CPU_HAS_ACTLR
asm("mrc p15, 0, r3, c1, c0, 1 ");
#else
asm("mov r3, #0 ");
#endif
asm("str r3, [r0], #4 "); // ACTLR
asm("mrc p15, 0, r3, c2, c0, 0 ");
asm("str r3, [r0], #4 "); // TTBR0
#ifdef __CPU_HAS_TTBR1
asm("mrc p15, 0, r2, c2, c0, 1 ");
asm("mrc p15, 0, r3, c2, c0, 2 ");
#else
asm("mov r2, #0 ");
asm("mov r3, #0 ");
#endif
asm("stmia r0!, {r2,r3} "); // TTBR1, TTBCR
asm("mrc p15, 0, r3, c3, c0, 0 ");
asm("str r3, [r0], #4 "); // DACR
#ifdef __CPU_MEMORY_TYPE_REMAPPING
asm("mrc p15, 0, r2, c10, c2, 0 ");
asm("mrc p15, 0, r3, c10, c2, 1 ");
#else
asm("mov r2, #0 ");
asm("mov r3, #0 ");
#endif
asm("stmia r0!, {r2,r3} "); // PRRR, NMRR
#ifdef __CPU_ARMV7
asm("mrc p15, 0, r3, c12, c0, 0 ");
#else
asm("mov r3, #0 ");
#endif
asm("str r3, [r0], #4 "); // VBAR
#if defined(__CPU_SA1) || defined(__CPU_ARM920T) || defined(__CPU_ARM925T) || defined(__CPU_ARMV5T) || defined(__CPU_ARMV6) || defined(__CPU_ARMV7)
asm("mrc p15, 0, r3, c13, c0, 0 ");
#else
asm("mov r3, #0 ");
#endif
asm("str r3, [r0], #4 "); // FCSEIDR
#if defined(__CPU_ARMV6) || defined(__CPU_ARMV7)
asm("mrc p15, 0, r3, c13, c0, 1 ");
#else
asm("mov r3, #0 ");
#endif
asm("str r3, [r0], #4 "); // CONTEXTIDR
#ifdef __CPU_HAS_CP15_THREAD_ID_REG
GET_RWRW_TID(,r2);
GET_RWRO_TID(,r3);
GET_RWNO_TID(,r12);
#else
asm("mov r2, #0 ");
asm("mov r3, #0 ");
asm("mov r12, #0 ");
#endif
asm("stmia r0!, {r2,r3,r12} "); // RWRWTID, RWROTID, RWNOTID
asm("mrc p15, 0, r2, c5, c0, 0 "); // DFSR
#ifdef __CPU_ARM_HAS_SPLIT_FSR
asm("mrc p15, 0, r3, c5, c0, 1 "); // IFSR
#else
asm("mov r3, #0 ");
#endif
asm("stmia r0!, {r2,r3} "); // DFSR, IFSR
#ifdef __CPU_ARMV7
asm("mrc p15, 0, r2, c5, c1, 0 "); // ADFSR
asm("mrc p15, 0, r3, c5, c1, 1 "); // AIFSR
#else
asm("mov r2, #0 ");
asm("mov r3, #0 ");
#endif
asm("stmia r0!, {r2,r3} "); // ADFSR, AIFSR
asm("mrc p15, 0, r2, c6, c0, 0 "); // DFAR
#ifdef __CPU_ARM_HAS_CP15_IFAR
asm("mrc p15, 0, r3, c6, c0, 2 "); // IFAR
#else
asm("mov r3, #0 ");
#endif
asm("stmia r0!, {r2,r3} "); // DFAR, IFAR
// zero spare words
asm("stmia r0!, {r4-r7} ");
asm("stmia r0!, {r4-r11} ");
#else // __CPU_HAS_MMU
asm("stmia r0!, {r4-r11} "); // no MMU so zero fill
asm("stmia r0!, {r4-r11} "); // no MMU so zero fill
asm("stmia r0!, {r4-r11} "); // no MMU so zero fill
asm("stmia r0!, {r4-r11} "); // no MMU so zero fill
#endif // __CPU_HAS_MMU
// zero iB[1]
asm("stmia r0!, {r4-r11} ");
asm("stmia r0!, {r4-r11} ");
asm("stmia r0!, {r4-r11} ");
asm("stmia r0!, {r4-r11} "); // r0 = &a.iMore[0]
asm("add r1, r0, #62*8 "); // r1 = &a.iExcCode
// Save VFP state
// Save order:
// FPEXC FPSCR
// VFPv2 ONLY: FPINST FPINST2
// D0-D3 D4-D7 D8-D11 D12-D15
// VFPv3 ONLY: D16-D19 D20-D23 D24-D27 D28-D31
#ifdef __CPU_HAS_VFP
GET_CAR(,r2);
asm("bic r2, r2, #0x00f00000 ");
#ifdef __VFP_V3
asm("bic r2, r2, #0xc0000000 "); // mask off ASEDIS, D32DIS
#endif
asm("orr r2, r2, #0x00500000 "); // enable privileged access to CP10, CP11
SET_CAR(,r2);
VFP_FMRX(,2,VFP_XREG_FPEXC); // r2=FPEXC
asm("orr r3, r2, #%a0" : : "i" ((TInt)VFP_FPEXC_EN));
asm("bic r3, r3, #%a0" : : "i" ((TInt)VFP_FPEXC_EX));
VFP_FMXR(,VFP_XREG_FPEXC,3); // enable VFP
__DATA_SYNC_BARRIER__(r4);
__INST_SYNC_BARRIER__(r4);
VFP_FMRX(,3,VFP_XREG_FPSCR); // r3=FPSCR
asm("stmia r0!, {r2,r3} "); //
#ifdef __VFP_V3
VFP_FSTMIADW(CC_AL,0,0,16); // save D0 - D15
VFP_FMRX(,3,VFP_XREG_MVFR0);
asm("tst r3, #%a0" : : "i" ((TInt)VFP_MVFR0_ASIMD32)); // check to see if all 32 Advanced SIMD registers are present
VFP_FSTMIADW(CC_NE,0,16,16); // if so then save D15 - D31 (don't need to check CPACR.D32DIS as it is cleared above)
#else
VFP_FMRX(,2,VFP_XREG_FPINST);
VFP_FMRX(,3,VFP_XREG_FPINST2);
asm("stmia r0!, {r2,r3} "); // FPINST, FPINST2
VFP_FSTMIADW(CC_AL,0,0,16); // save D0 - D15
#endif
#endif // __CPU_HAS_VFP
asm("1: ");
asm("cmp r0, r1 ");
asm("strlo r4, [r0], #4 "); // clear up to end of iMore[61]
asm("blo 1b ");
asm("mov r1, #%a0" : : "i" ((TInt)KMaxTInt));
asm("stmia r0!, {r1,r5-r7} "); // iExcCode=KMaxTInt, iCrashArgs[0...2]=0
asm("sub r0, r0, #1024 "); // r0 = &a
#ifdef __CPU_HAS_VFP
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iMore[0]));
VFP_FMXR(,VFP_XREG_FPEXC,2); // restore FPEXC
__DATA_SYNC_BARRIER__(r4);
__INST_SYNC_BARRIER__(r4);
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iA.iCPACR));
SET_CAR(,r2); // restore CPACR
#endif
asm("ldr r1, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iFlags));
asm("orr r1, r1, #0xC0 "); // interrupts off
asm("msr cpsr, r1 "); // restore CPSR with interrupts off
asm("ldmia r0, {r0-r11} "); // restore R4-R11
__JUMP(,lr);
}
/** Update the saved ARM registers with information from an exception
@internalTechnology
*/
__NAKED__ void Arm::UpdateState(SFullArmRegSet&, TArmExcInfo&)
{
asm("ldr r2, [r1, #%a0]" : : "i" _FOFF(TArmExcInfo, iExcCode));
asm("cmp r2, #%a0 " : : "i" ((TInt)EArmExceptionPrefetchAbort));
asm("ldmia r1!, {r2,r3,r12} ");
asm("streq r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iB[0].iIFAR));
asm("strne r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iB[0].iDFAR));
asm("streq r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iB[0].iIFSR));
asm("strne r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iB[0].iDFSR));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iSpsrSvc));
asm("add r1, r1, #4 ");
asm("ldmia r1!, {r2,r3,r12} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR13Svc));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR14Svc));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR0));
asm("ldmia r1!, {r2,r3,r12} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR1));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR2));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR3));
asm("ldmia r1!, {r2,r3,r12} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR4));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR5));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR6));
asm("ldmia r1!, {r2,r3,r12} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR7));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR8));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR9));
asm("ldmia r1!, {r2,r3,r12} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR10));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR11));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR12));
asm("ldmia r1!, {r2,r3,r12} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR13));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR14));
asm("str r12, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iExcCode));
asm("ldmia r1!, {r2,r3} ");
asm("str r2, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iR15));
asm("str r3, [r0, #%a0]" : : "i" _FOFF(SFullArmRegSet,iN.iFlags));
__JUMP(,lr);
}
/** Get a pointer to a stored integer register, accounting for registers which
are banked across modes.
@param a Pointer to saved register block
@param aRegNum Number of register required, 0-15 or -1 (indicates SPSR)
@param aMode Bottom 5 bits indicate which processor mode
Other bits of aMode are ignored
@return Pointer to the required saved register value
@internalTechnology
*/
__NAKED__ TArmReg* Arm::Reg(SFullArmRegSet& /*a*/, TInt /*aRegNum*/, TArmReg /*aMode*/)
{
asm("cmp r1, #8 "); // register number < 8 ?
asm("addlo r0, r0, r1, lsl #2 "); // register R0-R7 are not banked
asm("blo 0f ");
asm("cmp r1, #15 "); // register number = 15 ?
asm("addeq r0, r0, r1, lsl #2 "); // register R15 not banked
asm("movgt r0, #0 "); // no registers > 15
asm("bge 0f ");
asm("cmn r1, #1 ");
asm("movlt r0, #0 "); // no registers < -1
asm("blt 0f ");
asm("and r12, r2, #0x1F ");
asm("cmp r12, #0x11 "); // mode_fiq?
asm("beq 1f "); // skip if it is
asm("cmp r1, #13 ");
asm("addlo r0, r0, r1, lsl #2 "); // register R8-R12 are only banked in mode_fiq
asm("blo 0f ");
asm("cmp r12, #0x10 "); // mode_usr ?
asm("cmpne r12, #0x1F "); // if not, mode_sys ?
asm("bne 2f "); // skip if neither
asm("cmp r1, #16 ");
asm("addlo r0, r0, r1, lsl #2 "); // handle R13_usr, R14_usr
asm("movhs r0, #0 "); // no SPSR in mode_usr or mode_sys
asm("blo 0f ");
asm("1: "); // mode_fiq, regnum = 8-12
asm("2: "); // exception mode, regnum not 0-12 or 15
asm("cmn r1, #1 "); // regnum = -1 ?
asm("moveq r1, #15 "); // if so, change to 15
asm("sub r1, r1, #13 ");
asm("add r0, r0, r1, lsl #2 "); // add 0 for R13, 4 for R14, 8 for SPSR
asm("cmp r12, #0x16 ");
asm("addeq r0, r0, #12 "); // if mon, add offset from R13Fiq to R13Mon
asm("cmpne r12, #0x11 ");
asm("addeq r0, r0, #32 "); // if valid but not svc/abt/und/irq, add offset from R13Irq to R13Fiq
asm("cmpne r12, #0x12 ");
asm("addeq r0, r0, #12 "); // if valid but not svc/abt/und, add offset from R13Und to R13Irq
asm("cmpne r12, #0x1b ");
asm("addeq r0, r0, #12 "); // if valid but not svc/abt, add offset from R13Abt to R13Und
asm("cmpne r12, #0x17 ");
asm("addeq r0, r0, #12 "); // if valid but not svc, add offset from R13Svc to R13Abt
asm("cmpne r12, #0x13 ");
asm("addeq r0, r0, #%a0" : : "i" _FOFF(SFullArmRegSet, iN.iR13Svc)); // if valid mode add offset to R13Svc
asm("movne r0, #0 ");
asm("0: ");
__JUMP(,lr);
}
/** Restore all the ARM registers
@internalTechnology
*/
__NAKED__ void Arm::RestoreState(SFullArmRegSet&)
{
}
__NAKED__ EXPORT_C TBool BTrace::OutFilteredPcFormatBig(TUint32 a0, TUint32 aModuleUid, TUint32 aPc, TUint16 aFormatId, const TAny* aData, TInt aDataSize)
{
asm("mov r0, #0"); //Kernel side not implemented yet
}