// Copyright (c) 1995-2009 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\include\u32std.h

//

//

/**

 @file

 @internalComponent

 @released

*/

#ifndef __U32STD_H__

#define __U32STD_H__

#include <e32cmn.h>

#ifndef SYMBIAN_ENABLE_SPLIT_HEADERS

#include <e32cmn_private.h>

#endif

#include <e32hal.h>

#include <e32lmsg.h>

#include <e32event.h>

#include <e32ldr.h>

#include <e32power.h>

#include <e32shbufcmn.h>

#include <e32property.h>

#include <u32property.h>

#include <u32hal.h>

#include <cpudefs.h>

#ifdef __MARM__

#define	EKA2_ENTRY_POINT_VERSION_IDENTIFIER	\

	asm("tst pc, #%a0" : : "i" ((TInt)0) )

#endif

struct TUnicodeDataSet;                 // forward declaration

struct TCollationDataSet;               // forward declaration

/*

The LCharSet structure is used in Unicode builds to supply locale-specific

character attribute and collation data.

The structure is defined in both builds to avoid having to have a dummy ExecHandler::GetLocaleCharSet function

with a different signature in the 8-bit build.

*/

struct LCharSet

	{

	const TUnicodeDataSet* iCharDataSet;			// if non-null, character data overriding standard Unicode data

	const TCollationDataSet* iCollationDataSet;		// if non-null, locale-specific collation data

	};

extern const LCharSet* GetLocaleCharSet();

/** @internalTechnology */

const TInt KNumLocaleExports = 22;

//

// The bits in the type table (non-Unicode build only)

//

#ifndef _UNICODE

/** @internalTechnology */

const TUint __U=0x01; // Uppercase letter

/** @internalTechnology */

const TUint __L=0x02; // Lowercase letter

/** @internalTechnology */

const TUint __D=0x04; // Decimal digit

/** @internalTechnology */

const TUint __S=0x08; // Space

/** @internalTechnology */

const TUint __P=0x10; // Punctuation

/** @internalTechnology */

const TUint __C=0x20; // Control character

/** @internalTechnology */

const TUint __X=0x40; // Hex digit

/** @internalTechnology */

const TUint __B=0x80; // A blank character

#endif

//

// Time set mode parameters for setting system time and offset

//

enum TTimeSetMode

	{

	ETimeSetTime = 1,    // set the time to the value given, else leave it unchanged

	ETimeSetOffset = 2,  // set the offset to the value given, else leave it unchanged

	ETimeSetAllowTimeReversal = 4,  // allow time to go backwards

	ETimeSetNoTimeUpdate = 8,       // Don't restart second queue or notify changes - not valid with ESetTime, used early in boot only

	ETimeSetLocalTime = 16,			// Set time in local time, instead of UTC

	ETimeSetSecure = 32,  // use when setting the secure hardware clock

	};

//

enum TMatchType {EMatchNormal,EMatchFolded,EMatchCollated};

//

// Constants for descriptor implementation code

//

enum TDesType {EBufC,EPtrC,EPtr,EBuf,EBufCPtr};

const TUint KMaskDesLength=0xfffffff;

const TInt KShiftDesType=28;

//

// Constants for iFlags in DProcess and DThread

//

const TUint KThreadFlagProcessCritical		= 0x00000001;	// thread panic panics process

const TUint KThreadFlagProcessPermanent		= 0x00000002;	// thread exit of any kind causes process to exit (=main)

const TUint KThreadFlagSystemCritical		= 0x00000004;	// thread panic reboots entire system

const TUint KThreadFlagSystemPermanent		= 0x00000008;	// thread exit of any kind reboots entire system

const TUint KThreadFlagOriginal				= 0x00000010;

const TUint KThreadFlagLastChance			= 0x00000020;

const TUint KThreadFlagRealtime				= 0x00000040;	// thread will be panicked when using some non-realtime functions

const TUint KThreadFlagRealtimeTest			= 0x00000080;	// non-realtime functions only warn rather than panic

const TUint KThreadFlagLocalThreadDataValid	= 0x00000100;	// thread has valid local thread data

const TUint KProcessFlagPriorityControl		= 0x40000000;

const TUint KProcessFlagJustInTime			= 0x80000000;

const TUint KProcessFlagSystemCritical		= KThreadFlagSystemCritical;	// process panic reboots entire system

const TUint KProcessFlagSystemPermanent		= KThreadFlagSystemPermanent;	// process exit of any kind reboots entire system

//

const TUint KThreadHandle=0x40000000;

//

struct SPtrC8 {TInt length;const TUint8 *ptr;};

struct SBufC8 {TInt length;TUint8 buf[1];};

struct SPtr8 {TInt length;TInt maxLength;TUint8 *ptr;};

struct SBuf8 {TInt length;TInt maxLength;TUint8 buf[1];};

struct SBufCPtr8 {TInt length;TInt maxLength;SBufC8 *ptr;};

struct SPtrC16 {TInt length;const TUint16 *ptr;};

struct SBufC16 {TInt length;TUint16 buf[1];};

struct SPtr16 {TInt length;TInt maxLength;TUint16 *ptr;};

struct SBuf16 {TInt length;TInt maxLength;TUint16 buf[1];};

struct SBufCPtr16 {TInt length;TInt maxLength;SBufC16 *ptr;};

//

// Flags used for IPC copy functions

//

const TInt KChunkShiftBy0=0;

const TInt KChunkShiftBy1=KMinTInt;

const TInt KIpcDirRead=0;

const TInt KIpcDirWrite=0x10000000;

class TChunkCreate

	{

public:

	// Attributes for chunk creation that are used by both euser and the kernel

	// by classes TChunkCreateInfo and SChunkCreateInfo, respectively.

	enum TChunkCreateAtt

		{

		ENormal				= 0x00000000,

		EDoubleEnded		= 0x00000001,

		EDisconnected		= 0x00000002,

		ECache				= 0x00000003,

		EMappingMask		= 0x0000000f,

		ELocal				= 0x00000000,

		EGlobal				= 0x00000010,

		EData				= 0x00000000,

		ECode				= 0x00000020,

		EMemoryNotOwned		= 0x00000040,

		// Force local chunk to be named.  Only required for thread heap

		// chunks, all other local chunks should be nameless.

		ELocalNamed 		= 0x000000080,

		// Paging attributes for chunks.

		EPagingUnspec		= 0x00000000,

		EPaged				= 0x80000000,

		EUnpaged			= 0x40000000,

		EPagingMask 		= EPaged | EUnpaged,

		EChunkCreateAttMask =	EMappingMask | EGlobal | ECode |

		};

public:

	TUint iAtt;

	TBool iForceFixed;

	TInt iInitialBottom;

	TInt iInitialTop;

	TInt iMaxSize;

	TUint8 iClearByte;

	};

enum TChunkRestrictions

	{

	// Keep this in sync with definitions in RChunk

	EChunkPreventAdjust = 0x01,  // Disallow Adjust, Commit, Allocate and Decommit

	};

class TChannelDoCreate

	{

public:

	TVersion iVer;

	const TDesC *iName;

	const TDesC *iPhysicalDevice;

	const TDesC8 *iInfo;

	};

class TCreateSession

	{

public:

	TVersion iVer;

	TInt iMessageSlots;

	};

enum TObjectType

	{

	EThread=0,

	EProcess,

	EChunk,

	ELibrary,

	ESemaphore,

	EMutex,

	ETimer,

	EServer,

	ESession,

	ELogicalDevice,

	EPhysicalDevice,

	ELogicalChannel,

	EChangeNotifier,

	EUndertaker,

	EMsgQueue,

	EPropertyRef,

	ECondVar,

	EShPool,

	EShBuf,

	ENumObjectTypes,	// number of DObject-derived types

	EObjectTypeAny=-1,

	EIpcMessageD=0x20,	// lookup IPC message handle, allow disconnect

	EIpcMessage=0x21,	// lookup IPC message handle, don't allow disconnect

	EIpcClient=0x22,	// lookup IPC message client, don't allow disconnect

	};

class TObjectOpenInfo

	{

public:

	TObjectType iObjType;

	TBool isReadOnly;

	};

class TChannelCreateInfo

	{

public:

	TVersion iVersion;

	TInt iUnit;

	const TDesC* iPhysicalDevice;

	const TDesC8* iInfo;

	};

#if defined(_UNICODE) && !defined(__KERNEL_MODE__)

class TChannelCreateInfo8

	{

public:

	TVersion iVersion;

	TInt iUnit;

	const TDesC8* iPhysicalDevice;

	const TDesC8* iInfo;

	};

#else

typedef TChannelCreateInfo TChannelCreateInfo8;

#endif

const TInt KMaxThreadCreateInfo = 256;

struct SThreadCreateInfo

	{

	TAny* iHandle;

	TInt iType;

	TThreadFunction iFunction;

	TAny* iPtr;

	TAny* iSupervisorStack;

	TInt iSupervisorStackSize;

	TAny* iUserStack;

	TInt iUserStackSize;

	TInt iInitialThreadPriority;

	TPtrC iName;

	TInt iTotalSize;	// Size including any extras (must be a multiple of 8 bytes)

	};

enum TThreadCreationFlags

	{

	ETraceHeapAllocs 				= 0x00000001,

	EMonitorHeapMemory				= 0x00000002,

	EThreadCreateFlagPaged			= 0x00000004,

	EThreadCreateFlagUnpaged		= 0x00000008,

	EThreadCreateFlagPagingUnspec	= 0x00000000,

	EThreadCreateFlagPagingMask	= EThreadCreateFlagPaged | EThreadCreateFlagUnpaged,

	EThreadCreateFlagMask = ETraceHeapAllocs | EMonitorHeapMemory | EThreadCreateFlagPagingMask,

	};

struct SStdEpocThreadCreateInfo : public SThreadCreateInfo

	{

	SStdEpocThreadCreateInfo()

		: iFlags(0)	// Must be clear on creation.

		{

		};

	RAllocator* iAllocator;

	TInt iHeapInitialSize;

	TInt iHeapMaxSize;

	TUint iFlags;

	};

#if defined(_UNICODE) && !defined(__KERNEL_MODE__)

struct SThreadCreateInfo8

	{

	TAny* iHandle;

	TInt iType;

	TThreadFunction iFunction;

	TAny* iPtr;

	TAny* iSupervisorStack;

	TInt iSupervisorStackSize;

	TAny* iUserStack;

	TInt iUserStackSize;

	TInt iInitialThreadPriority;

	TPtrC8 iName;

	TInt iTotalSize;	// size including any extras

	};

struct SStdEpocThreadCreateInfo8 : public SThreadCreateInfo8

	{

	SStdEpocThreadCreateInfo8()

		: iFlags(0) // Must be clear on creation.

		{

		};

	RAllocator* iAllocator;

	TInt iHeapInitialSize;

	TInt iHeapMaxSize;

	TUint iFlags;

	};

#else

typedef SThreadCreateInfo SThreadCreateInfo8;

typedef SStdEpocThreadCreateInfo SStdEpocThreadCreateInfo8;

#endif

struct SIpcCopyInfo

	{

	TUint8* iLocalPtr;

	TInt iLocalLen;

	TInt iFlags;

	};

enum TChunkAdjust

	{

	EChunkAdjust=0,

	EChunkAdjustDoubleEnded=1,

	EChunkCommit=2,

	EChunkDecommit=3,

	EChunkAllocate=4,

	EChunkUnlock=5,

	EChunkLock=6

	};

enum TMemModelAttributes

	{

	EMemModelTypeMask=0xf,					// bottom 4 bits give type of memory model

	EMemModelTypeDirect=0,					// direct memory model on hardware

	EMemModelTypeMoving=1,					// moving memory model on hardware

	EMemModelTypeMultiple=2,				// multiple memory model on hardware

	EMemModelTypeEmul=3,					// emulation using single host process

	EMemModelTypeFlexible=4,				// flexible memory model on hardware

	EMemModelAttrRomPaging=0x10,			// Demand paging of XIP ROM

	EMemModelAttrCodePaging=0x20,			// Demand paging of RAM loaded code

	EMemModelAttrDataPaging=0x40,			// Demand paging of all RAM

	EMemModelAttrPagingMask=0xf0,			// Mask for demand paging attributes

	EMemModelAttrNonExProt=(TInt)0x80000000,// accesses to nonexistent addresses are trapped

	EMemModelAttrKernProt=0x40000000,		// accesses to kernel memory from user mode are trapped

	EMemModelAttrWriteProt=0x20000000,		// addresses can be marked as read-only; writes to these are trapped

	EMemModelAttrVA=0x10000000,				// system supports virtual addresses

	EMemModelAttrProcessProt=0x08000000,	// accesses to other processes' memory are trapped

	EMemModelAttrSameVA=0x04000000,			// different processes map the same virtual address to different physical addresses

	EMemModelAttrSupportFixed=0x02000000,	// 'fixed' processes are supported

	EMemModelAttrSvKernProt=0x01000000,		// unexpected accesses to kernel memory within an executive call are trapped

	EMemModelAttrIPCKernProt=0x00800000,	// accesses to kernel memory via IPC are trapped

	EMemModelAttrIPCFullProt=0x00400000,	// accesses via IPC have same protection as user mode

	EMemModelAttrRamCodeProt=0x00200000,	// RAM-loaded code is only visible to processes which have loaded it

	};

/** @test */

enum TKernelHeapDebugFunction {EDbgMarkStart,EDbgMarkCheck,EDbgMarkEnd,EDbgSetAllocFail,EDbgSetBurstAllocFail,EDbgCheckFailure};

/** @test */

class TKernelHeapMarkCheckInfo

	{

public:

	TBool iCountAll;

	const TDesC8* iFileName;

	TInt iLineNum;

	};

//

class TTrapHandler;

class CActiveScheduler;

class TLocale;

//

//

//

// Handler below is used by test prints to trucate rather than panic the caller.

//

#if defined(_UNICODE) && !defined(__KERNEL_MODE__)

NONSHARABLE_CLASS(TestOverflowTruncate) : public TDes16Overflow

	{

public:

	virtual void Overflow(TDes16 &aDes);

	};

#else

NONSHARABLE_CLASS(TestOverflowTruncate) : public TDes8Overflow

	{

public:

	virtual void Overflow(TDes8 &aDes);

	};

#endif

//

/********************************************

 * Thread local storage entry

 ********************************************/

struct STls

	{

	TInt	iHandle;

	TInt	iDllUid;

	TAny*	iPtr;

	};

const TInt KDllUid_Default = 0;		// for ROM DLLs and direct calls to UserSvr::DllTls

const TInt KDllUid_Special = -1;	// used on emulator to instruct the kernel to get the DLL UID from the module handle

/********************************************

 * Entry point call values

 ********************************************/

const TInt	KModuleEntryReasonProcessInit		=0;		// Process start

const TInt	KModuleEntryReasonThreadInit		=1;		// Start new thread

const TInt	KModuleEntryReasonProcessAttach		=2;		// Process attach (init static data)

const TInt	KModuleEntryReasonProcessDetach		=3;		// Process detach (destroy static data)

const TInt	KModuleEntryReasonException			=4;		// Handle exception

const TInt	KModuleEntryReasonVariantInit0		=-3;	// Call variant static constructors

/** @publishedPartner

	@released

*/

const TInt	KModuleEntryReasonExtensionInit0	=-2;	// Extension early initialisation check

/** @publishedPartner

	@released

*/

const TInt	KModuleEntryReasonExtensionInit1	=-1;	// Extension initialisation

/**

	Flags returned by Exec::KernelConfigFlags()

*/

enum TKernelConfigFlags

	{

	EKernelConfigIpcV1Available = 1<<0,

	EKernelConfigPlatSecEnforcement = 1<<1,

	EKernelConfigPlatSecDiagnostics = 1<<2,

	EKernelConfigPlatSecProcessIsolation = 1<<3,

	EKernelConfigPlatSecEnforceSysBin = 1<<4,

	// paging policy values use by 2-bit code and data paging policy enums...

	EKernelConfigPagingPolicyNoPaging = 0,

	EKernelConfigPagingPolicyAlwaysPage = 1,

	EKernelConfigPagingPolicyDefaultUnpaged = 2,

	EKernelConfigPagingPolicyDefaultPaged = 3,

	EKernelConfigCodePagingPolicyShift			= 5,

	EKernelConfigCodePagingPolicyMask			= 3<<5,

	EKernelConfigCodePagingPolicyNoPaging		= EKernelConfigPagingPolicyNoPaging<<5,

	EKernelConfigCodePagingPolicyAlwaysPage		= EKernelConfigPagingPolicyAlwaysPage<<5,

	EKernelConfigCodePagingPolicyDefaultUnpaged	= EKernelConfigPagingPolicyDefaultUnpaged<<5,

	EKernelConfigCodePagingPolicyDefaultPaged	= EKernelConfigPagingPolicyDefaultPaged<<5,

	EKernelConfigPlatSecLocked = 1<<7,					// Primarily used by __PLATSEC_UNLOCKED__ (q.v.) test code

	EKernelConfigCrazyScheduling = 1<<8,				// Enables thread priority/timeslice craziness

	EKernelConfigDataPagingPolicyShift			= 9,

	EKernelConfigDataPagingPolicyMask			= 3<<9,

	EKernelConfigDataPagingPolicyNoPaging		= EKernelConfigPagingPolicyNoPaging<<9,

	EKernelConfigDataPagingPolicyAlwaysPage		= EKernelConfigPagingPolicyAlwaysPage<<9,

	EKernelConfigDataPagingPolicyDefaultUnpaged	= EKernelConfigPagingPolicyDefaultUnpaged<<9,

	EKernelConfigDataPagingPolicyDefaultPaged	= EKernelConfigPagingPolicyDefaultPaged<<9,

	EKernelConfigSMPUnsafeCompat = 1<<12,				// Enables compatibility mode for SMP-unsafe processes

	EKernelConfigSMPUnsafeCPU0   = 1<<13,				// Slow compatibility mode: all SMP-unsafe processes run on CPU 0 only

	EKernelConfigSMPCrazyInterrupts = 1<<14,			// Enables CPU target rotation for HW Interrupts.

	EKernelConfigDisableAPs = 1u<<30,

	EKernelConfigTest = 1u<<31,							// Only used by test code for __PLATSEC_UNLOCKED__

	};

/**

	If __PLATSEC_UNLOCKED__ is not defined, these flags must always

	be considered to be set.  See KernelConfigFlags() in kern_priv.h.

	@see KernelConfigFlags()

	@internalTechnology

*/

#ifdef __PLATSEC_UNLOCKED__

#define __PLATSEC_FORCED_FLAGS__	 0

#else

#define __PLATSEC_FORCED_FLAGS__	(EKernelConfigPlatSecEnforcement|EKernelConfigPlatSecProcessIsolation|EKernelConfigPlatSecEnforceSysBin)

#endif