GNU Linux-libre 4.4.284-gnu1

[releases.git] / arch / powerpc / kernel / misc_32.S

/*
 * This file contains miscellaneous low-level functions.
 *    Copyright (C) 1995-1996 Gary Thomas (gdt@linuxppc.org)
 *
 * Largely rewritten by Cort Dougan (cort@cs.nmt.edu)
 * and Paul Mackerras.
 *
 * kexec bits:
 * Copyright (C) 2002-2003 Eric Biederman  <ebiederm@xmission.com>
 * GameCube/ppc32 port Copyright (C) 2004 Albert Herranz
 * PPC44x port. Copyright (C) 2011,  IBM Corporation
 *              Author: Suzuki Poulose <suzuki@in.ibm.com>
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version
 * 2 of the License, or (at your option) any later version.
 *
 */

#include <linux/sys.h>
#include <asm/unistd.h>
#include <asm/errno.h>
#include <asm/reg.h>
#include <asm/page.h>
#include <asm/cache.h>
#include <asm/cputable.h>
#include <asm/mmu.h>
#include <asm/ppc_asm.h>
#include <asm/thread_info.h>
#include <asm/asm-offsets.h>
#include <asm/processor.h>
#include <asm/kexec.h>
#include <asm/bug.h>
#include <asm/ptrace.h>

        .text

/*
 * We store the saved ksp_limit in the unused part
 * of the STACK_FRAME_OVERHEAD
 */
_GLOBAL(call_do_softirq)
        mflr    r0
        stw     r0,4(r1)
        lwz     r10,THREAD+KSP_LIMIT(r2)
        addi    r11,r3,THREAD_INFO_GAP
        stwu    r1,THREAD_SIZE-STACK_FRAME_OVERHEAD(r3)
        mr      r1,r3
        stw     r10,8(r1)
        stw     r11,THREAD+KSP_LIMIT(r2)
        bl      __do_softirq
        lwz     r10,8(r1)
        lwz     r1,0(r1)
        lwz     r0,4(r1)
        stw     r10,THREAD+KSP_LIMIT(r2)
        mtlr    r0
        blr

/*
 * void call_do_irq(struct pt_regs *regs, struct thread_info *irqtp);
 */
_GLOBAL(call_do_irq)
        mflr    r0
        stw     r0,4(r1)
        lwz     r10,THREAD+KSP_LIMIT(r2)
        addi    r11,r4,THREAD_INFO_GAP
        stwu    r1,THREAD_SIZE-STACK_FRAME_OVERHEAD(r4)
        mr      r1,r4
        stw     r10,8(r1)
        stw     r11,THREAD+KSP_LIMIT(r2)
        bl      __do_irq
        lwz     r10,8(r1)
        lwz     r1,0(r1)
        lwz     r0,4(r1)
        stw     r10,THREAD+KSP_LIMIT(r2)
        mtlr    r0
        blr

/*
 * This returns the high 64 bits of the product of two 64-bit numbers.
 */
_GLOBAL(mulhdu)
        cmpwi   r6,0
        cmpwi   cr1,r3,0
        mr      r10,r4
        mulhwu  r4,r4,r5
        beq     1f
        mulhwu  r0,r10,r6
        mullw   r7,r10,r5
        addc    r7,r0,r7
        addze   r4,r4
1:      beqlr   cr1             /* all done if high part of A is 0 */
        mr      r10,r3
        mullw   r9,r3,r5
        mulhwu  r3,r3,r5
        beq     2f
        mullw   r0,r10,r6
        mulhwu  r8,r10,r6
        addc    r7,r0,r7
        adde    r4,r4,r8
        addze   r3,r3
2:      addc    r4,r4,r9
        addze   r3,r3
        blr

/*
 * sub_reloc_offset(x) returns x - reloc_offset().
 */
_GLOBAL(sub_reloc_offset)
        mflr    r0
        bl      1f
1:      mflr    r5
        lis     r4,1b@ha
        addi    r4,r4,1b@l
        subf    r5,r4,r5
        subf    r3,r5,r3
        mtlr    r0
        blr

/*
 * reloc_got2 runs through the .got2 section adding an offset
 * to each entry.
 */
_GLOBAL(reloc_got2)
        mflr    r11
        lis     r7,__got2_start@ha
        addi    r7,r7,__got2_start@l
        lis     r8,__got2_end@ha
        addi    r8,r8,__got2_end@l
        subf    r8,r7,r8
        srwi.   r8,r8,2
        beqlr
        mtctr   r8
        bl      1f
1:      mflr    r0
        lis     r4,1b@ha
        addi    r4,r4,1b@l
        subf    r0,r4,r0
        add     r7,r0,r7
2:      lwz     r0,0(r7)
        add     r0,r0,r3
        stw     r0,0(r7)
        addi    r7,r7,4
        bdnz    2b
        mtlr    r11
        blr

/*
 * call_setup_cpu - call the setup_cpu function for this cpu
 * r3 = data offset, r24 = cpu number
 *
 * Setup function is called with:
 *   r3 = data offset
 *   r4 = ptr to CPU spec (relocated)
 */
_GLOBAL(call_setup_cpu)
        addis   r4,r3,cur_cpu_spec@ha
        addi    r4,r4,cur_cpu_spec@l
        lwz     r4,0(r4)
        add     r4,r4,r3
        lwz     r5,CPU_SPEC_SETUP(r4)
        cmpwi   0,r5,0
        add     r5,r5,r3
        beqlr
        mtctr   r5
        bctr

#if defined(CONFIG_CPU_FREQ_PMAC) && defined(CONFIG_6xx)

/* This gets called by via-pmu.c to switch the PLL selection
 * on 750fx CPU. This function should really be moved to some
 * other place (as most of the cpufreq code in via-pmu
 */
_GLOBAL(low_choose_750fx_pll)
        /* Clear MSR:EE */
        mfmsr   r7
        rlwinm  r0,r7,0,17,15
        mtmsr   r0

        /* If switching to PLL1, disable HID0:BTIC */
        cmplwi  cr0,r3,0
        beq     1f
        mfspr   r5,SPRN_HID0
        rlwinm  r5,r5,0,27,25
        sync
        mtspr   SPRN_HID0,r5
        isync
        sync

1:
        /* Calc new HID1 value */
        mfspr   r4,SPRN_HID1    /* Build a HID1:PS bit from parameter */
        rlwinm  r5,r3,16,15,15  /* Clear out HID1:PS from value read */
        rlwinm  r4,r4,0,16,14   /* Could have I used rlwimi here ? */
        or      r4,r4,r5
        mtspr   SPRN_HID1,r4

        /* Store new HID1 image */
        CURRENT_THREAD_INFO(r6, r1)
        lwz     r6,TI_CPU(r6)
        slwi    r6,r6,2
        addis   r6,r6,nap_save_hid1@ha
        stw     r4,nap_save_hid1@l(r6)

        /* If switching to PLL0, enable HID0:BTIC */
        cmplwi  cr0,r3,0
        bne     1f
        mfspr   r5,SPRN_HID0
        ori     r5,r5,HID0_BTIC
        sync
        mtspr   SPRN_HID0,r5
        isync
        sync

1:
        /* Return */
        mtmsr   r7
        blr

_GLOBAL(low_choose_7447a_dfs)
        /* Clear MSR:EE */
        mfmsr   r7
        rlwinm  r0,r7,0,17,15
        mtmsr   r0
        
        /* Calc new HID1 value */
        mfspr   r4,SPRN_HID1
        insrwi  r4,r3,1,9       /* insert parameter into bit 9 */
        sync
        mtspr   SPRN_HID1,r4
        sync
        isync

        /* Return */
        mtmsr   r7
        blr

#endif /* CONFIG_CPU_FREQ_PMAC && CONFIG_6xx */

/*
 * complement mask on the msr then "or" some values on.
 *     _nmask_and_or_msr(nmask, value_to_or)
 */
_GLOBAL(_nmask_and_or_msr)
        mfmsr   r0              /* Get current msr */
        andc    r0,r0,r3        /* And off the bits set in r3 (first parm) */
        or      r0,r0,r4        /* Or on the bits in r4 (second parm) */
        SYNC                    /* Some chip revs have problems here... */
        mtmsr   r0              /* Update machine state */
        isync
        blr                     /* Done */

#ifdef CONFIG_40x

/*
 * Do an IO access in real mode
 */
_GLOBAL(real_readb)
        mfmsr   r7
        ori     r0,r7,MSR_DR
        xori    r0,r0,MSR_DR
        sync
        mtmsr   r0
        sync
        isync
        lbz     r3,0(r3)
        sync
        mtmsr   r7
        sync
        isync
        blr

        /*
 * Do an IO access in real mode
 */
_GLOBAL(real_writeb)
        mfmsr   r7
        ori     r0,r7,MSR_DR
        xori    r0,r0,MSR_DR
        sync
        mtmsr   r0
        sync
        isync
        stb     r3,0(r4)
        sync
        mtmsr   r7
        sync
        isync
        blr

#endif /* CONFIG_40x */


/*
 * Flush instruction cache.
 * This is a no-op on the 601.
 */
_GLOBAL(flush_instruction_cache)
#if defined(CONFIG_8xx)
        isync
        lis     r5, IDC_INVALL@h
        mtspr   SPRN_IC_CST, r5
#elif defined(CONFIG_4xx)
#ifdef CONFIG_403GCX
        li      r3, 512
        mtctr   r3
        lis     r4, KERNELBASE@h
1:      iccci   0, r4
        addi    r4, r4, 16
        bdnz    1b
#else
        lis     r3, KERNELBASE@h
        iccci   0,r3
#endif
#elif defined(CONFIG_FSL_BOOKE)
BEGIN_FTR_SECTION
        mfspr   r3,SPRN_L1CSR0
        ori     r3,r3,L1CSR0_CFI|L1CSR0_CLFC
        /* msync; isync recommended here */
        mtspr   SPRN_L1CSR0,r3
        isync
        blr
END_FTR_SECTION_IFSET(CPU_FTR_UNIFIED_ID_CACHE)
        mfspr   r3,SPRN_L1CSR1
        ori     r3,r3,L1CSR1_ICFI|L1CSR1_ICLFR
        mtspr   SPRN_L1CSR1,r3
#else
        mfspr   r3,SPRN_PVR
        rlwinm  r3,r3,16,16,31
        cmpwi   0,r3,1
        beqlr                   /* for 601, do nothing */
        /* 603/604 processor - use invalidate-all bit in HID0 */
        mfspr   r3,SPRN_HID0
        ori     r3,r3,HID0_ICFI
        mtspr   SPRN_HID0,r3
#endif /* CONFIG_8xx/4xx */
        isync
        blr

/*
 * Write any modified data cache blocks out to memory
 * and invalidate the corresponding instruction cache blocks.
 * This is a no-op on the 601.
 *
 * flush_icache_range(unsigned long start, unsigned long stop)
 */
_KPROBE(flush_icache_range)
BEGIN_FTR_SECTION
        PURGE_PREFETCHED_INS
        blr                             /* for 601, do nothing */
END_FTR_SECTION_IFSET(CPU_FTR_COHERENT_ICACHE)
        li      r5,L1_CACHE_BYTES-1
        andc    r3,r3,r5
        subf    r4,r3,r4
        add     r4,r4,r5
        srwi.   r4,r4,L1_CACHE_SHIFT
        beqlr
        mtctr   r4
        mr      r6,r3
1:      dcbst   0,r3
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    1b
        sync                            /* wait for dcbst's to get to ram */
#ifndef CONFIG_44x
        mtctr   r4
2:      icbi    0,r6
        addi    r6,r6,L1_CACHE_BYTES
        bdnz    2b
#else
        /* Flash invalidate on 44x because we are passed kmapped addresses and
           this doesn't work for userspace pages due to the virtually tagged
           icache.  Sigh. */
        iccci   0, r0
#endif
        sync                            /* additional sync needed on g4 */
        isync
        blr
/*
 * Write any modified data cache blocks out to memory.
 * Does not invalidate the corresponding cache lines (especially for
 * any corresponding instruction cache).
 *
 * clean_dcache_range(unsigned long start, unsigned long stop)
 */
_GLOBAL(clean_dcache_range)
        li      r5,L1_CACHE_BYTES-1
        andc    r3,r3,r5
        subf    r4,r3,r4
        add     r4,r4,r5
        srwi.   r4,r4,L1_CACHE_SHIFT
        beqlr
        mtctr   r4

1:      dcbst   0,r3
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    1b
        sync                            /* wait for dcbst's to get to ram */
        blr

/*
 * Write any modified data cache blocks out to memory and invalidate them.
 * Does not invalidate the corresponding instruction cache blocks.
 *
 * flush_dcache_range(unsigned long start, unsigned long stop)
 */
_GLOBAL(flush_dcache_range)
        li      r5,L1_CACHE_BYTES-1
        andc    r3,r3,r5
        subf    r4,r3,r4
        add     r4,r4,r5
        srwi.   r4,r4,L1_CACHE_SHIFT
        beqlr
        mtctr   r4

1:      dcbf    0,r3
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    1b
        sync                            /* wait for dcbst's to get to ram */
        blr

/*
 * Like above, but invalidate the D-cache.  This is used by the 8xx
 * to invalidate the cache so the PPC core doesn't get stale data
 * from the CPM (no cache snooping here :-).
 *
 * invalidate_dcache_range(unsigned long start, unsigned long stop)
 */
_GLOBAL(invalidate_dcache_range)
        li      r5,L1_CACHE_BYTES-1
        andc    r3,r3,r5
        subf    r4,r3,r4
        add     r4,r4,r5
        srwi.   r4,r4,L1_CACHE_SHIFT
        beqlr
        mtctr   r4

1:      dcbi    0,r3
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    1b
        sync                            /* wait for dcbi's to get to ram */
        blr

/*
 * Flush a particular page from the data cache to RAM.
 * Note: this is necessary because the instruction cache does *not*
 * snoop from the data cache.
 * This is a no-op on the 601 which has a unified cache.
 *
 *      void __flush_dcache_icache(void *page)
 */
_GLOBAL(__flush_dcache_icache)
BEGIN_FTR_SECTION
        PURGE_PREFETCHED_INS
        blr
END_FTR_SECTION_IFSET(CPU_FTR_COHERENT_ICACHE)
        rlwinm  r3,r3,0,0,31-PAGE_SHIFT         /* Get page base address */
        li      r4,PAGE_SIZE/L1_CACHE_BYTES     /* Number of lines in a page */
        mtctr   r4
        mr      r6,r3
0:      dcbst   0,r3                            /* Write line to ram */
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    0b
        sync
#ifdef CONFIG_44x
        /* We don't flush the icache on 44x. Those have a virtual icache
         * and we don't have access to the virtual address here (it's
         * not the page vaddr but where it's mapped in user space). The
         * flushing of the icache on these is handled elsewhere, when
         * a change in the address space occurs, before returning to
         * user space
         */
BEGIN_MMU_FTR_SECTION
        blr
END_MMU_FTR_SECTION_IFSET(MMU_FTR_TYPE_44x)
#endif /* CONFIG_44x */
        mtctr   r4
1:      icbi    0,r6
        addi    r6,r6,L1_CACHE_BYTES
        bdnz    1b
        sync
        isync
        blr

#ifndef CONFIG_BOOKE
/*
 * Flush a particular page from the data cache to RAM, identified
 * by its physical address.  We turn off the MMU so we can just use
 * the physical address (this may be a highmem page without a kernel
 * mapping).
 *
 *      void __flush_dcache_icache_phys(unsigned long physaddr)
 */
_GLOBAL(__flush_dcache_icache_phys)
BEGIN_FTR_SECTION
        PURGE_PREFETCHED_INS
        blr                                     /* for 601, do nothing */
END_FTR_SECTION_IFSET(CPU_FTR_COHERENT_ICACHE)
        mfmsr   r10
        rlwinm  r0,r10,0,28,26                  /* clear DR */
        mtmsr   r0
        isync
        rlwinm  r3,r3,0,0,31-PAGE_SHIFT         /* Get page base address */
        li      r4,PAGE_SIZE/L1_CACHE_BYTES     /* Number of lines in a page */
        mtctr   r4
        mr      r6,r3
0:      dcbst   0,r3                            /* Write line to ram */
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    0b
        sync
        mtctr   r4
1:      icbi    0,r6
        addi    r6,r6,L1_CACHE_BYTES
        bdnz    1b
        sync
        mtmsr   r10                             /* restore DR */
        isync
        blr
#endif /* CONFIG_BOOKE */

/*
 * Clear pages using the dcbz instruction, which doesn't cause any
 * memory traffic (except to write out any cache lines which get
 * displaced).  This only works on cacheable memory.
 *
 * void clear_pages(void *page, int order) ;
 */
_GLOBAL(clear_pages)
        li      r0,PAGE_SIZE/L1_CACHE_BYTES
        slw     r0,r0,r4
        mtctr   r0
1:      dcbz    0,r3
        addi    r3,r3,L1_CACHE_BYTES
        bdnz    1b
        blr

/*
 * Copy a whole page.  We use the dcbz instruction on the destination
 * to reduce memory traffic (it eliminates the unnecessary reads of
 * the destination into cache).  This requires that the destination
 * is cacheable.
 */
#define COPY_16_BYTES           \
        lwz     r6,4(r4);       \
        lwz     r7,8(r4);       \
        lwz     r8,12(r4);      \
        lwzu    r9,16(r4);      \
        stw     r6,4(r3);       \
        stw     r7,8(r3);       \
        stw     r8,12(r3);      \
        stwu    r9,16(r3)

_GLOBAL(copy_page)
        addi    r3,r3,-4
        addi    r4,r4,-4

        li      r5,4

#if MAX_COPY_PREFETCH > 1
        li      r0,MAX_COPY_PREFETCH
        li      r11,4
        mtctr   r0
11:     dcbt    r11,r4
        addi    r11,r11,L1_CACHE_BYTES
        bdnz    11b
#else /* MAX_COPY_PREFETCH == 1 */
        dcbt    r5,r4
        li      r11,L1_CACHE_BYTES+4
#endif /* MAX_COPY_PREFETCH */
        li      r0,PAGE_SIZE/L1_CACHE_BYTES - MAX_COPY_PREFETCH
        crclr   4*cr0+eq
2:
        mtctr   r0
1:
        dcbt    r11,r4
        dcbz    r5,r3
        COPY_16_BYTES
#if L1_CACHE_BYTES >= 32
        COPY_16_BYTES
#if L1_CACHE_BYTES >= 64
        COPY_16_BYTES
        COPY_16_BYTES
#if L1_CACHE_BYTES >= 128
        COPY_16_BYTES
        COPY_16_BYTES
        COPY_16_BYTES
        COPY_16_BYTES
#endif
#endif
#endif
        bdnz    1b
        beqlr
        crnot   4*cr0+eq,4*cr0+eq
        li      r0,MAX_COPY_PREFETCH
        li      r11,4
        b       2b

/*
 * Extended precision shifts.
 *
 * Updated to be valid for shift counts from 0 to 63 inclusive.
 * -- Gabriel
 *
 * R3/R4 has 64 bit value
 * R5    has shift count
 * result in R3/R4
 *
 *  ashrdi3: arithmetic right shift (sign propagation)  
 *  lshrdi3: logical right shift
 *  ashldi3: left shift
 */
_GLOBAL(__ashrdi3)
        subfic  r6,r5,32
        srw     r4,r4,r5        # LSW = count > 31 ? 0 : LSW >> count
        addi    r7,r5,32        # could be xori, or addi with -32
        slw     r6,r3,r6        # t1 = count > 31 ? 0 : MSW << (32-count)
        rlwinm  r8,r7,0,32      # t3 = (count < 32) ? 32 : 0
        sraw    r7,r3,r7        # t2 = MSW >> (count-32)
        or      r4,r4,r6        # LSW |= t1
        slw     r7,r7,r8        # t2 = (count < 32) ? 0 : t2
        sraw    r3,r3,r5        # MSW = MSW >> count
        or      r4,r4,r7        # LSW |= t2
        blr

_GLOBAL(__ashldi3)
        subfic  r6,r5,32
        slw     r3,r3,r5        # MSW = count > 31 ? 0 : MSW << count
        addi    r7,r5,32        # could be xori, or addi with -32
        srw     r6,r4,r6        # t1 = count > 31 ? 0 : LSW >> (32-count)
        slw     r7,r4,r7        # t2 = count < 32 ? 0 : LSW << (count-32)
        or      r3,r3,r6        # MSW |= t1
        slw     r4,r4,r5        # LSW = LSW << count
        or      r3,r3,r7        # MSW |= t2
        blr

_GLOBAL(__lshrdi3)
        subfic  r6,r5,32
        srw     r4,r4,r5        # LSW = count > 31 ? 0 : LSW >> count
        addi    r7,r5,32        # could be xori, or addi with -32
        slw     r6,r3,r6        # t1 = count > 31 ? 0 : MSW << (32-count)
        srw     r7,r3,r7        # t2 = count < 32 ? 0 : MSW >> (count-32)
        or      r4,r4,r6        # LSW |= t1
        srw     r3,r3,r5        # MSW = MSW >> count
        or      r4,r4,r7        # LSW |= t2
        blr

/*
 * 64-bit comparison: __cmpdi2(s64 a, s64 b)
 * Returns 0 if a < b, 1 if a == b, 2 if a > b.
 */
_GLOBAL(__cmpdi2)
        cmpw    r3,r5
        li      r3,1
        bne     1f
        cmplw   r4,r6
        beqlr
1:      li      r3,0
        bltlr
        li      r3,2
        blr
/*
 * 64-bit comparison: __ucmpdi2(u64 a, u64 b)
 * Returns 0 if a < b, 1 if a == b, 2 if a > b.
 */
_GLOBAL(__ucmpdi2)
        cmplw   r3,r5
        li      r3,1
        bne     1f
        cmplw   r4,r6
        beqlr
1:      li      r3,0
        bltlr
        li      r3,2
        blr

_GLOBAL(__bswapdi2)
        rotlwi  r9,r4,8
        rotlwi  r10,r3,8
        rlwimi  r9,r4,24,0,7
        rlwimi  r10,r3,24,0,7
        rlwimi  r9,r4,24,16,23
        rlwimi  r10,r3,24,16,23
        mr      r3,r9
        mr      r4,r10
        blr

_GLOBAL(abs)
        srawi   r4,r3,31
        xor     r3,r3,r4
        sub     r3,r3,r4
        blr

#ifdef CONFIG_SMP
_GLOBAL(start_secondary_resume)
        /* Reset stack */
        CURRENT_THREAD_INFO(r1, r1)
        addi    r1,r1,THREAD_SIZE-STACK_FRAME_OVERHEAD
        li      r3,0
        stw     r3,0(r1)                /* Zero the stack frame pointer */
        bl      start_secondary
        b       .
#endif /* CONFIG_SMP */
        
/*
 * This routine is just here to keep GCC happy - sigh...
 */
_GLOBAL(__main)
        blr

#ifdef CONFIG_KEXEC
        /*
         * Must be relocatable PIC code callable as a C function.
         */
        .globl relocate_new_kernel
relocate_new_kernel:
        /* r3 = page_list   */
        /* r4 = reboot_code_buffer */
        /* r5 = start_address      */

#ifdef CONFIG_FSL_BOOKE

        mr      r29, r3
        mr      r30, r4
        mr      r31, r5

#define ENTRY_MAPPING_KEXEC_SETUP
#include "fsl_booke_entry_mapping.S"
#undef ENTRY_MAPPING_KEXEC_SETUP

        mr      r3, r29
        mr      r4, r30
        mr      r5, r31

        li      r0, 0
#elif defined(CONFIG_44x)

        /* Save our parameters */
        mr      r29, r3
        mr      r30, r4
        mr      r31, r5

#ifdef CONFIG_PPC_47x
        /* Check for 47x cores */
        mfspr   r3,SPRN_PVR
        srwi    r3,r3,16
        cmplwi  cr0,r3,PVR_476@h
        beq     setup_map_47x
        cmplwi  cr0,r3,PVR_476_ISS@h
        beq     setup_map_47x
#endif /* CONFIG_PPC_47x */
        
/*
 * Code for setting up 1:1 mapping for PPC440x for KEXEC
 *
 * We cannot switch off the MMU on PPC44x.
 * So we:
 * 1) Invalidate all the mappings except the one we are running from.
 * 2) Create a tmp mapping for our code in the other address space(TS) and
 *    jump to it. Invalidate the entry we started in.
 * 3) Create a 1:1 mapping for 0-2GiB in chunks of 256M in original TS.
 * 4) Jump to the 1:1 mapping in original TS.
 * 5) Invalidate the tmp mapping.
 *
 * - Based on the kexec support code for FSL BookE
 *
 */

        /* 
         * Load the PID with kernel PID (0).
         * Also load our MSR_IS and TID to MMUCR for TLB search.
         */
        li      r3, 0
        mtspr   SPRN_PID, r3
        mfmsr   r4
        andi.   r4,r4,MSR_IS@l
        beq     wmmucr
        oris    r3,r3,PPC44x_MMUCR_STS@h
wmmucr:
        mtspr   SPRN_MMUCR,r3
        sync

        /*
         * Invalidate all the TLB entries except the current entry
         * where we are running from
         */
        bl      0f                              /* Find our address */
0:      mflr    r5                              /* Make it accessible */
        tlbsx   r23,0,r5                        /* Find entry we are in */
        li      r4,0                            /* Start at TLB entry 0 */
        li      r3,0                            /* Set PAGEID inval value */
1:      cmpw    r23,r4                          /* Is this our entry? */
        beq     skip                            /* If so, skip the inval */
        tlbwe   r3,r4,PPC44x_TLB_PAGEID         /* If not, inval the entry */
skip:
        addi    r4,r4,1                         /* Increment */
        cmpwi   r4,64                           /* Are we done? */
        bne     1b                              /* If not, repeat */
        isync

        /* Create a temp mapping and jump to it */
        andi.   r6, r23, 1              /* Find the index to use */
        addi    r24, r6, 1              /* r24 will contain 1 or 2 */

        mfmsr   r9                      /* get the MSR */
        rlwinm  r5, r9, 27, 31, 31      /* Extract the MSR[IS] */
        xori    r7, r5, 1               /* Use the other address space */

        /* Read the current mapping entries */
        tlbre   r3, r23, PPC44x_TLB_PAGEID
        tlbre   r4, r23, PPC44x_TLB_XLAT
        tlbre   r5, r23, PPC44x_TLB_ATTRIB

        /* Save our current XLAT entry */
        mr      r25, r4

        /* Extract the TLB PageSize */
        li      r10, 1                  /* r10 will hold PageSize */
        rlwinm  r11, r3, 0, 24, 27      /* bits 24-27 */

        /* XXX: As of now we use 256M, 4K pages */
        cmpwi   r11, PPC44x_TLB_256M
        bne     tlb_4k
        rotlwi  r10, r10, 28            /* r10 = 256M */
        b       write_out
tlb_4k:
        cmpwi   r11, PPC44x_TLB_4K
        bne     default
        rotlwi  r10, r10, 12            /* r10 = 4K */
        b       write_out
default:
        rotlwi  r10, r10, 10            /* r10 = 1K */

write_out:
        /*
         * Write out the tmp 1:1 mapping for this code in other address space
         * Fixup  EPN = RPN , TS=other address space
         */
        insrwi  r3, r7, 1, 23           /* Bit 23 is TS for PAGEID field */

        /* Write out the tmp mapping entries */
        tlbwe   r3, r24, PPC44x_TLB_PAGEID
        tlbwe   r4, r24, PPC44x_TLB_XLAT
        tlbwe   r5, r24, PPC44x_TLB_ATTRIB

        subi    r11, r10, 1             /* PageOffset Mask = PageSize - 1 */
        not     r10, r11                /* Mask for PageNum */

        /* Switch to other address space in MSR */
        insrwi  r9, r7, 1, 26           /* Set MSR[IS] = r7 */

        bl      1f
1:      mflr    r8
        addi    r8, r8, (2f-1b)         /* Find the target offset */

        /* Jump to the tmp mapping */
        mtspr   SPRN_SRR0, r8
        mtspr   SPRN_SRR1, r9
        rfi

2:
        /* Invalidate the entry we were executing from */
        li      r3, 0
        tlbwe   r3, r23, PPC44x_TLB_PAGEID

        /* attribute fields. rwx for SUPERVISOR mode */
        li      r5, 0
        ori     r5, r5, (PPC44x_TLB_SW | PPC44x_TLB_SR | PPC44x_TLB_SX | PPC44x_TLB_G)

        /* Create 1:1 mapping in 256M pages */
        xori    r7, r7, 1                       /* Revert back to Original TS */

        li      r8, 0                           /* PageNumber */
        li      r6, 3                           /* TLB Index, start at 3  */

next_tlb:
        rotlwi  r3, r8, 28                      /* Create EPN (bits 0-3) */
        mr      r4, r3                          /* RPN = EPN  */
        ori     r3, r3, (PPC44x_TLB_VALID | PPC44x_TLB_256M) /* SIZE = 256M, Valid */
        insrwi  r3, r7, 1, 23                   /* Set TS from r7 */

        tlbwe   r3, r6, PPC44x_TLB_PAGEID       /* PageID field : EPN, V, SIZE */
        tlbwe   r4, r6, PPC44x_TLB_XLAT         /* Address translation : RPN   */
        tlbwe   r5, r6, PPC44x_TLB_ATTRIB       /* Attributes */

        addi    r8, r8, 1                       /* Increment PN */
        addi    r6, r6, 1                       /* Increment TLB Index */
        cmpwi   r8, 8                           /* Are we done ? */
        bne     next_tlb
        isync

        /* Jump to the new mapping 1:1 */
        li      r9,0
        insrwi  r9, r7, 1, 26                   /* Set MSR[IS] = r7 */

        bl      1f
1:      mflr    r8
        and     r8, r8, r11                     /* Get our offset within page */
        addi    r8, r8, (2f-1b)

        and     r5, r25, r10                    /* Get our target PageNum */
        or      r8, r8, r5                      /* Target jump address */

        mtspr   SPRN_SRR0, r8
        mtspr   SPRN_SRR1, r9
        rfi
2:
        /* Invalidate the tmp entry we used */
        li      r3, 0
        tlbwe   r3, r24, PPC44x_TLB_PAGEID
        sync
        b       ppc44x_map_done

#ifdef CONFIG_PPC_47x

        /* 1:1 mapping for 47x */

setup_map_47x:

        /*
         * Load the kernel pid (0) to PID and also to MMUCR[TID].
         * Also set the MSR IS->MMUCR STS
         */
        li      r3, 0
        mtspr   SPRN_PID, r3                    /* Set PID */
        mfmsr   r4                              /* Get MSR */
        andi.   r4, r4, MSR_IS@l                /* TS=1? */
        beq     1f                              /* If not, leave STS=0 */
        oris    r3, r3, PPC47x_MMUCR_STS@h      /* Set STS=1 */
1:      mtspr   SPRN_MMUCR, r3                  /* Put MMUCR */
        sync

        /* Find the entry we are running from */
        bl      2f
2:      mflr    r23
        tlbsx   r23, 0, r23
        tlbre   r24, r23, 0                     /* TLB Word 0 */
        tlbre   r25, r23, 1                     /* TLB Word 1 */
        tlbre   r26, r23, 2                     /* TLB Word 2 */


        /*
         * Invalidates all the tlb entries by writing to 256 RPNs(r4)
         * of 4k page size in all  4 ways (0-3 in r3).
         * This would invalidate the entire UTLB including the one we are
         * running from. However the shadow TLB entries would help us 
         * to continue the execution, until we flush them (rfi/isync).
         */
        addis   r3, 0, 0x8000                   /* specify the way */
        addi    r4, 0, 0                        /* TLB Word0 = (EPN=0, VALID = 0) */
        addi    r5, 0, 0
        b       clear_utlb_entry

        /* Align the loop to speed things up. from head_44x.S */
        .align  6

clear_utlb_entry:

        tlbwe   r4, r3, 0
        tlbwe   r5, r3, 1
        tlbwe   r5, r3, 2
        addis   r3, r3, 0x2000                  /* Increment the way */
        cmpwi   r3, 0
        bne     clear_utlb_entry
        addis   r3, 0, 0x8000
        addis   r4, r4, 0x100                   /* Increment the EPN */
        cmpwi   r4, 0
        bne     clear_utlb_entry

        /* Create the entries in the other address space */
        mfmsr   r5
        rlwinm  r7, r5, 27, 31, 31              /* Get the TS (Bit 26) from MSR */
        xori    r7, r7, 1                       /* r7 = !TS */

        insrwi  r24, r7, 1, 21                  /* Change the TS in the saved TLB word 0 */

        /* 
         * write out the TLB entries for the tmp mapping
         * Use way '0' so that we could easily invalidate it later.
         */
        lis     r3, 0x8000                      /* Way '0' */ 

        tlbwe   r24, r3, 0
        tlbwe   r25, r3, 1
        tlbwe   r26, r3, 2

        /* Update the msr to the new TS */
        insrwi  r5, r7, 1, 26

        bl      1f
1:      mflr    r6
        addi    r6, r6, (2f-1b)

        mtspr   SPRN_SRR0, r6
        mtspr   SPRN_SRR1, r5
        rfi

        /* 
         * Now we are in the tmp address space.
         * Create a 1:1 mapping for 0-2GiB in the original TS.
         */
2:
        li      r3, 0
        li      r4, 0                           /* TLB Word 0 */
        li      r5, 0                           /* TLB Word 1 */
        li      r6, 0
        ori     r6, r6, PPC47x_TLB2_S_RWX       /* TLB word 2 */

        li      r8, 0                           /* PageIndex */

        xori    r7, r7, 1                       /* revert back to original TS */

write_utlb:
        rotlwi  r5, r8, 28                      /* RPN = PageIndex * 256M */
                                                /* ERPN = 0 as we don't use memory above 2G */

        mr      r4, r5                          /* EPN = RPN */
        ori     r4, r4, (PPC47x_TLB0_VALID | PPC47x_TLB0_256M)
        insrwi  r4, r7, 1, 21                   /* Insert the TS to Word 0 */

        tlbwe   r4, r3, 0                       /* Write out the entries */
        tlbwe   r5, r3, 1
        tlbwe   r6, r3, 2
        addi    r8, r8, 1
        cmpwi   r8, 8                           /* Have we completed ? */
        bne     write_utlb

        /* make sure we complete the TLB write up */
        isync

        /* 
         * Prepare to jump to the 1:1 mapping.
         * 1) Extract page size of the tmp mapping
         *    DSIZ = TLB_Word0[22:27]
         * 2) Calculate the physical address of the address
         *    to jump to.
         */
        rlwinm  r10, r24, 0, 22, 27

        cmpwi   r10, PPC47x_TLB0_4K
        bne     0f
        li      r10, 0x1000                     /* r10 = 4k */
        bl      1f

0:
        /* Defaults to 256M */
        lis     r10, 0x1000
        
        bl      1f
1:      mflr    r4
        addi    r4, r4, (2f-1b)                 /* virtual address  of 2f */

        subi    r11, r10, 1                     /* offsetmask = Pagesize - 1 */
        not     r10, r11                        /* Pagemask = ~(offsetmask) */

        and     r5, r25, r10                    /* Physical page */
        and     r6, r4, r11                     /* offset within the current page */

        or      r5, r5, r6                      /* Physical address for 2f */

        /* Switch the TS in MSR to the original one */
        mfmsr   r8
        insrwi  r8, r7, 1, 26

        mtspr   SPRN_SRR1, r8
        mtspr   SPRN_SRR0, r5
        rfi

2:
        /* Invalidate the tmp mapping */
        lis     r3, 0x8000                      /* Way '0' */

        clrrwi  r24, r24, 12                    /* Clear the valid bit */
        tlbwe   r24, r3, 0
        tlbwe   r25, r3, 1
        tlbwe   r26, r3, 2

        /* Make sure we complete the TLB write and flush the shadow TLB */
        isync

#endif

ppc44x_map_done:


        /* Restore the parameters */
        mr      r3, r29
        mr      r4, r30
        mr      r5, r31

        li      r0, 0
#else
        li      r0, 0

        /*
         * Set Machine Status Register to a known status,
         * switch the MMU off and jump to 1: in a single step.
         */

        mr      r8, r0
        ori     r8, r8, MSR_RI|MSR_ME
        mtspr   SPRN_SRR1, r8
        addi    r8, r4, 1f - relocate_new_kernel
        mtspr   SPRN_SRR0, r8
        sync
        rfi

1:
#endif
        /* from this point address translation is turned off */
        /* and interrupts are disabled */

        /* set a new stack at the bottom of our page... */
        /* (not really needed now) */
        addi    r1, r4, KEXEC_CONTROL_PAGE_SIZE - 8 /* for LR Save+Back Chain */
        stw     r0, 0(r1)

        /* Do the copies */
        li      r6, 0 /* checksum */
        mr      r0, r3
        b       1f

0:      /* top, read another word for the indirection page */
        lwzu    r0, 4(r3)

1:
        /* is it a destination page? (r8) */
        rlwinm. r7, r0, 0, 31, 31 /* IND_DESTINATION (1<<0) */
        beq     2f

        rlwinm  r8, r0, 0, 0, 19 /* clear kexec flags, page align */
        b       0b

2:      /* is it an indirection page? (r3) */
        rlwinm. r7, r0, 0, 30, 30 /* IND_INDIRECTION (1<<1) */
        beq     2f

        rlwinm  r3, r0, 0, 0, 19 /* clear kexec flags, page align */
        subi    r3, r3, 4
        b       0b

2:      /* are we done? */
        rlwinm. r7, r0, 0, 29, 29 /* IND_DONE (1<<2) */
        beq     2f
        b       3f

2:      /* is it a source page? (r9) */
        rlwinm. r7, r0, 0, 28, 28 /* IND_SOURCE (1<<3) */
        beq     0b

        rlwinm  r9, r0, 0, 0, 19 /* clear kexec flags, page align */

        li      r7, PAGE_SIZE / 4
        mtctr   r7
        subi    r9, r9, 4
        subi    r8, r8, 4
9:
        lwzu    r0, 4(r9)  /* do the copy */
        xor     r6, r6, r0
        stwu    r0, 4(r8)
        dcbst   0, r8
        sync
        icbi    0, r8
        bdnz    9b

        addi    r9, r9, 4
        addi    r8, r8, 4
        b       0b

3:

        /* To be certain of avoiding problems with self-modifying code
         * execute a serializing instruction here.
         */
        isync
        sync

        mfspr   r3, SPRN_PIR /* current core we are running on */
        mr      r4, r5 /* load physical address of chunk called */

        /* jump to the entry point, usually the setup routine */
        mtlr    r5
        blrl

1:      b       1b

relocate_new_kernel_end:

        .globl relocate_new_kernel_size
relocate_new_kernel_size:
        .long relocate_new_kernel_end - relocate_new_kernel
#endif