// Copyright (c) 1994-2009 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\memmodel\epoc\moving\arm\xkernel.cia
//
//
#include <e32cia.h>
#include <arm_mem.h>
__NAKED__ void DArmPlatChunk::MoveHomePdes(TLinAddr /*aOldAddr*/, TLinAddr /*aNewAddr*/)
{
asm("mov r2, r2, lsr #20 "); // r2=pde index for new addr
asm("subs r2, r2, r1, lsr #20 "); // subtract pde index for old addr
__JUMP(eq,lr); // if zero, nothing to do
asm("ldr r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iNumPdes));
asm("cmp r1, #0 ");
__JUMP(eq,lr); // if chunk empty, nothing to do
asm("ldr r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomePdes));
asm("add r1, r1, r2, asl #2 "); // move home pde address
asm("str r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomePdes));
__JUMP(,lr);
}
__NAKED__ void DArmPlatChunk::MoveCurrentPdes(TLinAddr /*aOldAddr*/, TLinAddr /*aNewAddr*/)
{
asm("mov r2, r2, lsr #20 "); // r2=pde index for new addr
asm("subs r2, r2, r1, lsr #20 "); // subtract pde index for old addr
__JUMP(eq,lr); // if zero, nothing to do
asm("ldr r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iNumPdes));
asm("cmp r1, #0 ");
__JUMP(eq,lr); // if chunk empty, nothing to do
asm("ldr r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdes));
asm("add r1, r1, r2, asl #2 "); // move current pde address
asm("str r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdes));
__JUMP(,lr);
}
__NAKED__ void DArmPlatChunk::AddPde(TInt /*aOffset*/)
{
asm("mov r1, r1, lsr #20 "); // r1=pde number
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iMaxSize));
asm("cmp r2, #0x02000000 ");
asm("ldr r3, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdeBitMap));
asm("bhi add_pde_large ");
asm("mov ip, #1 ");
asm("orr r3, r3, ip, lsl r1 "); // set bit in bitmap
asm("str r3, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdeBitMap));
asm("b scan_small_bitmap ");
asm("add_pde_large: ");
asm("stmfd sp!, {r4,lr} ");
asm("mov lr, r1, lsr #5 "); // lr=word number in bitmap
asm("and r1, r1, #31 "); // r1=bit number in word
asm("ldr r4, [r3, lr, lsl #2] ");
asm("mov ip, #1 ");
asm("orr r4, r4, ip, lsl r1 ");
asm("str r4, [r3, lr, lsl #2] "); // set bit in bitmap
asm("b scan_large_bitmap ");
}
__NAKED__ void DArmPlatChunk::RemovePde(TInt /*anOffset*/)
{
asm("mov r1, r1, lsr #20 "); // r1=pde number
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iMaxSize));
asm("cmp r2, #0x02000000 ");
asm("ldr r3, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdeBitMap));
asm("bhi rem_pde_large ");
asm("mov ip, #1 ");
asm("bics r3, r3, ip, lsl r1 "); // clear bit in bitmap
asm("str r3, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdeBitMap));
asm("beq empty_chunk "); // if chunk empty, skip rest
asm("scan_small_bitmap: "); // r3 contains nonzero bitmap
#ifdef __CPU_ARM_HAS_CLZ
asm("sub r2, r3, #1 "); // ip will hold index of first pde
asm("eor r2, r2, r3 ");
CLZ(12,2);
asm("rsb r12, r12, #31 ");
asm("mov r3, r3, lsr r12 "); // shift bitmap so bit 0 set
CLZ(1, 3);
asm("rsb r1, r1, #32 "); // r1 will be 1+most significant 1 in r3
#else
asm("mov ip, #0 "); // ip will hold index of first pde
asm("movs r2, r3, lsl #16 "); // test if bottom 16 bits zero
asm("moveq r3, r3, lsr #16 "); // if bottom 16 zero, shift right by 16
asm("addeq ip, ip, #16 "); // and add 16 to lsb index
asm("tst r3, #0xff ");
asm("moveq r3, r3, lsr #8 ");
asm("addeq ip, ip, #8 ");
asm("tst r3, #0x0f ");
asm("moveq r3, r3, lsr #4 ");
asm("addeq ip, ip, #4 ");
asm("tst r3, #0x03 ");
asm("moveq r3, r3, lsr #2 ");
asm("addeq ip, ip, #2 ");
asm("tst r3, #0x01 ");
asm("moveq r3, r3, lsr #1 ");
asm("addeq ip, ip, #1 "); // ip=number of right shifts applied, r3 bit 0 set
asm("mov r1, #32 "); // r1 will be 1+most significant 1 in r3
asm("cmp r3, #0x00010000 ");
asm("movcc r3, r3, lsl #16 ");
asm("subcc r1, r1, #16 ");
asm("cmp r3, #0x01000000 ");
asm("movcc r3, r3, lsl #8 ");
asm("subcc r1, r1, #8 ");
asm("cmp r3, #0x10000000 ");
asm("movcc r3, r3, lsl #4 ");
asm("subcc r1, r1, #4 ");
asm("cmp r3, #0x40000000 ");
asm("movcc r3, r3, lsl #2 ");
asm("subcc r1, r1, #2 ");
asm("cmp r3, #0x80000000 ");
asm("movcc r3, r3, lsl #1 ");
asm("subcc r1, r1, #1 ");
#endif
asm("scan_bitmap_end: ");
asm("str r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iNumPdes)); // r1 gives number of PDEs in range
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iBase));
asm("add r2, ip, r2, lsr #20 "); // r2=pde index of first current pde
asm("mov r2, r2, lsl #2 ");
asm("add r2, r2, #%a0" : : "i" ((TInt)KPageDirectoryBase)); // r2->first current pde
asm("str r2, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdes));
asm("ldr r2, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomeBase));
asm("add r2, ip, r2, lsr #20 "); // r2=pde index of first home pde
asm("mov r2, r2, lsl #2 ");
asm("add r2, r2, #%a0" : : "i" ((TInt)KPageDirectoryBase)); // r2->first home pde
asm("str r2, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomePdes));
__JUMP(,lr);
asm("empty_chunk: ");
asm("mov r1, #0 ");
asm("str r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iNumPdes));
asm("str r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iPdes));
asm("str r1, [r0, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomePdes));
__JUMP(,lr);
asm("rem_pde_large: ");
asm("stmfd sp!, {r4,lr} ");
asm("mov lr, r1, lsr #5 "); // lr=word number in bitmap
asm("and r1, r1, #31 "); // r1=bit number in word
asm("ldr r4, [r3, lr, lsl #2] ");
asm("mov ip, #1 ");
asm("bic r4, r4, ip, lsl r1 ");
asm("str r4, [r3, lr, lsl #2] "); // set bit in bitmap
asm("scan_large_bitmap: ");
// r0=this, r2=max size, r3->pde bit map
asm("add r2, r2, #0x1f00000 ");
asm("mov r2, r2, lsr #25 "); // r2=number of words in bitmap
asm("add r2, r3, r2, lsl #2 "); // r2=bitmap end address
asm("mov r4, r3 "); // save bitmap start address
asm("scan_large_1: ");
asm("ldr ip, [r3], #4 ");
asm("cmp ip, #0 ");
asm("bne scan_large_2 "); // found non-empty word
asm("cmp r3, r2 ");
asm("bne scan_large_1 "); // if not reached end, do next word
asm("ldmfd sp!, {r4,lr} ");
asm("b empty_chunk "); // branch if no bits set
asm("scan_large_2: ");
asm("sub r1, r3, r4 ");
asm("sub r1, r1, #4 ");
asm("mov r1, r1, lsl #3 "); // r1=bit number of lsb of this word
#ifdef __CPU_ARM_HAS_CLZ
asm("sub lr, ip, #1 "); // ip will hold index of first pde
asm("eor ip, lr, ip ");
CLZ(12, 12);
asm("rsb ip, ip, #31 ");
asm("add r1, r1, ip "); // r1 now = first occupied pde offset
#else
asm("movs lr, ip, lsl #16 ");
asm("moveq ip, ip, lsr #16 ");
asm("addeq r1, r1, #16 ");
asm("tst ip, #0xff ");
asm("moveq ip, ip, lsr #8 ");
asm("addeq r1, r1, #8 ");
asm("tst ip, #0x0f ");
asm("moveq ip, ip, lsr #4 ");
asm("addeq r1, r1, #4 ");
asm("tst ip, #0x03 ");
asm("moveq ip, ip, lsr #2 ");
asm("addeq r1, r1, #2 ");
asm("tst ip, #0x01 ");
asm("moveq ip, ip, lsr #1 ");
asm("addeq r1, r1, #1 "); // r1 now = first occupied pde offset
#endif
asm("scan_large_3: ");
asm("ldr ip, [r2, #-4]! "); // fetch words from end of bitmap
asm("cmp ip, #0 ");
asm("beq scan_large_3 "); // we know there is at least one non-zero word
asm("sub r2, r2, r4 ");
asm("mov r2, r2, lsl #3 "); // r2=bit number of lsb of this word
#ifdef __CPU_ARM_HAS_CLZ
CLZ(12, 12);
asm("rsb ip, ip, #31 ");
asm("add r2, r2, ip "); // r2 now = last occupied pde offset
#else
asm("movs lr, ip, lsr #16 ");
asm("movne ip, lr ");
asm("addne r2, r2, #16 ");
asm("movs lr, ip, lsr #8 ");
asm("movne ip, lr ");
asm("addne r2, r2, #8 ");
asm("movs lr, ip, lsr #4 ");
asm("movne ip, lr ");
asm("addne r2, r2, #4 ");
asm("movs lr, ip, lsr #2 ");
asm("movne ip, lr ");
asm("addne r2, r2, #2 ");
asm("movs lr, ip, lsr #1 ");
asm("movne ip, lr ");
asm("addne r2, r2, #1 "); // r2 now = last occupied pde offset
#endif
asm("sub r3, r2, r1 "); // r3=last-first
asm("mov ip, r1 "); // ip=first
asm("add r1, r3, #1 "); // r1 = number of pdes in range
asm("ldmfd sp!, {r4,lr} ");
asm("b scan_bitmap_end "); // go back to set pde info
}
__NAKED__ TBool Exc::IsMagic(TLinAddr /*anAddress*/)
//
// Return TRUE if anAddress is a 'magic' exception handling instruction
//
{
asm("adr r1, __magic_addresses "); // r1 points to list of magic addresses
asm("is_magic_1: ");
asm("ldr r2, [r1], #4 "); // r2=next magic address to check
asm("cmp r2, r0 "); // is r0=magic address?
asm("cmpne r2, #0 "); // if not, have we reached end of list?
asm("bne is_magic_1 "); // if neither, check next address
asm("movs r0, r2 "); // r0=0 if not magic, r0 unchanged if magic
__JUMP(,lr);
asm("__magic_addresses: ");
asm(".word __magic_address_kusaferead ");
asm(".word __magic_address_saferead ");
asm(".word __magic_address_kusafewrite ");
asm(".word __magic_address_safewrite ");
asm(".word __magic_address_msg_lookup_1 "); // in preprocess handler
asm(".word __magic_address_readdesheader1 ");
asm(".word __magic_address_readdesheader2 ");
asm(".word __magic_address_readdesheader3 ");
#ifdef __MESSAGE_MACHINE_CODED_2__
asm(".word __magic_address_msg_lookup_2 ");
#endif
#ifdef __CLIENT_REQUEST_MACHINE_CODED__
asm(".word __magic_address_client_request_callback");
asm(".word __magic_address_svr_accept_1 ");
asm(".word __magic_address_svr_accept_2 ");
asm(".word __magic_address_svr_accept_3 ");
asm(".word __magic_address_svr_accept_4 ");
asm(".word __magic_address_svr_accept_5 ");
asm(".word __magic_address_svr_accept_6 ");
asm(".word __magic_address_svr_accept_7 ");
asm(".word __magic_address_svr_accept_8 ");
#endif
#ifdef __REQUEST_COMPLETE_MACHINE_CODED__
asm(".word __magic_address_reqc ");
asm(".word __magic_address_kern_request_complete ");
#endif
// list terminator
asm(".word 0 ");
}
__NAKED__ TAny* MM::CurrentAddress(DThread* /*aThread*/, const TAny* /*aPtr*/, TInt /*aSize*/, TBool /*aWrite*/)
//
// Return the current base address corresponding to run address region
// aPtr to aPtr+aBase-1 in the context of aThread.
// aWrite indicates whether the address is intended for writing (aWrite=TRUE) or reading (aWrite=FALSE).
// Return NULL if the address range is not all accessible to aThread for access type specified by aWrite.
// aWrite=FALSE allows access to the ROM and RAM-loaded code chunks whereas aWrite=TRUE disallows these.
// NOTE THIS FUNCTION CONTAINS KNOWLEDGE OF FIXED LINEAR ADDRESSES (the RAM drive and HIVECS area).
//
// ALLERT! the ip register returns a pointer to the chunk which contains the addresses (null if none)
//
{
asm("CurrentAddress:");
asm("ldr r0, [r0, #%a0]" : : "i" _FOFF(DThread, iOwningProcess));
asm("stmfd sp!, {r4,r5,lr} ");
asm("eor r4, r1, #0x40000000 "); // r4<0x20000000u for RAM drive
asm("cmp r4, #0x20000000 "); // Check for RAM drive - ASSUMES RAM DRIVE IS AT 40000000-5FFFFFFF
asm("ldr lr, [r0, #%a0]!" : : "i" _FOFF(DMemModelProcess, iNumChunks)); // step r0 on to iChunks[0]
asm("bcc lookup_chunk_3 "); // branch if RAM drive
asm("subs lr, lr, #1 ");
asm("bcc lookup_chunk_2 "); // no chunks so do read check
asm("lookup_chunk_1: ");
asm("ldmib r0!, {r4,ip} "); // r4=data section base, ip=chunk ptr
asm("add r0, r0, #4 "); // move to next entry
asm("subs r4, r1, r4 "); // r4=offset
asm("ldrcs r5, [ip, #%a0]" : : "i" _FOFF(DChunk,iMaxSize)); // if offset>=0, r5=chunk max size
asm("cmpcs r4, r5 "); // and compare offset to max size
asm("subcss lr, lr, #1 "); // if offset>=max size, decrement counter
asm("bcs lookup_chunk_1 "); // loop if more chunks to check
asm("cmp lr, #0 "); // did we find chunk?
asm("ldrge r0, [ip, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomeRegionOffset));
asm("ldrge r5, [ip, #%a0]" : : "i" _FOFF(DMemModelChunk,iHomeRegionSize));
asm("ldrge lr, [ip, #%a0]" : : "i" _FOFF(DChunk,iBase));
asm("cmpge r4, r0 "); // if chunk not found or offset<iHomeRegionOffset, do read check
asm("blt lookup_chunk_2 ");
asm("add r0, r0, r5 "); // r0=home region offset+home region size
asm("add r5, r4, r2 "); // r5=offset after end of block
asm("cmp r5, r0 "); // check if offset after end<=iHomeRegionOffset+iHomeRegionSize
asm("addle r0, lr, r4 "); // if so, r0=current chunk base + offset
asm("ldmlefd sp!, {r4,r5,pc} "); // and we are done
asm("lookup_chunk_2: "); // come here if address not found in a chunk
asm("mov ip, #0"); // ip = 0 to indicate chunk not found
asm("ldr r4, __code_limit ");
asm("mov r0, #0 ");
asm("cmn r1, #0x00100000 "); // address in hivecs area?
asm("ldr r4, [r4] "); // r4 = lowest legitimate code address
asm("ldmcsfd sp!, {r4,r5,pc} "); // if in hivecs, return NULL
asm("cmp r3, #0 "); // is this address intended for writing?
asm("ldmnefd sp!, {r4,r5,pc} "); // if it is, return NULL
asm("cmp r1, r4 "); // check if address is in RAM-loaded code or ROM
asm("ldmccfd sp!, {r4,r5,pc} "); // if not, return NULL
asm("adds r4, r1, r2 "); // r4 = end address of requested region
asm("ldmcsfd sp!, {r4,r5,pc} "); // if it wrapped, return NULL
asm("cmn r4, #0x100000 "); // if it didn't wrap, check if it reaches into hivecs area
asm("movls r0, r1 "); // if not, addr is OK for reading
asm("ldmfd sp!, {r4,r5,pc} ");
asm("lookup_chunk_3: "); // come here if address in RAM drive
asm("mov ip, #0"); // ip = 0 to indicate chunk not found
asm("ldr r3, __f32 "); // r3=&K::TheFileServerProcess
asm("sub r4, r0, #%a0" : : "i" _FOFF(DMemModelProcess, iNumChunks)); // r4=aThread->iOwningProcess
asm("mov r0, #0 ");
asm("ldr r3, [r3] "); // r3=K::TheFileServerProcess
asm("add r5, r1, r2 "); // r5=end address of requested region + 1
asm("cmp r5, #0x60000000 "); // is this past the end of the RAM drive? ASSUMES ADDRESS OF RAM DRIVE
asm("cmpls r3, r4 "); // if not, is aThread part of F32?
asm("moveq r0, r1 "); // if it is, allow the access and return the address unaltered
asm("ldmfd sp!, {r4,r5,pc} "); // else return NULL
asm("__f32: ");
asm(".word " CSM_ZN1K20TheFileServerProcessE );
asm("__code_limit: ");
asm(".word %a0" : : "i" ((TInt)&::TheMmu.iUserCodeBase) );
}