Fix for bug 2283 (RVCT 4.0 support is missing from PDK 3.0.h)
Have multiple extension sections in the bld.inf, one for each version
of the compiler. The RVCT version building the tools will build the
runtime libraries for its version, but make sure we extract all the other
versions from zip archives. Also add the archive for RVCT4.
// Copyright (c) 1996-2009 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\direct\minit.cpp
//
//
#include <memmodel.h>
#include "cache_maintenance.h"
_LIT(KLitRamAlloc,"RamAlloc");
const TInt KMaxSupervisorStackSpace=0x200000;
void M::Init1()
{
__KTRACE_OPT2(KBOOT,KMMU,Kern::Printf("M::Init1"));
MM::UserDataSectionBase=TheRomHeader().iUserDataAddress;
MM::UserRomDataSectionEnd=TheRomHeader().iUserDataAddress+TheRomHeader().iTotalUserDataSize;
MM::UserDataSectionEnd = TheSuperPage().iRamBase + TheSuperPage().iTotalRamSize;
__KTRACE_OPT2(KBOOT,KMMU,Kern::Printf("MM::UserDataSectionBase=%08x",MM::UserDataSectionBase));
__KTRACE_OPT2(KBOOT,KMMU,Kern::Printf("MM::UserRomDataSectionEnd=%08x",MM::UserRomDataSectionEnd));
__KTRACE_OPT2(KBOOT,KMMU,Kern::Printf("MM::UserDataSectionEnd=%08x",MM::UserDataSectionEnd));
// Memory model dependent CPU stuff
MM::Init1();
// Set up cache info
CacheMaintenance::Init1();
}
void M::Init2()
{
__KTRACE_OPT2(KBOOT,KMMU,Kern::Printf("M::Init2"));
TInt userRam=MM::UserDataSectionEnd-MM::UserDataSectionBase;
TInt blocks=userRam>>MM::RamBlockShift;
MM::RamAllocator=TBitMapAllocator::New(blocks,ETrue);
if (!MM::RamAllocator)
MM::Panic(MM::ERamAllocCreateFailed);
TInt used_blocks=(MM::UserRomDataSectionEnd-MM::UserDataSectionBase)>>MM::RamBlockShift;
if (used_blocks)
MM::RamAllocator->Alloc(0,used_blocks);
__KTRACE_OPT(KBOOT,Kern::Printf("%d blocks, %d used",blocks,used_blocks));
TInt r=K::MutexCreate((DMutex*&)MM::RamAllocatorMutex, KLitRamAlloc, NULL, EFalse, KMutexOrdRamAlloc);
if (r!=KErrNone)
MM::Panic(MM::ERamAllocMutexCreateFailed);
const SRamBank* banks = (const SRamBank*)TheSuperPage().iRamBootData;
TInt nBanks = 0;
TInt maxBankBlocks = 0;
TInt bnum = 0;
const SRamBank* pB = banks;
for (; pB->iSize; ++nBanks, ++pB)
{
TInt nblocks = pB->iSize >> MM::RamBlockShift;
TInt abnum = bnum &~ 31;
TInt a_end = (bnum + nblocks + 31)&~31;
TInt a_count = a_end - abnum;
if (a_count > maxBankBlocks)
maxBankBlocks = a_count;
bnum += (pB->iSize >> MM::RamBlockShift);
}
__KTRACE_OPT(KBOOT,Kern::Printf("%d banks, max bank blocks %08x", nBanks, maxBankBlocks));
if (nBanks>1)
{
MM::SecondaryAllocator = TBitMapAllocator::New(maxBankBlocks, ETrue);
if (!MM::SecondaryAllocator)
MM::Panic(MM::ESecAllocCreateFailed);
}
}
void M::Init3()
{
// Third phase MMU initialisation
}
TInt M::InitSvHeapChunk(DChunk* aChunk, TInt aSize)
{
DMemModelChunk* pC=(DMemModelChunk*)aChunk;
TLinAddr base = TheRomHeader().iKernDataAddress;
K::HeapInfo.iChunk = aChunk;
K::HeapInfo.iBase = (TUint8*)base;
K::HeapInfo.iMaxSize = pC->MaxSize();
pC->SetFixedAddress(base, aSize);
__KTRACE_OPT(KBOOT,Kern::Printf("Created SvHeap chunk, addr %08X, init size %08X max size %08X",pC->Base(),aSize,pC->MaxSize()));
return KErrNone;
}
TInt M::InitSvStackChunk()
{
return KErrNone;
}