TOMOYO Linux Cross Reference
Linux/arch/powerpc/mm/nohash/tlb_low_64e.S

   /* SPDX-License-Identifier: GPL-2.0-or-later */
   /*
    *  Low level TLB miss handlers for Book3E
    *
    *  Copyright (C) 2008-2009
    *      Ben. Herrenschmidt (benh@kernel.crashing.org), IBM Corp.
    */
   
   #include <linux/pgtable.h>
  #include <asm/processor.h>
  #include <asm/reg.h>
  #include <asm/page.h>
  #include <asm/mmu.h>
  #include <asm/ppc_asm.h>
  #include <asm/asm-offsets.h>
  #include <asm/cputable.h>
  #include <asm/exception-64e.h>
  #include <asm/ppc-opcode.h>
  #include <asm/kvm_asm.h>
  #include <asm/kvm_booke_hv_asm.h>
  #include <asm/feature-fixups.h>
  
  #define VPTE_PMD_SHIFT  (PTE_INDEX_SIZE)
  #define VPTE_PUD_SHIFT  (VPTE_PMD_SHIFT + PMD_INDEX_SIZE)
  #define VPTE_PGD_SHIFT  (VPTE_PUD_SHIFT + PUD_INDEX_SIZE)
  #define VPTE_INDEX_SIZE (VPTE_PGD_SHIFT + PGD_INDEX_SIZE)
  
  /**********************************************************************
   *                                                                    *
   * TLB miss handling for Book3E with a bolted linear mapping          *
   * No virtual page table, no nested TLB misses                        *
   *                                                                    *
   **********************************************************************/
  
  /*
   * Note that, unlike non-bolted handlers, TLB_EXFRAME is not
   * modified by the TLB miss handlers themselves, since the TLB miss
   * handler code will not itself cause a recursive TLB miss.
   *
   * TLB_EXFRAME will be modified when crit/mc/debug exceptions are
   * entered/exited.
   */
  .macro tlb_prolog_bolted intnum addr
          mtspr   SPRN_SPRG_GEN_SCRATCH,r12
          mfspr   r12,SPRN_SPRG_TLB_EXFRAME
          std     r13,EX_TLB_R13(r12)
          std     r10,EX_TLB_R10(r12)
          mfspr   r13,SPRN_SPRG_PACA
  
          mfcr    r10
          std     r11,EX_TLB_R11(r12)
  #ifdef CONFIG_KVM_BOOKE_HV
  BEGIN_FTR_SECTION
          mfspr   r11, SPRN_SRR1
  END_FTR_SECTION_IFSET(CPU_FTR_EMB_HV)
  #endif
          DO_KVM  \intnum, SPRN_SRR1
          std     r16,EX_TLB_R16(r12)
          mfspr   r16,\addr               /* get faulting address */
          std     r14,EX_TLB_R14(r12)
          ld      r14,PACAPGD(r13)
          std     r15,EX_TLB_R15(r12)
          std     r10,EX_TLB_CR(r12)
  START_BTB_FLUSH_SECTION
          mfspr r11, SPRN_SRR1
          andi. r10,r11,MSR_PR
          beq 1f
          BTB_FLUSH(r10)
  1:
  END_BTB_FLUSH_SECTION
          std     r7,EX_TLB_R7(r12)
  .endm
  
  .macro tlb_epilog_bolted
          ld      r14,EX_TLB_CR(r12)
          ld      r7,EX_TLB_R7(r12)
          ld      r10,EX_TLB_R10(r12)
          ld      r11,EX_TLB_R11(r12)
          ld      r13,EX_TLB_R13(r12)
          mtcr    r14
          ld      r14,EX_TLB_R14(r12)
          ld      r15,EX_TLB_R15(r12)
          ld      r16,EX_TLB_R16(r12)
          mfspr   r12,SPRN_SPRG_GEN_SCRATCH
  .endm
  
  /* Data TLB miss */
          START_EXCEPTION(data_tlb_miss_bolted)
          tlb_prolog_bolted BOOKE_INTERRUPT_DTLB_MISS SPRN_DEAR
  
          /* We need _PAGE_PRESENT and  _PAGE_ACCESSED set */
  
          /* We do the user/kernel test for the PID here along with the RW test
           */
          /* We pre-test some combination of permissions to avoid double
           * faults:
           *
           * We move the ESR:ST bit into the position of _PAGE_BAP_SW in the PTE
           * ESR_ST   is 0x00800000
          * _PAGE_BAP_SW is 0x00000010
          * So the shift is >> 19. This tests for supervisor writeability.
          * If the page happens to be supervisor writeable and not user
          * writeable, we will take a new fault later, but that should be
          * a rare enough case.
          *
          * We also move ESR_ST in _PAGE_DIRTY position
          * _PAGE_DIRTY is 0x00001000 so the shift is >> 11
          *
          * MAS1 is preset for all we need except for TID that needs to
          * be cleared for kernel translations
          */
 
         mfspr   r11,SPRN_ESR
 
         srdi    r15,r16,60              /* get region */
         rldicl. r10,r16,64-PGTABLE_EADDR_SIZE,PGTABLE_EADDR_SIZE+4
         bne-    dtlb_miss_fault_bolted  /* Bail if fault addr is invalid */
 
         rlwinm  r10,r11,32-19,27,27
         rlwimi  r10,r11,32-16,19,19
         cmpwi   r15,0                   /* user vs kernel check */
         ori     r10,r10,_PAGE_PRESENT
         oris    r11,r10,_PAGE_ACCESSED@h
 
         bne     tlb_miss_kernel_bolted
 
 tlb_miss_user_bolted:
 #ifdef CONFIG_PPC_KUAP
         mfspr   r10,SPRN_MAS1
         rlwinm. r10,r10,0,0x3fff0000
         beq-    tlb_miss_fault_bolted /* KUAP fault */
 #endif
 
 tlb_miss_common_bolted:
 /*
  * This is the guts of the TLB miss handler for bolted-linear.
  * We are entered with:
  *
  * r16 = faulting address
  * r15 = crap (free to use)
  * r14 = page table base
  * r13 = PACA
  * r11 = PTE permission mask
  * r10 = crap (free to use)
  */
         rldicl  r15,r16,64-PGDIR_SHIFT+3,64-PGD_INDEX_SIZE-3
         cmpldi  cr0,r14,0
         clrrdi  r15,r15,3
         beq     tlb_miss_fault_bolted   /* No PGDIR, bail */
 
         ldx     r14,r14,r15             /* grab pgd entry */
 
         rldicl  r15,r16,64-PUD_SHIFT+3,64-PUD_INDEX_SIZE-3
         clrrdi  r15,r15,3
         cmpdi   cr0,r14,0
         bge     tlb_miss_fault_bolted   /* Bad pgd entry or hugepage; bail */
         ldx     r14,r14,r15             /* grab pud entry */
 
         rldicl  r15,r16,64-PMD_SHIFT+3,64-PMD_INDEX_SIZE-3
         clrrdi  r15,r15,3
         cmpdi   cr0,r14,0
         bge     tlb_miss_fault_bolted
         ldx     r14,r14,r15             /* Grab pmd entry */
 
         rldicl  r15,r16,64-PAGE_SHIFT+3,64-PTE_INDEX_SIZE-3
         clrrdi  r15,r15,3
         cmpdi   cr0,r14,0
         bge     tlb_miss_fault_bolted
         ldx     r14,r14,r15             /* Grab PTE, normal (!huge) page */
 
         /* Check if required permissions are met */
         andc.   r15,r11,r14
         rldicr  r15,r14,64-(PTE_RPN_SHIFT-PAGE_SHIFT),63-PAGE_SHIFT
         bne-    tlb_miss_fault_bolted
 
         /* Now we build the MAS:
          *
          * MAS 0   :    Fully setup with defaults in MAS4 and TLBnCFG
          * MAS 1   :    Almost fully setup
          *               - PID already updated by caller if necessary
          *               - TSIZE need change if !base page size, not
          *                 yet implemented for now
          * MAS 2   :    Defaults not useful, need to be redone
          * MAS 3+7 :    Needs to be done
          */
         clrrdi  r11,r16,12              /* Clear low crap in EA */
         clrldi  r15,r15,12              /* Clear crap at the top */
         rlwimi  r11,r14,32-19,27,31     /* Insert WIMGE */
         rlwimi  r15,r14,32-8,22,25      /* Move in U bits */
         mtspr   SPRN_MAS2,r11
         andi.   r11,r14,_PAGE_DIRTY
         rlwimi  r15,r14,32-2,26,31      /* Move in BAP bits */
 
         /* Mask out SW and UW if !DIRTY (XXX optimize this !) */
         bne     1f
         li      r11,MAS3_SW|MAS3_UW
         andc    r15,r15,r11
 1:
         mtspr   SPRN_MAS7_MAS3,r15
         tlbwe
 
 tlb_miss_done_bolted:
         tlb_epilog_bolted
         rfi
 
 itlb_miss_kernel_bolted:
         li      r11,_PAGE_PRESENT|_PAGE_BAP_SX  /* Base perm */
         oris    r11,r11,_PAGE_ACCESSED@h
 tlb_miss_kernel_bolted:
         mfspr   r10,SPRN_MAS1
         ld      r14,PACA_KERNELPGD(r13)
         srdi    r15,r16,44              /* get kernel region */
         andi.   r15,r15,1               /* Check for vmalloc region */
         rlwinm  r10,r10,0,16,1          /* Clear TID */
         mtspr   SPRN_MAS1,r10
         bne+    tlb_miss_common_bolted
 
 tlb_miss_fault_bolted:
         /* We need to check if it was an instruction miss */
         andi.   r10,r11,_PAGE_BAP_UX|_PAGE_BAP_SX
         bne     itlb_miss_fault_bolted
 dtlb_miss_fault_bolted:
         tlb_epilog_bolted
         b       exc_data_storage_book3e
 itlb_miss_fault_bolted:
         tlb_epilog_bolted
         b       exc_instruction_storage_book3e
 
 /* Instruction TLB miss */
         START_EXCEPTION(instruction_tlb_miss_bolted)
         tlb_prolog_bolted BOOKE_INTERRUPT_ITLB_MISS SPRN_SRR0
 
         rldicl. r10,r16,64-PGTABLE_EADDR_SIZE,PGTABLE_EADDR_SIZE+4
         srdi    r15,r16,60              /* get region */
         bne-    itlb_miss_fault_bolted
 
         li      r11,_PAGE_PRESENT|_PAGE_BAP_UX  /* Base perm */
 
         /* We do the user/kernel test for the PID here along with the RW test
          */
 
         cmpldi  cr0,r15,0                       /* Check for user region */
         oris    r11,r11,_PAGE_ACCESSED@h
         beq     tlb_miss_user_bolted
         b       itlb_miss_kernel_bolted
 
 /*
  * TLB miss handling for e6500 and derivatives, using hardware tablewalk.
  *
  * Linear mapping is bolted: no virtual page table or nested TLB misses
  * Indirect entries in TLB1, hardware loads resulting direct entries
  *    into TLB0
  * No HES or NV hint on TLB1, so we need to do software round-robin
  * No tlbsrx. so we need a spinlock, and we have to deal
  *    with MAS-damage caused by tlbsx
  * 4K pages only
  */
 
         START_EXCEPTION(instruction_tlb_miss_e6500)
         tlb_prolog_bolted BOOKE_INTERRUPT_ITLB_MISS SPRN_SRR0
 
         ld      r11,PACA_TCD_PTR(r13)
         srdi.   r15,r16,60              /* get region */
         ori     r16,r16,1
 
         bne     tlb_miss_kernel_e6500   /* user/kernel test */
 
         b       tlb_miss_common_e6500
 
         START_EXCEPTION(data_tlb_miss_e6500)
         tlb_prolog_bolted BOOKE_INTERRUPT_DTLB_MISS SPRN_DEAR
 
         ld      r11,PACA_TCD_PTR(r13)
         srdi.   r15,r16,60              /* get region */
         rldicr  r16,r16,0,62
 
         bne     tlb_miss_kernel_e6500   /* user vs kernel check */
 
 /*
  * This is the guts of the TLB miss handler for e6500 and derivatives.
  * We are entered with:
  *
  * r16 = page of faulting address (low bit 0 if data, 1 if instruction)
  * r15 = crap (free to use)
  * r14 = page table base
  * r13 = PACA
  * r11 = tlb_per_core ptr
  * r10 = crap (free to use)
  * r7  = esel_next
  */
 tlb_miss_common_e6500:
         crmove  cr2*4+2,cr0*4+2         /* cr2.eq != 0 if kernel address */
 
 BEGIN_FTR_SECTION               /* CPU_FTR_SMT */
         /*
          * Search if we already have an indirect entry for that virtual
          * address, and if we do, bail out.
          *
          * MAS6:IND should be already set based on MAS4
          */
         lhz     r10,PACAPACAINDEX(r13)
         addi    r10,r10,1
         crclr   cr1*4+eq        /* set cr1.eq = 0 for non-recursive */
 1:      lbarx   r15,0,r11
         cmpdi   r15,0
         bne     2f
         stbcx.  r10,0,r11
         bne     1b
 3:
         .subsection 1
 2:      cmpd    cr1,r15,r10     /* recursive lock due to mcheck/crit/etc? */
         beq     cr1,3b          /* unlock will happen if cr1.eq = 0 */
 10:     lbz     r15,0(r11)
         cmpdi   r15,0
         bne     10b
         b       1b
         .previous
 END_FTR_SECTION_IFSET(CPU_FTR_SMT)
 
         lbz     r7,TCD_ESEL_NEXT(r11)
 
 BEGIN_FTR_SECTION               /* CPU_FTR_SMT */
         /*
          * Erratum A-008139 says that we can't use tlbwe to change
          * an indirect entry in any way (including replacing or
          * invalidating) if the other thread could be in the process
          * of a lookup.  The workaround is to invalidate the entry
          * with tlbilx before overwriting.
          */
 
         rlwinm  r10,r7,16,0xff0000
         oris    r10,r10,MAS0_TLBSEL(1)@h
         mtspr   SPRN_MAS0,r10
         isync
         tlbre
         mfspr   r15,SPRN_MAS1
         andis.  r15,r15,MAS1_VALID@h
         beq     5f
 
 BEGIN_FTR_SECTION_NESTED(532)
         mfspr   r10,SPRN_MAS8
         rlwinm  r10,r10,0,0x80000fff  /* tgs,tlpid -> sgs,slpid */
         mtspr   SPRN_MAS5,r10
 END_FTR_SECTION_NESTED(CPU_FTR_EMB_HV,CPU_FTR_EMB_HV,532)
 
         mfspr   r10,SPRN_MAS1
         rlwinm  r15,r10,0,0x3fff0000  /* tid -> spid */
         rlwimi  r15,r10,20,0x00000003 /* ind,ts -> sind,sas */
         mfspr   r10,SPRN_MAS6
         mtspr   SPRN_MAS6,r15
 
         mfspr   r15,SPRN_MAS2
         isync
         PPC_TLBILX_VA(0,R15)
         isync
 
         mtspr   SPRN_MAS6,r10
 
 5:
 BEGIN_FTR_SECTION_NESTED(532)
         li      r10,0
         mtspr   SPRN_MAS8,r10
         mtspr   SPRN_MAS5,r10
 END_FTR_SECTION_NESTED(CPU_FTR_EMB_HV,CPU_FTR_EMB_HV,532)
 
         tlbsx   0,r16
         mfspr   r10,SPRN_MAS1
         andis.  r15,r10,MAS1_VALID@h
         bne     tlb_miss_done_e6500
 FTR_SECTION_ELSE
         mfspr   r10,SPRN_MAS1
 ALT_FTR_SECTION_END_IFSET(CPU_FTR_SMT)
 
         oris    r10,r10,MAS1_VALID@h
         beq     cr2,4f
         rlwinm  r10,r10,0,16,1          /* Clear TID */
 4:      mtspr   SPRN_MAS1,r10
 
         /* Now, we need to walk the page tables. First check if we are in
          * range.
          */
         rldicl. r10,r16,64-PGTABLE_EADDR_SIZE,PGTABLE_EADDR_SIZE+4
         bne-    tlb_miss_fault_e6500
 
         rldicl  r15,r16,64-PGDIR_SHIFT+3,64-PGD_INDEX_SIZE-3
         cmpldi  cr0,r14,0
         clrrdi  r15,r15,3
         beq-    tlb_miss_fault_e6500 /* No PGDIR, bail */
         ldx     r14,r14,r15             /* grab pgd entry */
 
         rldicl  r15,r16,64-PUD_SHIFT+3,64-PUD_INDEX_SIZE-3
         clrrdi  r15,r15,3
         cmpdi   cr0,r14,0
         bge     tlb_miss_huge_e6500     /* Bad pgd entry or hugepage; bail */
         ldx     r14,r14,r15             /* grab pud entry */
 
         rldicl  r15,r16,64-PMD_SHIFT+3,64-PMD_INDEX_SIZE-3
         clrrdi  r15,r15,3
         cmpdi   cr0,r14,0
         bge     tlb_miss_huge_e6500
         ldx     r14,r14,r15             /* Grab pmd entry */
 
         mfspr   r10,SPRN_MAS0
         cmpdi   cr0,r14,0
         bge     tlb_miss_huge_e6500
 
         /* Now we build the MAS for a 2M indirect page:
          *
          * MAS 0   :    ESEL needs to be filled by software round-robin
          * MAS 1   :    Fully set up
          *               - PID already updated by caller if necessary
          *               - TSIZE for now is base ind page size always
          *               - TID already cleared if necessary
          * MAS 2   :    Default not 2M-aligned, need to be redone
          * MAS 3+7 :    Needs to be done
          */
 
         ori     r14,r14,(BOOK3E_PAGESZ_4K << MAS3_SPSIZE_SHIFT)
         mtspr   SPRN_MAS7_MAS3,r14
 
         clrrdi  r15,r16,21              /* make EA 2M-aligned */
         mtspr   SPRN_MAS2,r15
 
 tlb_miss_huge_done_e6500:
         lbz     r16,TCD_ESEL_MAX(r11)
         lbz     r14,TCD_ESEL_FIRST(r11)
         rlwimi  r10,r7,16,0x00ff0000    /* insert esel_next into MAS0 */
         addi    r7,r7,1                 /* increment esel_next */
         mtspr   SPRN_MAS0,r10
         cmpw    r7,r16
         iseleq  r7,r14,r7               /* if next == last use first */
         stb     r7,TCD_ESEL_NEXT(r11)
 
         tlbwe
 
 tlb_miss_done_e6500:
         .macro  tlb_unlock_e6500
 BEGIN_FTR_SECTION
         beq     cr1,1f          /* no unlock if lock was recursively grabbed */
         li      r15,0
         isync
         stb     r15,0(r11)
 1:
 END_FTR_SECTION_IFSET(CPU_FTR_SMT)
         .endm
 
         tlb_unlock_e6500
         tlb_epilog_bolted
         rfi
 
 tlb_miss_huge_e6500:
         beq     tlb_miss_fault_e6500
         rlwinm  r15,r14,32-_PAGE_PSIZE_SHIFT,0x1e
 
         /*
          * Now we build the MAS for a huge page.
          *
          * MAS 0   :    ESEL needs to be filled by software round-robin
          *               - can be handled by indirect code
          * MAS 1   :    Need to clear IND and set TSIZE
          * MAS 2,3+7:   Needs to be redone similar to non-tablewalk handler
          */
 
         mfspr   r10,SPRN_MAS1
         rlwinm  r10,r10,0,~MAS1_IND
         rlwimi  r10,r15,MAS1_TSIZE_SHIFT,MAS1_TSIZE_MASK
         mtspr   SPRN_MAS1,r10
 
         li      r10,-0x400
         sld     r15,r10,r15             /* Generate mask based on size */
         and     r10,r16,r15
         rldicr  r15,r14,64-(PTE_RPN_SHIFT-PAGE_SHIFT),63-PAGE_SHIFT
         rlwimi  r10,r14,32-19,27,31     /* Insert WIMGE */
         clrldi  r15,r15,PAGE_SHIFT      /* Clear crap at the top */
         rlwimi  r15,r14,32-8,22,25      /* Move in U bits */
         mtspr   SPRN_MAS2,r10
         andi.   r10,r14,_PAGE_DIRTY
         rlwimi  r15,r14,32-2,26,31      /* Move in BAP bits */
 
         /* Mask out SW and UW if !DIRTY (XXX optimize this !) */
         bne     1f
         li      r10,MAS3_SW|MAS3_UW
         andc    r15,r15,r10
 1:
         mtspr   SPRN_MAS7_MAS3,r15
 
         mfspr   r10,SPRN_MAS0
         b       tlb_miss_huge_done_e6500
 
 tlb_miss_kernel_e6500:
         ld      r14,PACA_KERNELPGD(r13)
         srdi    r15,r16,44              /* get kernel region */
         xoris   r15,r15,0xc             /* Check for vmalloc region */
         cmplwi  cr1,r15,1
         beq+    cr1,tlb_miss_common_e6500
 
 tlb_miss_fault_e6500:
         tlb_unlock_e6500
         /* We need to check if it was an instruction miss */
         andi.   r16,r16,1
         bne     itlb_miss_fault_e6500
 dtlb_miss_fault_e6500:
         tlb_epilog_bolted
         b       exc_data_storage_book3e
 itlb_miss_fault_e6500:
         tlb_epilog_bolted
         b       exc_instruction_storage_book3e
 
 /*
  * This is the guts of the second-level TLB miss handler for direct
  * misses. We are entered with:
  *
  * r16 = virtual page table faulting address
  * r15 = region (top 4 bits of address)
  * r14 = crap (free to use)
  * r13 = PACA
  * r12 = TLB exception frame in PACA
  * r11 = crap (free to use)
  * r10 = crap (free to use)
  *
  * Note that this should only ever be called as a second level handler
  * with the current scheme when using SW load.
  * That means we can always get the original fault DEAR at
  * EX_TLB_DEAR-EX_TLB_SIZE(r12)
  *
  * It can be re-entered by the linear mapping miss handler. However, to
  * avoid too much complication, it will restart the whole fault at level
  * 0 so we don't care too much about clobbers
  *
  * XXX That code was written back when we couldn't clobber r14. We can now,
  * so we could probably optimize things a bit
  */
 virt_page_table_tlb_miss:
         /* Are we hitting a kernel page table ? */
         srdi    r15,r16,60
         andi.   r10,r15,0x8
 
         /* The cool thing now is that r10 contains 0 for user and 8 for kernel,
          * and we happen to have the swapper_pg_dir at offset 8 from the user
          * pgdir in the PACA :-).
          */
         add     r11,r10,r13
 
         /* If kernel, we need to clear MAS1 TID */
         beq     1f
         /* XXX replace the RMW cycles with immediate loads + writes */
         mfspr   r10,SPRN_MAS1
         rlwinm  r10,r10,0,16,1                  /* Clear TID */
         mtspr   SPRN_MAS1,r10
 #ifdef CONFIG_PPC_KUAP
         b       2f
 1:
         mfspr   r10,SPRN_MAS1
         rlwinm. r10,r10,0,0x3fff0000
         beq-    virt_page_table_tlb_miss_fault /* KUAP fault */
 2:
 #else
 1:
 #endif
 
         /* Now, we need to walk the page tables. First check if we are in
          * range.
          */
         rldicl  r10,r16,64-(VPTE_INDEX_SIZE+3),VPTE_INDEX_SIZE+3+4
         cmpldi  r10,0x80
         bne-    virt_page_table_tlb_miss_fault
 
         /* Get the PGD pointer */
         ld      r15,PACAPGD(r11)
         cmpldi  cr0,r15,0
         beq-    virt_page_table_tlb_miss_fault
 
         /* Get to PGD entry */
         rldicl  r11,r16,64-VPTE_PGD_SHIFT,64-PGD_INDEX_SIZE-3
         clrrdi  r10,r11,3
         ldx     r15,r10,r15
         cmpdi   cr0,r15,0
         bge     virt_page_table_tlb_miss_fault
 
         /* Get to PUD entry */
         rldicl  r11,r16,64-VPTE_PUD_SHIFT,64-PUD_INDEX_SIZE-3
         clrrdi  r10,r11,3
         ldx     r15,r10,r15
         cmpdi   cr0,r15,0
         bge     virt_page_table_tlb_miss_fault
 
         /* Get to PMD entry */
         rldicl  r11,r16,64-VPTE_PMD_SHIFT,64-PMD_INDEX_SIZE-3
         clrrdi  r10,r11,3
         ldx     r15,r10,r15
         cmpdi   cr0,r15,0
         bge     virt_page_table_tlb_miss_fault
 
         /* Ok, we're all right, we can now create a kernel translation for
          * a 4K or 64K page from r16 -> r15.
          */
         /* Now we build the MAS:
          *
          * MAS 0   :    Fully setup with defaults in MAS4 and TLBnCFG
          * MAS 1   :    Almost fully setup
          *               - PID already updated by caller if necessary
          *               - TSIZE for now is base page size always
          * MAS 2   :    Use defaults
          * MAS 3+7 :    Needs to be done
          *
          * So we only do MAS 2 and 3 for now...
          */
         clrldi  r11,r15,4               /* remove region ID from RPN */
         ori     r10,r11,1               /* Or-in SR */
 
         srdi    r16,r10,32
         mtspr   SPRN_MAS3,r10
         mtspr   SPRN_MAS7,r16
 
         tlbwe
 
         /* Return to caller, normal case */
         TLB_MISS_EPILOG_SUCCESS
         rfi
 
 virt_page_table_tlb_miss_fault:
         /* If we fault here, things are a little bit tricky. We need to call
          * either data or instruction store fault, and we need to retrieve
          * the original fault address and ESR (for data).
          *
          * The thing is, we know that in normal circumstances, this is
          * always called as a second level tlb miss for SW load or as a first
          * level TLB miss for HW load, so we should be able to peek at the
          * relevant information in the first exception frame in the PACA.
          *
          * However, we do need to double check that, because we may just hit
          * a stray kernel pointer or a userland attack trying to hit those
          * areas. If that is the case, we do a data fault. (We can't get here
          * from an instruction tlb miss anyway).
          *
          * Note also that when going to a fault, we must unwind the previous
          * level as well. Since we are doing that, we don't need to clear or
          * restore the TLB reservation neither.
          */
         subf    r10,r13,r12
         cmpldi  cr0,r10,PACA_EXTLB+EX_TLB_SIZE
         bne-    virt_page_table_tlb_miss_whacko_fault
 
         /* We dig the original DEAR and ESR from slot 0 */
         ld      r15,EX_TLB_DEAR+PACA_EXTLB(r13)
         ld      r16,EX_TLB_ESR+PACA_EXTLB(r13)
 
         /* We check for the "special" ESR value for instruction faults */
         cmpdi   cr0,r16,-1
         beq     1f
         mtspr   SPRN_DEAR,r15
         mtspr   SPRN_ESR,r16
         TLB_MISS_EPILOG_ERROR
         b       exc_data_storage_book3e
 1:      TLB_MISS_EPILOG_ERROR
         b       exc_instruction_storage_book3e
 
 virt_page_table_tlb_miss_whacko_fault:
         /* The linear fault will restart everything so ESR and DEAR will
          * not have been clobbered, let's just fault with what we have
          */
         TLB_MISS_EPILOG_ERROR
         b       exc_data_storage_book3e
 
 /*
  * This is the guts of "any" level TLB miss handler for kernel linear
  * mapping misses. We are entered with:
  *
  *
  * r16 = faulting address
  * r15 = crap (free to use)
  * r14 = ESR (data) or -1 (instruction)
  * r13 = PACA
  * r12 = TLB exception frame in PACA
  * r11 = crap (free to use)
  * r10 = crap (free to use)
  *
  * In addition we know that we will not re-enter, so in theory, we could
  * use a simpler epilog not restoring SRR0/1 etc.. but we'll do that later.
  *
  * We also need to be careful about MAS registers here & TLB reservation,
  * as we know we'll have clobbered them if we interrupt the main TLB miss
  * handlers in which case we probably want to do a full restart at level
  * 0 rather than saving / restoring the MAS.
  *
  * Note: If we care about performance of that core, we can easily shuffle
  *       a few things around
  */
 tlb_load_linear:
         /* For now, we assume the linear mapping is contiguous and stops at
          * linear_map_top. We also assume the size is a multiple of 1G, thus
          * we only use 1G pages for now. That might have to be changed in a
          * final implementation, especially when dealing with hypervisors
          */
         __LOAD_PACA_TOC(r11)
         LOAD_REG_ADDR_ALTTOC(r11, r11, linear_map_top)
         ld      r10,0(r11)
         tovirt(10,10)
         cmpld   cr0,r16,r10
         bge     tlb_load_linear_fault
 
         /* MAS1 need whole new setup. */
         li      r15,(BOOK3E_PAGESZ_1GB<<MAS1_TSIZE_SHIFT)
         oris    r15,r15,MAS1_VALID@h    /* MAS1 needs V and TSIZE */
         mtspr   SPRN_MAS1,r15
 
         /* Already somebody there ? */
         PPC_TLBSRX_DOT(0,R16)
         beq     tlb_load_linear_done
 
         /* Now we build the remaining MAS. MAS0 and 2 should be fine
          * with their defaults, which leaves us with MAS 3 and 7. The
          * mapping is linear, so we just take the address, clear the
          * region bits, and or in the permission bits which are currently
          * hard wired
          */
         clrrdi  r10,r16,30              /* 1G page index */
         clrldi  r10,r10,4               /* clear region bits */
         ori     r10,r10,MAS3_SR|MAS3_SW|MAS3_SX
 
         srdi    r16,r10,32
         mtspr   SPRN_MAS3,r10
         mtspr   SPRN_MAS7,r16
 
         tlbwe
 
 tlb_load_linear_done:
         /* We use the "error" epilog for success as we do want to
          * restore to the initial faulting context, whatever it was.
          * We do that because we can't resume a fault within a TLB
          * miss handler, due to MAS and TLB reservation being clobbered.
          */
         TLB_MISS_EPILOG_ERROR
         rfi
 
 tlb_load_linear_fault:
         /* We keep the DEAR and ESR around, this shouldn't have happened */
         cmpdi   cr0,r14,-1
         beq     1f
         TLB_MISS_EPILOG_ERROR_SPECIAL
         b       exc_data_storage_book3e
 1:      TLB_MISS_EPILOG_ERROR_SPECIAL
         b       exc_instruction_storage_book3e

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