xnu-792.10.96.tar.gz

[apple/xnu.git] / osfmk / ppc / proc_reg.h

/*
 * Copyright (c) 2000-2004 Apple Computer, Inc. All rights reserved.
 *
 * @APPLE_LICENSE_HEADER_START@
 * 
 * The contents of this file constitute Original Code as defined in and
 * are subject to the Apple Public Source License Version 1.1 (the
 * "License").  You may not use this file except in compliance with the
 * License.  Please obtain a copy of the License at
 * http://www.apple.com/publicsource and read it before using this file.
 * 
 * This Original Code and all software distributed under the License are
 * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT.  Please see the
 * License for the specific language governing rights and limitations
 * under the License.
 * 
 * @APPLE_LICENSE_HEADER_END@
 */
/*
 * @OSF_COPYRIGHT@
 */

#ifndef _PPC_PROC_REG_H_
#define _PPC_PROC_REG_H_

#include <mach/boolean.h>

/* Define some useful masks that convert from bit numbers */

#if __PPC__
#ifdef __BIG_ENDIAN__
#ifndef ENDIAN_MASK
#define ENDIAN_MASK(val,size) (1 << ((size-1) - val))
#endif
#else
#error code not ported to little endian targets yet
#endif /* __BIG_ENDIAN__ */
#endif /* __PPC__ */

#define MASK32(PART)    ENDIAN_MASK(PART ## _BIT, 32)
#define MASK16(PART)    ENDIAN_MASK(PART ## _BIT, 16)
#define MASK8(PART)     ENDIAN_MASK(PART ## _BIT, 8)

#undef MASK
#define MASK(PART)      MASK32(PART)

#define BITS_PER_WORD   32
#define BITS_PER_WORD_POW2 5

/* Defines for decoding the MSR bits */

#define MSR_SF_BIT              0
#define MSR_HV_BIT              3
#define MSR_RES1_BIT    1
#define MSR_RES2_BIT    2
#define MSR_RES3_BIT    3
#define MSR_RES4_BIT    4
#define MSR_RES5_BIT    5
#define MSR_VEC_BIT             6
#define MSR_RES7_BIT    7
#define MSR_RES8_BIT    8
#define MSR_RES9_BIT    9
#define MSR_RES10_BIT   10
#define MSR_RES11_BIT   11
#define MSR_KEY_BIT     12      /* Key bit on 603e (not on 603) */
#define MSR_POW_BIT     13
#define MSR_TGPR_BIT    14      /* Temporary GPR mappings on 603/603e */
#define MSR_ILE_BIT     15
#define MSR_EE_BIT      16
#define MSR_PR_BIT      17
#define MSR_FP_BIT      18
#define MSR_ME_BIT      19
#define MSR_FE0_BIT     20
#define MSR_SE_BIT      21
#define MSR_BE_BIT      22
#define MSR_FE1_BIT     23
#define MSR_RES24_BIT   24      /* AL bit in power architectures */
#define MSR_IP_BIT      25
#define MSR_IR_BIT      26
#define MSR_DR_BIT      27
#define MSR_RES28_BIT   28
#define MSR_PM_BIT      29
#define MSR_RI_BIT      30
#define MSR_LE_BIT      31

/* MSR for kernel mode, interrupts disabled, running in virtual mode */
#define MSR_SUPERVISOR_INT_OFF (MASK(MSR_ME) | MASK(MSR_IR) | MASK(MSR_DR))  

/* MSR for above but with interrupts enabled */
#define MSR_SUPERVISOR_INT_ON (MSR_SUPERVISOR_INT_OFF | MASK(MSR_EE))

/* MSR for physical mode code */
#define MSR_VM_OFF     (MASK(MSR_ME))

/* MSR for physical instruction, virtual data */
#define MSR_PHYS_INST_VIRT_DATA     (MASK(MSR_ME) | MASK(MSR_IR))

/* MSR mask for user-exported bits - identify bits that must be set/reset */

/* SET - external exceptions, machine check, vm on, user-level privs */
#define MSR_EXPORT_MASK_SET     (MASK(MSR_EE)| MASK(MSR_ME)| \
                                 MASK(MSR_IR)|MASK(MSR_DR)|MASK(MSR_PR))

/* only the following bits may be changed by a task */
#define MSR_IMPORT_BITS (MASK(MSR_FE0)|MASK(MSR_SE)|MASK(MSR_BE)| \
                         MASK(MSR_FE1)| MASK(MSR_PM) | MASK(MSR_LE))

#define MSR_PREPARE_FOR_IMPORT(origmsr, newmsr) \
        ((origmsr & ~MSR_IMPORT_BITS) | (newmsr & MSR_IMPORT_BITS))

#define MSR_VEC_ON      (MASK(MSR_VEC))

#define USER_MODE(msr) (msr & MASK(MSR_PR) ? TRUE : FALSE)

/* seg reg values must be simple expressions so that assembler can cope */
#define SEG_REG_INVALID 0x0000
#define KERNEL_SEG_REG0_VALUE 0x20000000 /* T=0,Ks=0,Ku=1 PPC_SID_KERNEL=0*/

/* For SEG_REG_PROT we have T=0, Ks=0, Ku=1 */
#define SEG_REG_PROT    0x20000000   /* seg regs should have these bits set */

/* SR_COPYIN is used for copyin/copyout+remapping and must be
 * saved and restored in the thread context.
 */
/* SR_UNUSED_BY_KERN is unused by the kernel, and thus contains
 * the space ID of the currently interrupted user task immediately
 * after an exception and before interrupts are reenabled. It's used
 * purely for an assert.
 */

/* SR_KERNEL used for asserts... */

#define SR_COPYIN       sr14
#define SR_UNUSED_BY_KERN sr13
#define SR_KERNEL       sr0

#define SR_UNUSED_BY_KERN_NUM 13
#define SR_COPYIN_NAME  sr14
#define SR_COPYIN_NUM   14
#define BAT_INVALID 0


/* DSISR bits on data access exceptions */

#define DSISR_IO_BIT            0       /* NOT USED on 601 */
#define DSISR_HASH_BIT          1
#define DSISR_NOEX_BIT          3
#define DSISR_PROT_BIT          4
#define DSISR_IO_SPC_BIT        5
#define DSISR_WRITE_BIT         6
#define DSISR_WATCH_BIT         9
#define DSISR_EIO_BIT           11

#define dsiMiss                         0x40000000
#define dsiMissb                        1
#define dsiNoEx                         0x10000000
#define dsiProt                         0x08000000
#define dsiInvMode                      0x04000000
#define dsiStore                        0x02000000
#define dsiAC                           0x00400000
#define dsiSeg                          0x00200000
#define dsiValid                        0x5E600000
#define dsiLinkage                      0x00010000      /* Linkage mapping type - software flag */
#define dsiLinkageb                     15                      /* Linkage mapping type - software flag */
#define dsiSoftware                     0x0000FFFF

/* SRR1 bits on data/instruction translation exceptions */

#define SRR1_TRANS_HASH_BIT     1
#define SRR1_TRANS_IO_BIT       3
#define SRR1_TRANS_PROT_BIT     4
#define SRR1_TRANS_NO_PTE_BIT   10

/* SRR1 bits on program exceptions */

#define SRR1_PRG_FE_BIT         11
#define SRR1_PRG_ILL_INS_BIT    12
#define SRR1_PRG_PRV_INS_BIT    13
#define SRR1_PRG_TRAP_BIT       14

/*
 * Virtual to physical mapping macros/structures.
 * IMPORTANT NOTE: there is one mapping per HW page, not per MACH page.
 */

#define PTE1_WIMG_GUARD_BIT     28      /* Needed for assembler */
#define PTE1_REFERENCED_BIT     23      /* ditto */
#define PTE1_CHANGED_BIT        24
#define PTE0_HASH_ID_BIT        25

#define PTE_WIMG_CB_CACHED_COHERENT             0       /* cached, writeback, coherent (default) */
#define PTE_WIMG_CB_CACHED_COHERENT_GUARDED     1       /* cached, writeback, coherent, guarded */
#define PTE_WIMG_UNCACHED_COHERENT              2       /* uncached, coherentt */
#define PTE_WIMG_UNCACHED_COHERENT_GUARDED      3       /* uncached, coherent, guarded */

#define PTE_WIMG_DEFAULT        PTE_WIMG_CB_CACHED_COHERENT
#define PTE_WIMG_IO             PTE_WIMG_UNCACHED_COHERENT_GUARDED



#ifndef ASSEMBLER
#ifdef __GNUC__

/* Structures and types for machine registers */


/*
 * C-helper inline functions for accessing machine registers follow.
 */


/*
 * Various memory/IO synchronisation instructions
 */

        /*      Use eieio as a memory barrier to order stores.
         *      Useful for device control and PTE maintenance.
         */

#define eieio() \
        __asm__ volatile("eieio")

        /*      Use sync to ensure previous stores have completed.
                This is  required when manipulating locks and/or
                maintaining PTEs or other shared structures on SMP 
                machines.
        */

#define sync() \
        __asm__ volatile("sync")

        /*      Use isync to sychronize context; that is, the ensure
                no prefetching of instructions happen before the
                instruction.
        */

#define isync() \
        __asm__ volatile("isync")


/*
 * Access to various system registers
 */

extern unsigned int mflr(void);

extern __inline__ unsigned int mflr(void)
{
        unsigned int result;
        __asm__ volatile("mflr %0" : "=r" (result));
        return result;
}

extern unsigned int mfpvr(void);

extern __inline__ unsigned int mfpvr(void)
{
        unsigned int result;
        __asm__ ("mfpvr %0" : "=r" (result));
        return result;
}

/* mtmsr might need syncs etc around it, don't provide simple
 * inline macro
 */

extern unsigned int mfmsr(void);

extern __inline__ unsigned int mfmsr(void)
{
        unsigned int result;
        __asm__ volatile("mfmsr %0" : "=r" (result));
        return result;
}


extern unsigned int mfdar(void);

extern __inline__ unsigned int mfdar(void)
{
        unsigned int result;
        __asm__ volatile("mfdar %0" : "=r" (result));
        return result;
}

extern void mtdec(unsigned int val);

extern __inline__ void mtdec(unsigned int val)
{
        __asm__ volatile("mtdec %0" : : "r" (val));
        return;
}

extern void mttb(unsigned int val);

extern __inline__ void mttb(unsigned int val)
{
        __asm__ volatile("mtspr tbl, %0" : : "r" (val));
        return;
}

extern unsigned int mftb(void);

extern __inline__ unsigned int mftb(void)
{
        unsigned int result;
        __asm__ volatile("mftb %0" : "=r" (result));
        return result;
}

extern void mttbu(unsigned int val);

extern __inline__ void mttbu(unsigned int val)
{
        __asm__ volatile("mtspr tbu, %0" : : "r" (val));
        return;
}

extern unsigned int mftbu(void);

extern __inline__ unsigned int mftbu(void)
{
        unsigned int result;
        __asm__ volatile("mftbu %0" : "=r" (result));
        return result;
}

extern unsigned int mfl2cr(void);

extern __inline__ unsigned int mfl2cr(void)
{
  unsigned int result;
  __asm__ volatile("mfspr %0, l2cr" : "=r" (result));
  return result;
}

extern unsigned int cntlzw(unsigned int num);

extern __inline__ unsigned int cntlzw(unsigned int num)
{
  unsigned int result;
  __asm__ volatile("cntlzw %0, %1" : "=r" (result) : "r" (num));
  return result;
}


/* functions for doing byte reversed loads and stores */

extern unsigned int lwbrx(unsigned int addr);

extern __inline__ unsigned int lwbrx(unsigned int addr)
{
  unsigned int result;
  __asm__ volatile("lwbrx %0, 0, %1" : "=r" (result) : "r" (addr));
  return result;
}

extern void stwbrx(unsigned int data, unsigned int addr);

extern __inline__ void stwbrx(unsigned int data, unsigned int addr)
{
  __asm__ volatile("stwbrx %0, 0, %1" : : "r" (data), "r" (addr));
}

/* Performance Monitor Register access routines */
extern unsigned long   mfmmcr0(void);
extern void                    mtmmcr0(unsigned long);
extern unsigned long   mfmmcr1(void);
extern void                    mtmmcr1(unsigned long);
extern unsigned long   mfmmcr2(void);
extern void                    mtmmcr2(unsigned long);
extern unsigned long   mfpmc1(void);
extern void                    mtpmc1(unsigned long);
extern unsigned long   mfpmc2(void);
extern void                    mtpmc2(unsigned long);
extern unsigned long   mfpmc3(void);
extern void                    mtpmc3(unsigned long);
extern unsigned long   mfpmc4(void);
extern void                    mtpmc4(unsigned long);
extern unsigned long   mfsia(void);
extern unsigned long   mfsda(void);

/* macros since the argument n is a hard-coded constant */

#define mtsprg(n, reg)  __asm__ volatile("mtsprg  " # n ", %0" : : "r" (reg))
#define mfsprg(reg, n)  __asm__ volatile("mfsprg  %0, " # n : "=r" (reg))

#define mtspr(spr, val)  __asm__ volatile("mtspr  " # spr ", %0" : : "r" (val))
#define mfspr(reg, spr)  __asm__ volatile("mfspr  %0, " # spr : "=r" (reg))

#endif /* __GNUC__ */
#endif /* !ASSEMBLER */

#endif /* _PPC_PROC_REG_H_ */