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/*- * Copyright (c) 1997 Berkeley Software Design, Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Berkeley Software Design Inc's name may not be used to endorse or * promote products derived from this software without specific prior * written permission. * * THIS SOFTWARE IS PROVIDED BY BERKELEY SOFTWARE DESIGN INC ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL BERKELEY SOFTWARE DESIGN INC BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * BSDI $Id: locore.s,v 1.36.2.15 1999/08/23 22:34:41 cp Exp $ */ /*- * Copyright (c) 2001 Jake Burkholder. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include <machine/asm.h> __FBSDID("$FreeBSD: release/9.1.0/sys/sparc64/sparc64/exception.S 230680 2012-01-28 23:33:50Z marius $"); #include "opt_compat.h" #include "opt_ddb.h" #include <machine/asi.h> #include <machine/asmacros.h> #include <machine/frame.h> #include <machine/fsr.h> #include <machine/intr_machdep.h> #include <machine/ktr.h> #include <machine/pcb.h> #include <machine/pstate.h> #include <machine/trap.h> #include <machine/tsb.h> #include <machine/tstate.h> #include <machine/utrap.h> #include <machine/wstate.h> #include "assym.s" #define TSB_ASI 0x0 #define TSB_KERNEL 0x0 #define TSB_KERNEL_MASK 0x0 #define TSB_KERNEL_PHYS 0x0 #define TSB_KERNEL_PHYS_END 0x0 #define TSB_QUAD_LDD 0x0 .register %g2,#ignore .register %g3,#ignore .register %g6,#ignore .register %g7,#ignore /* * Atomically set a bit in a TTE. */ #define TTE_SET_BIT(r1, r2, r3, bit, a, asi) \ add r1, TTE_DATA, r1 ; \ LD(x, a) [r1] asi, r2 ; \ 9: or r2, bit, r3 ; \ CAS(x, a) [r1] asi, r2, r3 ; \ cmp r2, r3 ; \ bne,pn %xcc, 9b ; \ mov r3, r2 #define TTE_SET_REF(r1, r2, r3, a, asi) TTE_SET_BIT(r1, r2, r3, TD_REF, a, asi) #define TTE_SET_W(r1, r2, r3, a, asi) TTE_SET_BIT(r1, r2, r3, TD_W, a, asi) /* * Macros for spilling and filling live windows. * * NOTE: These macros use exactly 16 instructions, and it is assumed that the * handler will not use more than 24 instructions total, to leave room for * resume vectors which occupy the last 8 instructions. */ #define SPILL(storer, base, size, asi) \ storer %l0, [base + (0 * size)] asi ; \ storer %l1, [base + (1 * size)] asi ; \ storer %l2, [base + (2 * size)] asi ; \ storer %l3, [base + (3 * size)] asi ; \ storer %l4, [base + (4 * size)] asi ; \ storer %l5, [base + (5 * size)] asi ; \ storer %l6, [base + (6 * size)] asi ; \ storer %l7, [base + (7 * size)] asi ; \ storer %i0, [base + (8 * size)] asi ; \ storer %i1, [base + (9 * size)] asi ; \ storer %i2, [base + (10 * size)] asi ; \ storer %i3, [base + (11 * size)] asi ; \ storer %i4, [base + (12 * size)] asi ; \ storer %i5, [base + (13 * size)] asi ; \ storer %i6, [base + (14 * size)] asi ; \ storer %i7, [base + (15 * size)] asi #define FILL(loader, base, size, asi) \ loader [base + (0 * size)] asi, %l0 ; \ loader [base + (1 * size)] asi, %l1 ; \ loader [base + (2 * size)] asi, %l2 ; \ loader [base + (3 * size)] asi, %l3 ; \ loader [base + (4 * size)] asi, %l4 ; \ loader [base + (5 * size)] asi, %l5 ; \ loader [base + (6 * size)] asi, %l6 ; \ loader [base + (7 * size)] asi, %l7 ; \ loader [base + (8 * size)] asi, %i0 ; \ loader [base + (9 * size)] asi, %i1 ; \ loader [base + (10 * size)] asi, %i2 ; \ loader [base + (11 * size)] asi, %i3 ; \ loader [base + (12 * size)] asi, %i4 ; \ loader [base + (13 * size)] asi, %i5 ; \ loader [base + (14 * size)] asi, %i6 ; \ loader [base + (15 * size)] asi, %i7 #define ERRATUM50(reg) mov reg, reg #define KSTACK_SLOP 1024 /* * Sanity check the kernel stack and bail out if it's wrong. * XXX: doesn't handle being on the panic stack. */ #define KSTACK_CHECK \ dec 16, ASP_REG ; \ stx %g1, [ASP_REG + 0] ; \ stx %g2, [ASP_REG + 8] ; \ add %sp, SPOFF, %g1 ; \ andcc %g1, (1 << PTR_SHIFT) - 1, %g0 ; \ bnz,a %xcc, tl1_kstack_fault ; \ inc 16, ASP_REG ; \ ldx [PCPU(CURTHREAD)], %g2 ; \ ldx [%g2 + TD_KSTACK], %g2 ; \ add %g2, KSTACK_SLOP, %g2 ; \ subcc %g1, %g2, %g1 ; \ ble,a %xcc, tl1_kstack_fault ; \ inc 16, ASP_REG ; \ set KSTACK_PAGES * PAGE_SIZE, %g2 ; \ cmp %g1, %g2 ; \ bgt,a %xcc, tl1_kstack_fault ; \ inc 16, ASP_REG ; \ ldx [ASP_REG + 8], %g2 ; \ ldx [ASP_REG + 0], %g1 ; \ inc 16, ASP_REG .globl tl_text_begin tl_text_begin: nop ENTRY(tl1_kstack_fault) rdpr %tl, %g1 1: cmp %g1, 2 be,a 2f nop #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl1_kstack_fault: tl=%#lx tpc=%#lx tnpc=%#lx" , %g2, %g3, %g4, 7, 8, 9) rdpr %tl, %g3 stx %g3, [%g2 + KTR_PARM1] rdpr %tpc, %g3 stx %g3, [%g2 + KTR_PARM1] rdpr %tnpc, %g3 stx %g3, [%g2 + KTR_PARM1] 9: #endif sub %g1, 1, %g1 wrpr %g1, 0, %tl ba,a %xcc, 1b nop 2: #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl1_kstack_fault: sp=%#lx ks=%#lx cr=%#lx cs=%#lx ow=%#lx ws=%#lx" , %g1, %g2, %g3, 7, 8, 9) add %sp, SPOFF, %g2 stx %g2, [%g1 + KTR_PARM1] ldx [PCPU(CURTHREAD)], %g2 ldx [%g2 + TD_KSTACK], %g2 stx %g2, [%g1 + KTR_PARM2] rdpr %canrestore, %g2 stx %g2, [%g1 + KTR_PARM3] rdpr %cansave, %g2 stx %g2, [%g1 + KTR_PARM4] rdpr %otherwin, %g2 stx %g2, [%g1 + KTR_PARM5] rdpr %wstate, %g2 stx %g2, [%g1 + KTR_PARM6] 9: #endif wrpr %g0, 0, %canrestore wrpr %g0, 6, %cansave wrpr %g0, 0, %otherwin wrpr %g0, WSTATE_KERNEL, %wstate sub ASP_REG, SPOFF + CCFSZ, %sp clr %fp set trap, %o2 ba %xcc, tl1_trap mov T_KSTACK_FAULT | T_KERNEL, %o0 END(tl1_kstack_fault) /* * Magic to resume from a spill or fill trap. If we get an alignment or an * MMU fault during a spill or a fill, this macro will detect the fault and * resume at a set instruction offset in the trap handler. * * To check if the previous trap was a spill/fill we convert the trapped pc * to a trap type and verify that it is in the range of spill/fill vectors. * The spill/fill vectors are types 0x80-0xff and 0x280-0x2ff, masking off the * tl bit allows us to detect both ranges with one test. * * This is: * 0x80 <= (((%tpc - %tba) >> 5) & ~0x200) < 0x100 * * To calculate the new pc we take advantage of the xor feature of wrpr. * Forcing all the low bits of the trapped pc on we can produce any offset * into the spill/fill vector. The size of a spill/fill trap vector is 0x80. * * 0x7f ^ 0x1f == 0x60 * 0x1f == (0x80 - 0x60) - 1 * * Which are the offset and xor value used to resume from alignment faults. */ /* * Determine if we have trapped inside of a spill/fill vector, and if so resume * at a fixed instruction offset in the trap vector. Must be called on * alternate globals. */ #define RESUME_SPILLFILL_MAGIC(stxa_g0_sfsr, xor) \ dec 16, ASP_REG ; \ stx %g1, [ASP_REG + 0] ; \ stx %g2, [ASP_REG + 8] ; \ rdpr %tpc, %g1 ; \ ERRATUM50(%g1) ; \ rdpr %tba, %g2 ; \ sub %g1, %g2, %g2 ; \ srlx %g2, 5, %g2 ; \ andn %g2, 0x200, %g2 ; \ cmp %g2, 0x80 ; \ blu,pt %xcc, 9f ; \ cmp %g2, 0x100 ; \ bgeu,pt %xcc, 9f ; \ or %g1, 0x7f, %g1 ; \ wrpr %g1, xor, %tnpc ; \ stxa_g0_sfsr ; \ ldx [ASP_REG + 8], %g2 ; \ ldx [ASP_REG + 0], %g1 ; \ inc 16, ASP_REG ; \ done ; \ 9: ldx [ASP_REG + 8], %g2 ; \ ldx [ASP_REG + 0], %g1 ; \ inc 16, ASP_REG /* * For certain faults we need to clear the SFSR MMU register before returning. */ #define RSF_CLR_SFSR \ wr %g0, ASI_DMMU, %asi ; \ stxa %g0, [%g0 + AA_DMMU_SFSR] %asi #define RSF_XOR(off) ((0x80 - off) - 1) /* * Instruction offsets in spill and fill trap handlers for handling certain * nested traps, and corresponding xor constants for wrpr. */ #define RSF_OFF_ALIGN 0x60 #define RSF_OFF_MMU 0x70 #define RESUME_SPILLFILL_ALIGN \ RESUME_SPILLFILL_MAGIC(RSF_CLR_SFSR, RSF_XOR(RSF_OFF_ALIGN)) #define RESUME_SPILLFILL_MMU \ RESUME_SPILLFILL_MAGIC(EMPTY, RSF_XOR(RSF_OFF_MMU)) #define RESUME_SPILLFILL_MMU_CLR_SFSR \ RESUME_SPILLFILL_MAGIC(RSF_CLR_SFSR, RSF_XOR(RSF_OFF_MMU)) /* * Constant to add to %tnpc when taking a fill trap just before returning to * user mode. */ #define RSF_FILL_INC tl0_ret_fill_end - tl0_ret_fill /* * Generate a T_SPILL or T_FILL trap if the window operation fails. */ #define RSF_TRAP(type) \ ba %xcc, tl0_sftrap ; \ mov type, %g2 ; \ .align 16 /* * Game over if the window operation fails. */ #define RSF_FATAL(type) \ ba %xcc, rsf_fatal ; \ mov type, %g2 ; \ .align 16 /* * Magic to resume from a failed fill a few instructions after the corrsponding * restore. This is used on return from the kernel to usermode. */ #define RSF_FILL_MAGIC \ rdpr %tnpc, %g1 ; \ add %g1, RSF_FILL_INC, %g1 ; \ wrpr %g1, 0, %tnpc ; \ done ; \ .align 16 /* * Spill to the pcb if a spill to the user stack in kernel mode fails. */ #define RSF_SPILL_TOPCB \ ba,a %xcc, tl1_spill_topcb ; \ nop ; \ .align 16 ENTRY(rsf_fatal) #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "rsf_fatal: bad window trap tt=%#lx type=%#lx" , %g1, %g3, %g4, 7, 8, 9) rdpr %tt, %g3 stx %g3, [%g1 + KTR_PARM1] stx %g2, [%g1 + KTR_PARM2] 9: #endif KSTACK_CHECK sir END(rsf_fatal) .data _ALIGN_DATA .globl intrnames, sintrnames intrnames: .space (IV_MAX + PIL_MAX) * (MAXCOMLEN + 1) sintrnames: .quad (IV_MAX + PIL_MAX) * (MAXCOMLEN + 1) .globl intrcnt, sintrcnt intrcnt: .space (IV_MAX + PIL_MAX) * 8 sintrcnt: .quad (IV_MAX + PIL_MAX) * 8 .text /* * Trap table and associated macros * * Due to its size a trap table is an inherently hard thing to represent in * code in a clean way. There are approximately 1024 vectors, of 8 or 32 * instructions each, many of which are identical. The way that this is * laid out is the instructions (8 or 32) for the actual trap vector appear * as an AS macro. In general this code branches to tl0_trap or tl1_trap, * but if not supporting code can be placed just after the definition of the * macro. The macros are then instantiated in a different section (.trap), * which is setup to be placed by the linker at the beginning of .text, and the * code around the macros is moved to the end of trap table. In this way the * code that must be sequential in memory can be split up, and located near * its supporting code so that it is easier to follow. */ /* * Clean window traps occur when %cleanwin is zero to ensure that data * is not leaked between address spaces in registers. */ .macro clean_window clr %o0 clr %o1 clr %o2 clr %o3 clr %o4 clr %o5 clr %o6 clr %o7 clr %l0 clr %l1 clr %l2 clr %l3 clr %l4 clr %l5 clr %l6 rdpr %cleanwin, %l7 inc %l7 wrpr %l7, 0, %cleanwin clr %l7 retry .align 128 .endm /* * Stack fixups for entry from user mode. We are still running on the * user stack, and with its live registers, so we must save soon. We * are on alternate globals so we do have some registers. Set the * transitional window state, and do the save. If this traps we * attempt to spill a window to the user stack. If this fails, we * spill the window to the pcb and continue. Spilling to the pcb * must not fail. * * NOTE: Must be called with alternate globals and clobbers %g1. */ .macro tl0_split rdpr %wstate, %g1 wrpr %g1, WSTATE_TRANSITION, %wstate save .endm .macro tl0_setup type tl0_split clr %o1 set trap, %o2 ba %xcc, tl0_utrap mov \type, %o0 .endm /* * Generic trap type. Call trap() with the specified type. */ .macro tl0_gen type tl0_setup \type .align 32 .endm /* * This is used to suck up the massive swaths of reserved trap types. * Generates count "reserved" trap vectors. */ .macro tl0_reserved count .rept \count tl0_gen T_RESERVED .endr .endm .macro tl1_split rdpr %wstate, %g1 wrpr %g1, WSTATE_NESTED, %wstate save %sp, -(CCFSZ + TF_SIZEOF), %sp .endm .macro tl1_setup type tl1_split clr %o1 set trap, %o2 ba %xcc, tl1_trap mov \type | T_KERNEL, %o0 .endm .macro tl1_gen type tl1_setup \type .align 32 .endm .macro tl1_reserved count .rept \count tl1_gen T_RESERVED .endr .endm .macro tl0_insn_excptn wrpr %g0, PSTATE_ALT, %pstate wr %g0, ASI_IMMU, %asi rdpr %tpc, %g3 ldxa [%g0 + AA_IMMU_SFSR] %asi, %g4 /* * XXX in theory, a store to AA_IMMU_SFSR must be immediately * followed by a DONE, FLUSH or RETRY for USIII. In practice, * this triggers a RED state exception though. */ stxa %g0, [%g0 + AA_IMMU_SFSR] %asi membar #Sync ba %xcc, tl0_sfsr_trap mov T_INSTRUCTION_EXCEPTION, %g2 .align 32 .endm .macro tl0_data_excptn wrpr %g0, PSTATE_ALT, %pstate wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_SFAR] %asi, %g3 ldxa [%g0 + AA_DMMU_SFSR] %asi, %g4 stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync ba %xcc, tl0_sfsr_trap mov T_DATA_EXCEPTION, %g2 .align 32 .endm .macro tl0_align wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_SFAR] %asi, %g3 ldxa [%g0 + AA_DMMU_SFSR] %asi, %g4 stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync ba %xcc, tl0_sfsr_trap mov T_MEM_ADDRESS_NOT_ALIGNED, %g2 .align 32 .endm ENTRY(tl0_sfsr_trap) tl0_split clr %o1 set trap, %o2 mov %g3, %o4 mov %g4, %o5 ba %xcc, tl0_utrap mov %g2, %o0 END(tl0_sfsr_trap) .macro tl0_intr level, mask tl0_split set \mask, %o1 ba %xcc, tl0_intr mov \level, %o0 .align 32 .endm #define INTR(level, traplvl) \ tl ## traplvl ## _intr level, 1 << level #define TICK(traplvl) \ tl ## traplvl ## _intr PIL_TICK, 0x10001 #define INTR_LEVEL(tl) \ INTR(1, tl) ; \ INTR(2, tl) ; \ INTR(3, tl) ; \ INTR(4, tl) ; \ INTR(5, tl) ; \ INTR(6, tl) ; \ INTR(7, tl) ; \ INTR(8, tl) ; \ INTR(9, tl) ; \ INTR(10, tl) ; \ INTR(11, tl) ; \ INTR(12, tl) ; \ INTR(13, tl) ; \ TICK(tl) ; \ INTR(15, tl) ; .macro tl0_intr_level INTR_LEVEL(0) .endm .macro intr_vector ldxa [%g0] ASI_INTR_RECEIVE, %g1 andcc %g1, IRSR_BUSY, %g0 bnz,a,pt %xcc, intr_vector nop ba,a,pt %xcc, intr_vector_stray nop .align 32 .endm .macro tl0_immu_miss /* * Load the context and the virtual page number from the tag access * register. We ignore the context. */ wr %g0, ASI_IMMU, %asi ldxa [%g0 + AA_IMMU_TAR] %asi, %g1 /* * Initialize the page size walker. */ mov TS_MIN, %g2 /* * Loop over all supported page sizes. */ /* * Compute the page shift for the page size we are currently looking * for. */ 1: add %g2, %g2, %g3 add %g3, %g2, %g3 add %g3, PAGE_SHIFT, %g3 /* * Extract the virtual page number from the contents of the tag * access register. */ srlx %g1, %g3, %g3 /* * Compute the TTE bucket address. */ ldxa [%g0 + AA_IMMU_TSB] %asi, %g5 and %g3, TSB_BUCKET_MASK, %g4 sllx %g4, TSB_BUCKET_SHIFT + TTE_SHIFT, %g4 add %g4, %g5, %g4 /* * Compute the TTE tag target. */ sllx %g3, TV_SIZE_BITS, %g3 or %g3, %g2, %g3 /* * Loop over the TTEs in this bucket. */ /* * Load the TTE. Note that this instruction may fault, clobbering * the contents of the tag access register, %g5, %g6, and %g7. We * do not use %g5, and %g6 and %g7 are not used until this instruction * completes successfully. */ 2: ldda [%g4] ASI_NUCLEUS_QUAD_LDD, %g6 /*, %g7 */ /* * Check that it's valid and executable and that the TTE tags match. */ brgez,pn %g7, 3f andcc %g7, TD_EXEC, %g0 bz,pn %xcc, 3f cmp %g3, %g6 bne,pn %xcc, 3f EMPTY /* * We matched a TTE, load the TLB. */ /* * Set the reference bit, if it's currently clear. */ andcc %g7, TD_REF, %g0 bz,a,pn %xcc, tl0_immu_miss_set_ref nop /* * Load the TTE tag and data into the TLB and retry the instruction. */ stxa %g1, [%g0 + AA_IMMU_TAR] %asi stxa %g7, [%g0] ASI_ITLB_DATA_IN_REG retry /* * Advance to the next TTE in this bucket, and check the low bits * of the bucket pointer to see if we've finished the bucket. */ 3: add %g4, 1 << TTE_SHIFT, %g4 andcc %g4, (1 << (TSB_BUCKET_SHIFT + TTE_SHIFT)) - 1, %g0 bnz,pt %xcc, 2b EMPTY /* * See if we just checked the largest page size, and advance to the * next one if not. */ cmp %g2, TS_MAX bne,pt %xcc, 1b add %g2, 1, %g2 /* * Not in user TSB, call C code. */ ba,a %xcc, tl0_immu_miss_trap .align 128 .endm ENTRY(tl0_immu_miss_set_ref) /* * Set the reference bit. */ TTE_SET_REF(%g4, %g2, %g3, a, ASI_N) /* * May have become invalid during casxa, in which case start over. */ brgez,pn %g2, 1f nop /* * Load the TTE tag and data into the TLB and retry the instruction. */ stxa %g1, [%g0 + AA_IMMU_TAR] %asi stxa %g2, [%g0] ASI_ITLB_DATA_IN_REG 1: retry END(tl0_immu_miss_set_ref) ENTRY(tl0_immu_miss_trap) /* * Put back the contents of the tag access register, in case we * faulted. */ sethi %hi(KERNBASE), %g2 stxa %g1, [%g0 + AA_IMMU_TAR] %asi flush %g2 /* * Switch to alternate globals. */ wrpr %g0, PSTATE_ALT, %pstate /* * Reload the tag access register. */ ldxa [%g0 + AA_IMMU_TAR] %asi, %g2 /* * Save the tag access register, and call common trap code. */ tl0_split clr %o1 set trap, %o2 mov %g2, %o3 ba %xcc, tl0_utrap mov T_INSTRUCTION_MISS, %o0 END(tl0_immu_miss_trap) .macro tl0_dmmu_miss /* * Load the context and the virtual page number from the tag access * register. We ignore the context. */ wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_TAR] %asi, %g1 /* * Initialize the page size walker. */ tl1_dmmu_miss_user: mov TS_MIN, %g2 /* * Loop over all supported page sizes. */ /* * Compute the page shift for the page size we are currently looking * for. */ 1: add %g2, %g2, %g3 add %g3, %g2, %g3 add %g3, PAGE_SHIFT, %g3 /* * Extract the virtual page number from the contents of the tag * access register. */ srlx %g1, %g3, %g3 /* * Compute the TTE bucket address. */ ldxa [%g0 + AA_DMMU_TSB] %asi, %g5 and %g3, TSB_BUCKET_MASK, %g4 sllx %g4, TSB_BUCKET_SHIFT + TTE_SHIFT, %g4 add %g4, %g5, %g4 /* * Compute the TTE tag target. */ sllx %g3, TV_SIZE_BITS, %g3 or %g3, %g2, %g3 /* * Loop over the TTEs in this bucket. */ /* * Load the TTE. Note that this instruction may fault, clobbering * the contents of the tag access register, %g5, %g6, and %g7. We * do not use %g5, and %g6 and %g7 are not used until this instruction * completes successfully. */ 2: ldda [%g4] ASI_NUCLEUS_QUAD_LDD, %g6 /*, %g7 */ /* * Check that it's valid and that the virtual page numbers match. */ brgez,pn %g7, 3f cmp %g3, %g6 bne,pn %xcc, 3f EMPTY /* * We matched a TTE, load the TLB. */ /* * Set the reference bit, if it's currently clear. */ andcc %g7, TD_REF, %g0 bz,a,pn %xcc, tl0_dmmu_miss_set_ref nop /* * Load the TTE tag and data into the TLB and retry the instruction. */ stxa %g1, [%g0 + AA_DMMU_TAR] %asi stxa %g7, [%g0] ASI_DTLB_DATA_IN_REG retry /* * Advance to the next TTE in this bucket, and check the low bits * of the bucket pointer to see if we've finished the bucket. */ 3: add %g4, 1 << TTE_SHIFT, %g4 andcc %g4, (1 << (TSB_BUCKET_SHIFT + TTE_SHIFT)) - 1, %g0 bnz,pt %xcc, 2b EMPTY /* * See if we just checked the largest page size, and advance to the * next one if not. */ cmp %g2, TS_MAX bne,pt %xcc, 1b add %g2, 1, %g2 /* * Not in user TSB, call C code. */ ba,a %xcc, tl0_dmmu_miss_trap .align 128 .endm ENTRY(tl0_dmmu_miss_set_ref) /* * Set the reference bit. */ TTE_SET_REF(%g4, %g2, %g3, a, ASI_N) /* * May have become invalid during casxa, in which case start over. */ brgez,pn %g2, 1f nop /* * Load the TTE tag and data into the TLB and retry the instruction. */ stxa %g1, [%g0 + AA_DMMU_TAR] %asi stxa %g2, [%g0] ASI_DTLB_DATA_IN_REG 1: retry END(tl0_dmmu_miss_set_ref) ENTRY(tl0_dmmu_miss_trap) /* * Put back the contents of the tag access register, in case we * faulted. */ stxa %g1, [%g0 + AA_DMMU_TAR] %asi membar #Sync /* * Switch to alternate globals. */ wrpr %g0, PSTATE_ALT, %pstate /* * Check if we actually came from the kernel. */ rdpr %tl, %g1 cmp %g1, 1 bgt,a,pn %xcc, 1f nop /* * Reload the tag access register. */ ldxa [%g0 + AA_DMMU_TAR] %asi, %g2 /* * Save the tag access register and call common trap code. */ tl0_split clr %o1 set trap, %o2 mov %g2, %o3 ba %xcc, tl0_utrap mov T_DATA_MISS, %o0 /* * Handle faults during window spill/fill. */ 1: RESUME_SPILLFILL_MMU /* * Reload the tag access register. */ ldxa [%g0 + AA_DMMU_TAR] %asi, %g2 tl1_split clr %o1 set trap, %o2 mov %g2, %o3 ba %xcc, tl1_trap mov T_DATA_MISS | T_KERNEL, %o0 END(tl0_dmmu_miss_trap) .macro tl0_dmmu_prot ba,a %xcc, tl0_dmmu_prot_1 nop .align 128 .endm ENTRY(tl0_dmmu_prot_1) /* * Load the context and the virtual page number from the tag access * register. We ignore the context. */ wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_TAR] %asi, %g1 /* * Initialize the page size walker. */ tl1_dmmu_prot_user: mov TS_MIN, %g2 /* * Loop over all supported page sizes. */ /* * Compute the page shift for the page size we are currently looking * for. */ 1: add %g2, %g2, %g3 add %g3, %g2, %g3 add %g3, PAGE_SHIFT, %g3 /* * Extract the virtual page number from the contents of the tag * access register. */ srlx %g1, %g3, %g3 /* * Compute the TTE bucket address. */ ldxa [%g0 + AA_DMMU_TSB] %asi, %g5 and %g3, TSB_BUCKET_MASK, %g4 sllx %g4, TSB_BUCKET_SHIFT + TTE_SHIFT, %g4 add %g4, %g5, %g4 /* * Compute the TTE tag target. */ sllx %g3, TV_SIZE_BITS, %g3 or %g3, %g2, %g3 /* * Loop over the TTEs in this bucket. */ /* * Load the TTE. Note that this instruction may fault, clobbering * the contents of the tag access register, %g5, %g6, and %g7. We * do not use %g5, and %g6 and %g7 are not used until this instruction * completes successfully. */ 2: ldda [%g4] ASI_NUCLEUS_QUAD_LDD, %g6 /*, %g7 */ /* * Check that it's valid and writable and that the virtual page * numbers match. */ brgez,pn %g7, 4f andcc %g7, TD_SW, %g0 bz,pn %xcc, 4f cmp %g3, %g6 bne,pn %xcc, 4f nop /* * Set the hardware write bit. */ TTE_SET_W(%g4, %g2, %g3, a, ASI_N) /* * Delete the old TLB entry and clear the SFSR. */ srlx %g1, PAGE_SHIFT, %g3 sllx %g3, PAGE_SHIFT, %g3 stxa %g0, [%g3] ASI_DMMU_DEMAP stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync /* * May have become invalid during casxa, in which case start over. */ brgez,pn %g2, 3f or %g2, TD_W, %g2 /* * Load the TTE data into the TLB and retry the instruction. */ stxa %g1, [%g0 + AA_DMMU_TAR] %asi stxa %g2, [%g0] ASI_DTLB_DATA_IN_REG 3: retry /* * Check the low bits to see if we've finished the bucket. */ 4: add %g4, 1 << TTE_SHIFT, %g4 andcc %g4, (1 << (TSB_BUCKET_SHIFT + TTE_SHIFT)) - 1, %g0 bnz,pt %xcc, 2b EMPTY /* * See if we just checked the largest page size, and advance to the * next one if not. */ cmp %g2, TS_MAX bne,pt %xcc, 1b add %g2, 1, %g2 /* * Not in user TSB, call C code. */ ba,a %xcc, tl0_dmmu_prot_trap nop END(tl0_dmmu_prot_1) ENTRY(tl0_dmmu_prot_trap) /* * Put back the contents of the tag access register, in case we * faulted. */ stxa %g1, [%g0 + AA_DMMU_TAR] %asi membar #Sync /* * Switch to alternate globals. */ wrpr %g0, PSTATE_ALT, %pstate /* * Check if we actually came from the kernel. */ rdpr %tl, %g1 cmp %g1, 1 bgt,a,pn %xcc, 1f nop /* * Load the SFAR, SFSR and TAR. */ ldxa [%g0 + AA_DMMU_TAR] %asi, %g2 ldxa [%g0 + AA_DMMU_SFAR] %asi, %g3 ldxa [%g0 + AA_DMMU_SFSR] %asi, %g4 stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync /* * Save the MMU registers and call common trap code. */ tl0_split clr %o1 set trap, %o2 mov %g2, %o3 mov %g3, %o4 mov %g4, %o5 ba %xcc, tl0_utrap mov T_DATA_PROTECTION, %o0 /* * Handle faults during window spill/fill. */ 1: RESUME_SPILLFILL_MMU_CLR_SFSR /* * Load the SFAR, SFSR and TAR. Clear the SFSR. */ ldxa [%g0 + AA_DMMU_TAR] %asi, %g2 ldxa [%g0 + AA_DMMU_SFAR] %asi, %g3 ldxa [%g0 + AA_DMMU_SFSR] %asi, %g4 stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync tl1_split clr %o1 set trap, %o2 mov %g2, %o3 mov %g3, %o4 mov %g4, %o5 ba %xcc, tl1_trap mov T_DATA_PROTECTION | T_KERNEL, %o0 END(tl0_dmmu_prot_trap) .macro tl0_spill_0_n wr %g0, ASI_AIUP, %asi SPILL(stxa, %sp + SPOFF, 8, %asi) saved retry .align 32 RSF_TRAP(T_SPILL) RSF_TRAP(T_SPILL) .endm .macro tl0_spill_1_n wr %g0, ASI_AIUP, %asi SPILL(stwa, %sp, 4, %asi) saved retry .align 32 RSF_TRAP(T_SPILL) RSF_TRAP(T_SPILL) .endm .macro tl0_fill_0_n wr %g0, ASI_AIUP, %asi FILL(ldxa, %sp + SPOFF, 8, %asi) restored retry .align 32 RSF_TRAP(T_FILL) RSF_TRAP(T_FILL) .endm .macro tl0_fill_1_n wr %g0, ASI_AIUP, %asi FILL(lduwa, %sp, 4, %asi) restored retry .align 32 RSF_TRAP(T_FILL) RSF_TRAP(T_FILL) .endm ENTRY(tl0_sftrap) rdpr %tstate, %g1 and %g1, TSTATE_CWP_MASK, %g1 wrpr %g1, 0, %cwp tl0_split clr %o1 set trap, %o2 ba %xcc, tl0_trap mov %g2, %o0 END(tl0_sftrap) .macro tl0_spill_bad count .rept \count sir .align 128 .endr .endm .macro tl0_fill_bad count .rept \count sir .align 128 .endr .endm .macro tl0_syscall tl0_split clr %o1 set syscall, %o2 ba %xcc, tl0_trap mov T_SYSCALL, %o0 .align 32 .endm .macro tl0_fp_restore ba,a %xcc, tl0_fp_restore nop .align 32 .endm ENTRY(tl0_fp_restore) ldx [PCB_REG + PCB_FLAGS], %g1 andn %g1, PCB_FEF, %g1 stx %g1, [PCB_REG + PCB_FLAGS] wr %g0, FPRS_FEF, %fprs wr %g0, ASI_BLK_S, %asi ldda [PCB_REG + PCB_UFP + (0 * 64)] %asi, %f0 ldda [PCB_REG + PCB_UFP + (1 * 64)] %asi, %f16 ldda [PCB_REG + PCB_UFP + (2 * 64)] %asi, %f32 ldda [PCB_REG + PCB_UFP + (3 * 64)] %asi, %f48 membar #Sync done END(tl0_fp_restore) .macro tl1_insn_excptn wrpr %g0, PSTATE_ALT, %pstate wr %g0, ASI_IMMU, %asi rdpr %tpc, %g3 ldxa [%g0 + AA_IMMU_SFSR] %asi, %g4 /* * XXX in theory, a store to AA_IMMU_SFSR must be immediately * followed by a DONE, FLUSH or RETRY for USIII. In practice, * this triggers a RED state exception though. */ stxa %g0, [%g0 + AA_IMMU_SFSR] %asi membar #Sync ba %xcc, tl1_insn_exceptn_trap mov T_INSTRUCTION_EXCEPTION | T_KERNEL, %g2 .align 32 .endm ENTRY(tl1_insn_exceptn_trap) tl1_split clr %o1 set trap, %o2 mov %g3, %o4 mov %g4, %o5 ba %xcc, tl1_trap mov %g2, %o0 END(tl1_insn_exceptn_trap) .macro tl1_fp_disabled ba,a %xcc, tl1_fp_disabled_1 nop .align 32 .endm ENTRY(tl1_fp_disabled_1) rdpr %tpc, %g1 set fpu_fault_begin, %g2 sub %g1, %g2, %g1 cmp %g1, fpu_fault_size bgeu,a,pn %xcc, 1f nop wr %g0, FPRS_FEF, %fprs wr %g0, ASI_BLK_S, %asi ldda [PCB_REG + PCB_KFP + (0 * 64)] %asi, %f0 ldda [PCB_REG + PCB_KFP + (1 * 64)] %asi, %f16 ldda [PCB_REG + PCB_KFP + (2 * 64)] %asi, %f32 ldda [PCB_REG + PCB_KFP + (3 * 64)] %asi, %f48 membar #Sync retry 1: tl1_split clr %o1 set trap, %o2 ba %xcc, tl1_trap mov T_FP_DISABLED | T_KERNEL, %o0 END(tl1_fp_disabled_1) .macro tl1_data_excptn wrpr %g0, PSTATE_ALT, %pstate ba,a %xcc, tl1_data_excptn_trap nop .align 32 .endm ENTRY(tl1_data_excptn_trap) RESUME_SPILLFILL_MMU_CLR_SFSR ba %xcc, tl1_sfsr_trap mov T_DATA_EXCEPTION | T_KERNEL, %g2 END(tl1_data_excptn_trap) .macro tl1_align wrpr %g0, PSTATE_ALT, %pstate ba,a %xcc, tl1_align_trap nop .align 32 .endm ENTRY(tl1_align_trap) RESUME_SPILLFILL_ALIGN ba %xcc, tl1_sfsr_trap mov T_MEM_ADDRESS_NOT_ALIGNED | T_KERNEL, %g2 END(tl1_align_trap) ENTRY(tl1_sfsr_trap) wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_SFAR] %asi, %g3 ldxa [%g0 + AA_DMMU_SFSR] %asi, %g4 stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync tl1_split clr %o1 set trap, %o2 mov %g3, %o4 mov %g4, %o5 ba %xcc, tl1_trap mov %g2, %o0 END(tl1_sfsr_trap) .macro tl1_intr level, mask tl1_split set \mask, %o1 ba %xcc, tl1_intr mov \level, %o0 .align 32 .endm .macro tl1_intr_level INTR_LEVEL(1) .endm .macro tl1_immu_miss /* * Load the context and the virtual page number from the tag access * register. We ignore the context. */ wr %g0, ASI_IMMU, %asi ldxa [%g0 + AA_IMMU_TAR] %asi, %g5 /* * Compute the address of the TTE. The TSB mask and address of the * TSB are patched at startup. */ .globl tl1_immu_miss_patch_tsb_1 tl1_immu_miss_patch_tsb_1: sethi %uhi(TSB_KERNEL), %g6 or %g6, %ulo(TSB_KERNEL), %g6 sllx %g6, 32, %g6 sethi %hi(TSB_KERNEL), %g7 or %g7, %g6, %g7 .globl tl1_immu_miss_patch_tsb_mask_1 tl1_immu_miss_patch_tsb_mask_1: sethi %hi(TSB_KERNEL_MASK), %g6 or %g6, %lo(TSB_KERNEL_MASK), %g6 srlx %g5, TAR_VPN_SHIFT, %g5 and %g5, %g6, %g6 sllx %g6, TTE_SHIFT, %g6 add %g6, %g7, %g6 /* * Load the TTE. */ .globl tl1_immu_miss_patch_quad_ldd_1 tl1_immu_miss_patch_quad_ldd_1: ldda [%g6] TSB_QUAD_LDD, %g6 /*, %g7 */ /* * Check that it's valid and executable and that the virtual page * numbers match. */ brgez,pn %g7, tl1_immu_miss_trap andcc %g7, TD_EXEC, %g0 bz,pn %xcc, tl1_immu_miss_trap srlx %g6, TV_SIZE_BITS, %g6 cmp %g5, %g6 bne,pn %xcc, tl1_immu_miss_trap EMPTY /* * Set the reference bit if it's currently clear. */ andcc %g7, TD_REF, %g0 bz,a,pn %xcc, tl1_immu_miss_set_ref nop /* * Load the TTE data into the TLB and retry the instruction. */ stxa %g7, [%g0] ASI_ITLB_DATA_IN_REG retry .align 128 .endm ENTRY(tl1_immu_miss_set_ref) /* * Recompute the TTE address, which we clobbered loading the TTE. * The TSB mask and address of the TSB are patched at startup. */ .globl tl1_immu_miss_patch_tsb_2 tl1_immu_miss_patch_tsb_2: sethi %uhi(TSB_KERNEL), %g6 or %g6, %ulo(TSB_KERNEL), %g6 sllx %g6, 32, %g6 sethi %hi(TSB_KERNEL), %g7 or %g7, %g6, %g7 .globl tl1_immu_miss_patch_tsb_mask_2 tl1_immu_miss_patch_tsb_mask_2: sethi %hi(TSB_KERNEL_MASK), %g6 or %g6, %lo(TSB_KERNEL_MASK), %g6 and %g5, %g6, %g5 sllx %g5, TTE_SHIFT, %g5 add %g5, %g7, %g5 /* * Set the reference bit. */ .globl tl1_immu_miss_patch_asi_1 tl1_immu_miss_patch_asi_1: wr %g0, TSB_ASI, %asi TTE_SET_REF(%g5, %g6, %g7, a, %asi) /* * May have become invalid during casxa, in which case start over. */ brgez,pn %g6, 1f nop /* * Load the TTE data into the TLB and retry the instruction. */ stxa %g6, [%g0] ASI_ITLB_DATA_IN_REG 1: retry END(tl1_immu_miss_set_ref) ENTRY(tl1_immu_miss_trap) /* * Switch to alternate globals. */ wrpr %g0, PSTATE_ALT, %pstate ldxa [%g0 + AA_IMMU_TAR] %asi, %g2 tl1_split clr %o1 set trap, %o2 mov %g2, %o3 ba %xcc, tl1_trap mov T_INSTRUCTION_MISS | T_KERNEL, %o0 END(tl1_immu_miss_trap) .macro tl1_dmmu_miss /* * Load the context and the virtual page number from the tag access * register. */ wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_TAR] %asi, %g5 /* * Extract the context from the contents of the tag access register. * If it's non-zero this is a fault on a user address. Note that the * faulting address is passed in %g1. */ sllx %g5, 64 - TAR_VPN_SHIFT, %g6 brnz,a,pn %g6, tl1_dmmu_miss_user mov %g5, %g1 /* * Check for the direct mapped physical region. These addresses have * the high bit set so they are negative. */ brlz,pn %g5, tl1_dmmu_miss_direct EMPTY /* * Compute the address of the TTE. The TSB mask and address of the * TSB are patched at startup. */ .globl tl1_dmmu_miss_patch_tsb_1 tl1_dmmu_miss_patch_tsb_1: sethi %uhi(TSB_KERNEL), %g6 or %g6, %ulo(TSB_KERNEL), %g6 sllx %g6, 32, %g6 sethi %hi(TSB_KERNEL), %g7 or %g7, %g6, %g7 .globl tl1_dmmu_miss_patch_tsb_mask_1 tl1_dmmu_miss_patch_tsb_mask_1: sethi %hi(TSB_KERNEL_MASK), %g6 or %g6, %lo(TSB_KERNEL_MASK), %g6 srlx %g5, TAR_VPN_SHIFT, %g5 and %g5, %g6, %g6 sllx %g6, TTE_SHIFT, %g6 add %g6, %g7, %g6 /* * Load the TTE. */ .globl tl1_dmmu_miss_patch_quad_ldd_1 tl1_dmmu_miss_patch_quad_ldd_1: ldda [%g6] TSB_QUAD_LDD, %g6 /*, %g7 */ /* * Check that it's valid and that the virtual page numbers match. */ brgez,pn %g7, tl1_dmmu_miss_trap srlx %g6, TV_SIZE_BITS, %g6 cmp %g5, %g6 bne,pn %xcc, tl1_dmmu_miss_trap EMPTY /* * Set the reference bit if it's currently clear. */ andcc %g7, TD_REF, %g0 bz,a,pt %xcc, tl1_dmmu_miss_set_ref nop /* * Load the TTE data into the TLB and retry the instruction. */ stxa %g7, [%g0] ASI_DTLB_DATA_IN_REG retry .align 128 .endm ENTRY(tl1_dmmu_miss_set_ref) /* * Recompute the TTE address, which we clobbered loading the TTE. * The TSB mask and address of the TSB are patched at startup. */ .globl tl1_dmmu_miss_patch_tsb_mask_2 tl1_dmmu_miss_patch_tsb_2: sethi %uhi(TSB_KERNEL), %g6 or %g6, %ulo(TSB_KERNEL), %g6 sllx %g6, 32, %g6 sethi %hi(TSB_KERNEL), %g7 or %g7, %g6, %g7 .globl tl1_dmmu_miss_patch_tsb_2 tl1_dmmu_miss_patch_tsb_mask_2: sethi %hi(TSB_KERNEL_MASK), %g6 or %g6, %lo(TSB_KERNEL_MASK), %g6 and %g5, %g6, %g5 sllx %g5, TTE_SHIFT, %g5 add %g5, %g7, %g5 /* * Set the reference bit. */ .globl tl1_dmmu_miss_patch_asi_1 tl1_dmmu_miss_patch_asi_1: wr %g0, TSB_ASI, %asi TTE_SET_REF(%g5, %g6, %g7, a, %asi) /* * May have become invalid during casxa, in which case start over. */ brgez,pn %g6, 1f nop /* * Load the TTE data into the TLB and retry the instruction. */ stxa %g6, [%g0] ASI_DTLB_DATA_IN_REG 1: retry END(tl1_dmmu_miss_set_ref) ENTRY(tl1_dmmu_miss_trap) /* * Switch to alternate globals. */ wrpr %g0, PSTATE_ALT, %pstate ldxa [%g0 + AA_DMMU_TAR] %asi, %g2 KSTACK_CHECK tl1_split clr %o1 set trap, %o2 mov %g2, %o3 ba %xcc, tl1_trap mov T_DATA_MISS | T_KERNEL, %o0 END(tl1_dmmu_miss_trap) ENTRY(tl1_dmmu_miss_direct) /* * Mask off the high bits of the virtual address to get the physical * address, and or in the TTE bits. The virtual address bits that * correspond to the TTE valid and page size bits are left set, so * they don't have to be included in the TTE bits below. We know they * are set because the virtual address is in the upper va hole. * NB: if we are taking advantage of the ASI_ATOMIC_QUAD_LDD_PHYS * and we get a miss on the directly accessed kernel TSB we must not * set TD_CV in order to access it uniformly bypassing the D$. */ setx TLB_DIRECT_ADDRESS_MASK, %g7, %g4 and %g5, %g4, %g4 setx TLB_DIRECT_TO_TTE_MASK, %g7, %g6 and %g5, %g6, %g5 .globl tl1_dmmu_miss_direct_patch_tsb_phys_1 tl1_dmmu_miss_direct_patch_tsb_phys_1: sethi %uhi(TSB_KERNEL_PHYS), %g3 or %g3, %ulo(TSB_KERNEL_PHYS), %g3 sllx %g3, 32, %g3 sethi %hi(TSB_KERNEL_PHYS), %g3 or %g7, %g3, %g7 cmp %g4, %g7 bl,pt %xcc, 1f or %g5, TD_CP | TD_W, %g5 .globl tl1_dmmu_miss_direct_patch_tsb_phys_end_1 tl1_dmmu_miss_direct_patch_tsb_phys_end_1: sethi %uhi(TSB_KERNEL_PHYS_END), %g3 or %g3, %ulo(TSB_KERNEL_PHYS_END), %g3 sllx %g3, 32, %g3 sethi %hi(TSB_KERNEL_PHYS_END), %g7 or %g7, %g3, %g7 cmp %g4, %g7 bg,a,pt %xcc, 1f nop ba,pt %xcc, 2f nop 1: or %g5, TD_CV, %g5 /* * Load the TTE data into the TLB and retry the instruction. */ 2: stxa %g5, [%g0] ASI_DTLB_DATA_IN_REG retry END(tl1_dmmu_miss_direct) .macro tl1_dmmu_prot ba,a %xcc, tl1_dmmu_prot_1 nop .align 128 .endm ENTRY(tl1_dmmu_prot_1) /* * Load the context and the virtual page number from the tag access * register. */ wr %g0, ASI_DMMU, %asi ldxa [%g0 + AA_DMMU_TAR] %asi, %g5 /* * Extract the context from the contents of the tag access register. * If it's non-zero this is a fault on a user address. Note that the * faulting address is passed in %g1. */ sllx %g5, 64 - TAR_VPN_SHIFT, %g6 brnz,a,pn %g6, tl1_dmmu_prot_user mov %g5, %g1 /* * Compute the address of the TTE. The TSB mask and address of the * TSB are patched at startup. */ .globl tl1_dmmu_prot_patch_tsb_1 tl1_dmmu_prot_patch_tsb_1: sethi %uhi(TSB_KERNEL), %g6 or %g6, %ulo(TSB_KERNEL), %g6 sllx %g6, 32, %g6 sethi %hi(TSB_KERNEL), %g7 or %g7, %g6, %g7 .globl tl1_dmmu_prot_patch_tsb_mask_1 tl1_dmmu_prot_patch_tsb_mask_1: sethi %hi(TSB_KERNEL_MASK), %g6 or %g6, %lo(TSB_KERNEL_MASK), %g6 srlx %g5, TAR_VPN_SHIFT, %g5 and %g5, %g6, %g6 sllx %g6, TTE_SHIFT, %g6 add %g6, %g7, %g6 /* * Load the TTE. */ .globl tl1_dmmu_prot_patch_quad_ldd_1 tl1_dmmu_prot_patch_quad_ldd_1: ldda [%g6] TSB_QUAD_LDD, %g6 /*, %g7 */ /* * Check that it's valid and writeable and that the virtual page * numbers match. */ brgez,pn %g7, tl1_dmmu_prot_trap andcc %g7, TD_SW, %g0 bz,pn %xcc, tl1_dmmu_prot_trap srlx %g6, TV_SIZE_BITS, %g6 cmp %g5, %g6 bne,pn %xcc, tl1_dmmu_prot_trap EMPTY /* * Delete the old TLB entry and clear the SFSR. */ sllx %g5, TAR_VPN_SHIFT, %g6 or %g6, TLB_DEMAP_NUCLEUS, %g6 stxa %g0, [%g6] ASI_DMMU_DEMAP stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync /* * Recompute the TTE address, which we clobbered loading the TTE. * The TSB mask and address of the TSB are patched at startup. */ .globl tl1_dmmu_prot_patch_tsb_2 tl1_dmmu_prot_patch_tsb_2: sethi %uhi(TSB_KERNEL), %g6 or %g6, %ulo(TSB_KERNEL), %g6 sllx %g6, 32, %g6 sethi %hi(TSB_KERNEL), %g7 or %g7, %g6, %g7 .globl tl1_dmmu_prot_patch_tsb_mask_2 tl1_dmmu_prot_patch_tsb_mask_2: sethi %hi(TSB_KERNEL_MASK), %g6 or %g6, %lo(TSB_KERNEL_MASK), %g6 and %g5, %g6, %g5 sllx %g5, TTE_SHIFT, %g5 add %g5, %g7, %g5 /* * Set the hardware write bit. */ .globl tl1_dmmu_prot_patch_asi_1 tl1_dmmu_prot_patch_asi_1: wr %g0, TSB_ASI, %asi TTE_SET_W(%g5, %g6, %g7, a, %asi) /* * May have become invalid during casxa, in which case start over. */ brgez,pn %g6, 1f or %g6, TD_W, %g6 /* * Load the TTE data into the TLB and retry the instruction. */ stxa %g6, [%g0] ASI_DTLB_DATA_IN_REG 1: retry END(tl1_dmmu_prot_1) ENTRY(tl1_dmmu_prot_trap) /* * Switch to alternate globals. */ wrpr %g0, PSTATE_ALT, %pstate /* * Load the SFAR, SFSR and TAR. Clear the SFSR. */ ldxa [%g0 + AA_DMMU_TAR] %asi, %g2 ldxa [%g0 + AA_DMMU_SFAR] %asi, %g3 ldxa [%g0 + AA_DMMU_SFSR] %asi, %g4 stxa %g0, [%g0 + AA_DMMU_SFSR] %asi membar #Sync tl1_split clr %o1 set trap, %o2 mov %g2, %o3 mov %g3, %o4 mov %g4, %o5 ba %xcc, tl1_trap mov T_DATA_PROTECTION | T_KERNEL, %o0 END(tl1_dmmu_prot_trap) .macro tl1_spill_0_n SPILL(stx, %sp + SPOFF, 8, EMPTY) saved retry .align 32 RSF_FATAL(T_SPILL) RSF_FATAL(T_SPILL) .endm .macro tl1_spill_2_n wr %g0, ASI_AIUP, %asi SPILL(stxa, %sp + SPOFF, 8, %asi) saved retry .align 32 RSF_SPILL_TOPCB RSF_SPILL_TOPCB .endm .macro tl1_spill_3_n wr %g0, ASI_AIUP, %asi SPILL(stwa, %sp, 4, %asi) saved retry .align 32 RSF_SPILL_TOPCB RSF_SPILL_TOPCB .endm .macro tl1_spill_7_n btst 1, %sp bnz,a,pn %xcc, tl1_spill_0_n nop srl %sp, 0, %sp SPILL(stw, %sp, 4, EMPTY) saved retry .align 32 RSF_FATAL(T_SPILL) RSF_FATAL(T_SPILL) .endm .macro tl1_spill_0_o wr %g0, ASI_AIUP, %asi SPILL(stxa, %sp + SPOFF, 8, %asi) saved retry .align 32 RSF_SPILL_TOPCB RSF_SPILL_TOPCB .endm .macro tl1_spill_1_o wr %g0, ASI_AIUP, %asi SPILL(stwa, %sp, 4, %asi) saved retry .align 32 RSF_SPILL_TOPCB RSF_SPILL_TOPCB .endm .macro tl1_spill_2_o RSF_SPILL_TOPCB .align 128 .endm .macro tl1_fill_0_n FILL(ldx, %sp + SPOFF, 8, EMPTY) restored retry .align 32 RSF_FATAL(T_FILL) RSF_FATAL(T_FILL) .endm .macro tl1_fill_2_n wr %g0, ASI_AIUP, %asi FILL(ldxa, %sp + SPOFF, 8, %asi) restored retry .align 32 RSF_FILL_MAGIC RSF_FILL_MAGIC .endm .macro tl1_fill_3_n wr %g0, ASI_AIUP, %asi FILL(lduwa, %sp, 4, %asi) restored retry .align 32 RSF_FILL_MAGIC RSF_FILL_MAGIC .endm .macro tl1_fill_7_n btst 1, %sp bnz,a,pt %xcc, tl1_fill_0_n nop srl %sp, 0, %sp FILL(lduw, %sp, 4, EMPTY) restored retry .align 32 RSF_FATAL(T_FILL) RSF_FATAL(T_FILL) .endm /* * This is used to spill windows that are still occupied with user * data on kernel entry to the pcb. */ ENTRY(tl1_spill_topcb) wrpr %g0, PSTATE_ALT, %pstate /* Free some globals for our use. */ dec 24, ASP_REG stx %g1, [ASP_REG + 0] stx %g2, [ASP_REG + 8] stx %g3, [ASP_REG + 16] ldx [PCB_REG + PCB_NSAVED], %g1 sllx %g1, PTR_SHIFT, %g2 add %g2, PCB_REG, %g2 stx %sp, [%g2 + PCB_RWSP] sllx %g1, RW_SHIFT, %g2 add %g2, PCB_REG, %g2 SPILL(stx, %g2 + PCB_RW, 8, EMPTY) inc %g1 stx %g1, [PCB_REG + PCB_NSAVED] #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl1_spill_topcb: pc=%#lx npc=%#lx sp=%#lx nsaved=%d" , %g1, %g2, %g3, 7, 8, 9) rdpr %tpc, %g2 stx %g2, [%g1 + KTR_PARM1] rdpr %tnpc, %g2 stx %g2, [%g1 + KTR_PARM2] stx %sp, [%g1 + KTR_PARM3] ldx [PCB_REG + PCB_NSAVED], %g2 stx %g2, [%g1 + KTR_PARM4] 9: #endif saved ldx [ASP_REG + 16], %g3 ldx [ASP_REG + 8], %g2 ldx [ASP_REG + 0], %g1 inc 24, ASP_REG retry END(tl1_spill_topcb) .macro tl1_spill_bad count .rept \count sir .align 128 .endr .endm .macro tl1_fill_bad count .rept \count sir .align 128 .endr .endm .macro tl1_soft count .rept \count tl1_gen T_SOFT | T_KERNEL .endr .endm .sect .trap .globl tl_trap_begin tl_trap_begin: nop .align 0x8000 .globl tl0_base tl0_base: tl0_reserved 8 ! 0x0-0x7 tl0_insn_excptn: tl0_insn_excptn ! 0x8 tl0_reserved 1 ! 0x9 tl0_insn_error: tl0_gen T_INSTRUCTION_ERROR ! 0xa tl0_reserved 5 ! 0xb-0xf tl0_insn_illegal: tl0_gen T_ILLEGAL_INSTRUCTION ! 0x10 tl0_priv_opcode: tl0_gen T_PRIVILEGED_OPCODE ! 0x11 tl0_reserved 14 ! 0x12-0x1f tl0_fp_disabled: tl0_gen T_FP_DISABLED ! 0x20 tl0_fp_ieee: tl0_gen T_FP_EXCEPTION_IEEE_754 ! 0x21 tl0_fp_other: tl0_gen T_FP_EXCEPTION_OTHER ! 0x22 tl0_tag_ovflw: tl0_gen T_TAG_OVERFLOW ! 0x23 tl0_clean_window: clean_window ! 0x24 tl0_divide: tl0_gen T_DIVISION_BY_ZERO ! 0x28 tl0_reserved 7 ! 0x29-0x2f tl0_data_excptn: tl0_data_excptn ! 0x30 tl0_reserved 1 ! 0x31 tl0_data_error: tl0_gen T_DATA_ERROR ! 0x32 tl0_reserved 1 ! 0x33 tl0_align: tl0_align ! 0x34 tl0_align_lddf: tl0_gen T_RESERVED ! 0x35 tl0_align_stdf: tl0_gen T_RESERVED ! 0x36 tl0_priv_action: tl0_gen T_PRIVILEGED_ACTION ! 0x37 tl0_reserved 9 ! 0x38-0x40 tl0_intr_level: tl0_intr_level ! 0x41-0x4f tl0_reserved 16 ! 0x50-0x5f tl0_intr_vector: intr_vector ! 0x60 tl0_watch_phys: tl0_gen T_PA_WATCHPOINT ! 0x61 tl0_watch_virt: tl0_gen T_VA_WATCHPOINT ! 0x62 tl0_ecc: tl0_gen T_CORRECTED_ECC_ERROR ! 0x63 tl0_immu_miss: tl0_immu_miss ! 0x64 tl0_dmmu_miss: tl0_dmmu_miss ! 0x68 tl0_dmmu_prot: tl0_dmmu_prot ! 0x6c tl0_reserved 16 ! 0x70-0x7f tl0_spill_0_n: tl0_spill_0_n ! 0x80 tl0_spill_1_n: tl0_spill_1_n ! 0x84 tl0_spill_bad 14 ! 0x88-0xbf tl0_fill_0_n: tl0_fill_0_n ! 0xc0 tl0_fill_1_n: tl0_fill_1_n ! 0xc4 tl0_fill_bad 14 ! 0xc8-0xff tl0_soft: tl0_gen T_SYSCALL ! 0x100 tl0_gen T_BREAKPOINT ! 0x101 tl0_gen T_DIVISION_BY_ZERO ! 0x102 tl0_reserved 1 ! 0x103 tl0_gen T_CLEAN_WINDOW ! 0x104 tl0_gen T_RANGE_CHECK ! 0x105 tl0_gen T_FIX_ALIGNMENT ! 0x106 tl0_gen T_INTEGER_OVERFLOW ! 0x107 tl0_gen T_SYSCALL ! 0x108 tl0_gen T_SYSCALL ! 0x109 tl0_fp_restore ! 0x10a tl0_reserved 5 ! 0x10b-0x10f tl0_gen T_TRAP_INSTRUCTION_16 ! 0x110 tl0_gen T_TRAP_INSTRUCTION_17 ! 0x111 tl0_gen T_TRAP_INSTRUCTION_18 ! 0x112 tl0_gen T_TRAP_INSTRUCTION_19 ! 0x113 tl0_gen T_TRAP_INSTRUCTION_20 ! 0x114 tl0_gen T_TRAP_INSTRUCTION_21 ! 0x115 tl0_gen T_TRAP_INSTRUCTION_22 ! 0x116 tl0_gen T_TRAP_INSTRUCTION_23 ! 0x117 tl0_gen T_TRAP_INSTRUCTION_24 ! 0x118 tl0_gen T_TRAP_INSTRUCTION_25 ! 0x119 tl0_gen T_TRAP_INSTRUCTION_26 ! 0x11a tl0_gen T_TRAP_INSTRUCTION_27 ! 0x11b tl0_gen T_TRAP_INSTRUCTION_28 ! 0x11c tl0_gen T_TRAP_INSTRUCTION_29 ! 0x11d tl0_gen T_TRAP_INSTRUCTION_30 ! 0x11e tl0_gen T_TRAP_INSTRUCTION_31 ! 0x11f tl0_reserved 32 ! 0x120-0x13f tl0_gen T_SYSCALL ! 0x140 tl0_syscall ! 0x141 tl0_gen T_SYSCALL ! 0x142 tl0_gen T_SYSCALL ! 0x143 tl0_reserved 188 ! 0x144-0x1ff tl1_base: tl1_reserved 8 ! 0x200-0x207 tl1_insn_excptn: tl1_insn_excptn ! 0x208 tl1_reserved 1 ! 0x209 tl1_insn_error: tl1_gen T_INSTRUCTION_ERROR ! 0x20a tl1_reserved 5 ! 0x20b-0x20f tl1_insn_illegal: tl1_gen T_ILLEGAL_INSTRUCTION ! 0x210 tl1_priv_opcode: tl1_gen T_PRIVILEGED_OPCODE ! 0x211 tl1_reserved 14 ! 0x212-0x21f tl1_fp_disabled: tl1_fp_disabled ! 0x220 tl1_fp_ieee: tl1_gen T_FP_EXCEPTION_IEEE_754 ! 0x221 tl1_fp_other: tl1_gen T_FP_EXCEPTION_OTHER ! 0x222 tl1_tag_ovflw: tl1_gen T_TAG_OVERFLOW ! 0x223 tl1_clean_window: clean_window ! 0x224 tl1_divide: tl1_gen T_DIVISION_BY_ZERO ! 0x228 tl1_reserved 7 ! 0x229-0x22f tl1_data_excptn: tl1_data_excptn ! 0x230 tl1_reserved 1 ! 0x231 tl1_data_error: tl1_gen T_DATA_ERROR ! 0x232 tl1_reserved 1 ! 0x233 tl1_align: tl1_align ! 0x234 tl1_align_lddf: tl1_gen T_RESERVED ! 0x235 tl1_align_stdf: tl1_gen T_RESERVED ! 0x236 tl1_priv_action: tl1_gen T_PRIVILEGED_ACTION ! 0x237 tl1_reserved 9 ! 0x238-0x240 tl1_intr_level: tl1_intr_level ! 0x241-0x24f tl1_reserved 16 ! 0x250-0x25f tl1_intr_vector: intr_vector ! 0x260 tl1_watch_phys: tl1_gen T_PA_WATCHPOINT ! 0x261 tl1_watch_virt: tl1_gen T_VA_WATCHPOINT ! 0x262 tl1_ecc: tl1_gen T_CORRECTED_ECC_ERROR ! 0x263 tl1_immu_miss: tl1_immu_miss ! 0x264 tl1_dmmu_miss: tl1_dmmu_miss ! 0x268 tl1_dmmu_prot: tl1_dmmu_prot ! 0x26c tl1_reserved 16 ! 0x270-0x27f tl1_spill_0_n: tl1_spill_0_n ! 0x280 tl1_spill_bad 1 ! 0x284 tl1_spill_2_n: tl1_spill_2_n ! 0x288 tl1_spill_3_n: tl1_spill_3_n ! 0x28c tl1_spill_bad 3 ! 0x290-0x29b tl1_spill_7_n: tl1_spill_7_n ! 0x29c tl1_spill_0_o: tl1_spill_0_o ! 0x2a0 tl1_spill_1_o: tl1_spill_1_o ! 0x2a4 tl1_spill_2_o: tl1_spill_2_o ! 0x2a8 tl1_spill_bad 5 ! 0x2ac-0x2bf tl1_fill_0_n: tl1_fill_0_n ! 0x2c0 tl1_fill_bad 1 ! 0x2c4 tl1_fill_2_n: tl1_fill_2_n ! 0x2c8 tl1_fill_3_n: tl1_fill_3_n ! 0x2cc tl1_fill_bad 3 ! 0x2d0-0x2db tl1_fill_7_n: tl1_fill_7_n ! 0x2dc tl1_fill_bad 8 ! 0x2e0-0x2ff tl1_reserved 1 ! 0x300 tl1_breakpoint: tl1_gen T_BREAKPOINT ! 0x301 tl1_gen T_RSTRWP_PHYS ! 0x302 tl1_gen T_RSTRWP_VIRT ! 0x303 tl1_reserved 252 ! 0x304-0x3ff .globl tl_trap_end tl_trap_end: nop /* * User trap entry point * * void tl0_utrap(u_long type, u_long o1, u_long o2, u_long tar, u_long sfar, * u_long sfsr) * * This handles redirecting a trap back to usermode as a user trap. The user * program must have first registered a trap handler with the kernel using * sysarch(SPARC_UTRAP_INSTALL). The trap handler is passed enough state * for it to return to the trapping code directly, it will not return through * the kernel. The trap type is passed in %o0, all out registers must be * passed through to tl0_trap or to usermode untouched. Note that the * parameters passed in out registers may be used by the user trap handler. * Do not change the registers they are passed in or you will break the ABI. * * If the trap type allows user traps, setup state to execute the user trap * handler and bounce back to usermode, otherwise branch to tl0_trap. */ ENTRY(tl0_utrap) /* * Check if the trap type allows user traps. */ cmp %o0, UT_MAX bge,a,pt %xcc, tl0_trap nop /* * Load the user trap handler from the utrap table. */ ldx [PCPU(CURTHREAD)], %l0 ldx [%l0 + TD_PROC], %l0 ldx [%l0 + P_MD + MD_UTRAP], %l0 brz,pt %l0, tl0_trap sllx %o0, PTR_SHIFT, %l1 ldx [%l0 + %l1], %l0 brz,a,pt %l0, tl0_trap nop /* * If the save we did on entry to the kernel had to spill a window * to the pcb, pretend we took a spill trap instead. Any windows * that are in the pcb must be copied out or the fill handler will * not be able to find them, since the user trap handler returns * directly to the trapping code. Note that we only support precise * user traps, which implies that the condition that caused the trap * in the first place is still valid, so it will occur again when we * re-execute the trapping instruction. */ ldx [PCB_REG + PCB_NSAVED], %l1 brnz,a,pn %l1, tl0_trap mov T_SPILL, %o0 /* * Pass %fsr in %l4, %tstate in %l5, %tpc in %l6 and %tnpc in %l7. * The ABI specifies only %l6 and %l7, but we need to pass %fsr or * it may be clobbered by an interrupt before the user trap code * can read it, and we must pass %tstate in order to restore %ccr * and %asi. The %fsr must be stored to memory, so we use the * temporary stack for that. */ rd %fprs, %l1 or %l1, FPRS_FEF, %l2 wr %l2, 0, %fprs dec 8, ASP_REG stx %fsr, [ASP_REG] ldx [ASP_REG], %l4 inc 8, ASP_REG wr %l1, 0, %fprs rdpr %tstate, %l5 rdpr %tpc, %l6 rdpr %tnpc, %l7 /* * Setup %tnpc to return to. */ wrpr %l0, 0, %tnpc /* * Setup %wstate for return, clear WSTATE_TRANSITION. */ rdpr %wstate, %l1 and %l1, WSTATE_NORMAL_MASK, %l1 wrpr %l1, 0, %wstate /* * Setup %tstate for return, change the saved cwp to point to the * current window instead of the window at the time of the trap. */ andn %l5, TSTATE_CWP_MASK, %l1 rdpr %cwp, %l2 wrpr %l1, %l2, %tstate /* * Setup %sp. Userland processes will crash if this is not setup. */ sub %fp, CCFSZ, %sp /* * Execute the user trap handler. */ done END(tl0_utrap) /* * (Real) User trap entry point * * void tl0_trap(u_int type, u_long o1, u_long o2, u_long tar, u_long sfsr, * u_int sfsr) * * The following setup has been performed: * - the windows have been split and the active user window has been saved * (maybe just to the pcb) * - we are on alternate globals and interrupts are disabled * * We switch to the kernel stack, build a trapframe, switch to normal * globals, enable interrupts and call trap. * * NOTE: We must be very careful setting up the per-cpu pointer. We know that * it has been pre-set in alternate globals, so we read it from there and setup * the normal %g7 *before* enabling interrupts. This avoids any possibility * of cpu migration and using the wrong pcpup. */ ENTRY(tl0_trap) /* * Force kernel store order. */ wrpr %g0, PSTATE_ALT, %pstate rdpr %tstate, %l0 rdpr %tpc, %l1 rdpr %tnpc, %l2 rd %y, %l3 rd %fprs, %l4 rdpr %wstate, %l5 #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl0_trap: td=%p type=%#x pil=%#lx pc=%#lx npc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] stx %o0, [%g1 + KTR_PARM2] rdpr %pil, %g2 stx %g2, [%g1 + KTR_PARM3] stx %l1, [%g1 + KTR_PARM4] stx %l2, [%g1 + KTR_PARM5] stx %i6, [%g1 + KTR_PARM6] 9: #endif 1: and %l5, WSTATE_NORMAL_MASK, %l5 sllx %l5, WSTATE_OTHER_SHIFT, %l5 wrpr %l5, WSTATE_KERNEL, %wstate rdpr %canrestore, %l6 wrpr %l6, 0, %otherwin wrpr %g0, 0, %canrestore sub PCB_REG, SPOFF + CCFSZ + TF_SIZEOF, %sp stx %o0, [%sp + SPOFF + CCFSZ + TF_TYPE] stx %o1, [%sp + SPOFF + CCFSZ + TF_LEVEL] stx %o3, [%sp + SPOFF + CCFSZ + TF_TAR] stx %o4, [%sp + SPOFF + CCFSZ + TF_SFAR] stx %o5, [%sp + SPOFF + CCFSZ + TF_SFSR] stx %l0, [%sp + SPOFF + CCFSZ + TF_TSTATE] stx %l1, [%sp + SPOFF + CCFSZ + TF_TPC] stx %l2, [%sp + SPOFF + CCFSZ + TF_TNPC] stx %l3, [%sp + SPOFF + CCFSZ + TF_Y] stx %l4, [%sp + SPOFF + CCFSZ + TF_FPRS] stx %l5, [%sp + SPOFF + CCFSZ + TF_WSTATE] wr %g0, FPRS_FEF, %fprs stx %fsr, [%sp + SPOFF + CCFSZ + TF_FSR] rd %gsr, %l6 stx %l6, [%sp + SPOFF + CCFSZ + TF_GSR] wr %g0, 0, %fprs mov PCB_REG, %l0 mov PCPU_REG, %l1 wrpr %g0, PSTATE_NORMAL, %pstate stx %g6, [%sp + SPOFF + CCFSZ + TF_G6] stx %g7, [%sp + SPOFF + CCFSZ + TF_G7] mov %l0, PCB_REG mov %l1, PCPU_REG wrpr %g0, PSTATE_KERNEL, %pstate stx %i0, [%sp + SPOFF + CCFSZ + TF_O0] stx %i1, [%sp + SPOFF + CCFSZ + TF_O1] stx %i2, [%sp + SPOFF + CCFSZ + TF_O2] stx %i3, [%sp + SPOFF + CCFSZ + TF_O3] stx %i4, [%sp + SPOFF + CCFSZ + TF_O4] stx %i5, [%sp + SPOFF + CCFSZ + TF_O5] stx %i6, [%sp + SPOFF + CCFSZ + TF_O6] stx %i7, [%sp + SPOFF + CCFSZ + TF_O7] stx %g1, [%sp + SPOFF + CCFSZ + TF_G1] stx %g2, [%sp + SPOFF + CCFSZ + TF_G2] stx %g3, [%sp + SPOFF + CCFSZ + TF_G3] stx %g4, [%sp + SPOFF + CCFSZ + TF_G4] stx %g5, [%sp + SPOFF + CCFSZ + TF_G5] set tl0_ret - 8, %o7 jmpl %o2, %g0 add %sp, CCFSZ + SPOFF, %o0 END(tl0_trap) /* * void tl0_intr(u_int level, u_int mask) */ ENTRY(tl0_intr) /* * Force kernel store order. */ wrpr %g0, PSTATE_ALT, %pstate rdpr %tstate, %l0 rdpr %tpc, %l1 rdpr %tnpc, %l2 rd %y, %l3 rd %fprs, %l4 rdpr %wstate, %l5 #if KTR_COMPILE & KTR_INTR CATR(KTR_INTR, "tl0_intr: td=%p level=%#x pil=%#lx pc=%#lx npc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] stx %o0, [%g1 + KTR_PARM2] rdpr %pil, %g2 stx %g2, [%g1 + KTR_PARM3] stx %l1, [%g1 + KTR_PARM4] stx %l2, [%g1 + KTR_PARM5] stx %i6, [%g1 + KTR_PARM6] 9: #endif wrpr %o0, 0, %pil wr %o1, 0, %clear_softint and %l5, WSTATE_NORMAL_MASK, %l5 sllx %l5, WSTATE_OTHER_SHIFT, %l5 wrpr %l5, WSTATE_KERNEL, %wstate rdpr %canrestore, %l6 wrpr %l6, 0, %otherwin wrpr %g0, 0, %canrestore sub PCB_REG, SPOFF + CCFSZ + TF_SIZEOF, %sp stx %l0, [%sp + SPOFF + CCFSZ + TF_TSTATE] stx %l1, [%sp + SPOFF + CCFSZ + TF_TPC] stx %l2, [%sp + SPOFF + CCFSZ + TF_TNPC] stx %l3, [%sp + SPOFF + CCFSZ + TF_Y] stx %l4, [%sp + SPOFF + CCFSZ + TF_FPRS] stx %l5, [%sp + SPOFF + CCFSZ + TF_WSTATE] wr %g0, FPRS_FEF, %fprs stx %fsr, [%sp + SPOFF + CCFSZ + TF_FSR] rd %gsr, %l6 stx %l6, [%sp + SPOFF + CCFSZ + TF_GSR] wr %g0, 0, %fprs mov %o0, %l3 mov T_INTERRUPT, %o1 stx %o0, [%sp + SPOFF + CCFSZ + TF_LEVEL] stx %o1, [%sp + SPOFF + CCFSZ + TF_TYPE] mov PCB_REG, %l0 mov PCPU_REG, %l1 wrpr %g0, PSTATE_NORMAL, %pstate stx %g1, [%sp + SPOFF + CCFSZ + TF_G1] stx %g2, [%sp + SPOFF + CCFSZ + TF_G2] stx %g3, [%sp + SPOFF + CCFSZ + TF_G3] stx %g4, [%sp + SPOFF + CCFSZ + TF_G4] stx %g5, [%sp + SPOFF + CCFSZ + TF_G5] stx %g6, [%sp + SPOFF + CCFSZ + TF_G6] stx %g7, [%sp + SPOFF + CCFSZ + TF_G7] mov %l0, PCB_REG mov %l1, PCPU_REG wrpr %g0, PSTATE_KERNEL, %pstate stx %i0, [%sp + SPOFF + CCFSZ + TF_O0] stx %i1, [%sp + SPOFF + CCFSZ + TF_O1] stx %i2, [%sp + SPOFF + CCFSZ + TF_O2] stx %i3, [%sp + SPOFF + CCFSZ + TF_O3] stx %i4, [%sp + SPOFF + CCFSZ + TF_O4] stx %i5, [%sp + SPOFF + CCFSZ + TF_O5] stx %i6, [%sp + SPOFF + CCFSZ + TF_O6] stx %i7, [%sp + SPOFF + CCFSZ + TF_O7] SET(intr_handlers, %l1, %l0) sllx %l3, IH_SHIFT, %l1 ldx [%l0 + %l1], %l1 KASSERT(%l1, "tl0_intr: ih null") call %l1 add %sp, CCFSZ + SPOFF, %o0 /* %l3 contains PIL */ SET(intrcnt, %l1, %l2) prefetcha [%l2] ASI_N, 1 SET(pil_countp, %l1, %l0) sllx %l3, 1, %l1 lduh [%l0 + %l1], %l0 sllx %l0, 3, %l0 add %l0, %l2, %l0 ldx [%l0], %l1 inc %l1 stx %l1, [%l0] lduw [PCPU(CNT) + V_INTR], %l0 inc %l0 stw %l0, [PCPU(CNT) + V_INTR] ba,a %xcc, tl0_ret nop END(tl0_intr) /* * Initiate return to usermode. * * Called with a trapframe on the stack. The window that was setup in * tl0_trap may have been used by "fast" trap handlers that pretend to be * leaf functions, so all ins and locals may have been clobbered since * then. * * This code is rather long and complicated. */ ENTRY(tl0_ret) /* * Check for pending asts atomically with returning. We must raise * the PIL before checking, and if no asts are found the PIL must * remain raised until the retry is executed, or we risk missing asts * caused by interrupts occurring after the test. If the PIL is * lowered, as it is when we call ast, the check must be re-executed. */ wrpr %g0, PIL_TICK, %pil ldx [PCPU(CURTHREAD)], %l0 lduw [%l0 + TD_FLAGS], %l1 set TDF_ASTPENDING | TDF_NEEDRESCHED, %l2 and %l1, %l2, %l1 brz,a,pt %l1, 1f nop /* * We have an AST. Re-enable interrupts and handle it, then restart * the return sequence. */ wrpr %g0, 0, %pil call ast add %sp, CCFSZ + SPOFF, %o0 ba,a %xcc, tl0_ret nop /* * Check for windows that were spilled to the pcb and need to be * copied out. This must be the last thing that is done before the * return to usermode. If there are still user windows in the cpu * and we call a nested function after this, which causes them to be * spilled to the pcb, they will not be copied out and the stack will * be inconsistent. */ 1: ldx [PCB_REG + PCB_NSAVED], %l1 brz,a,pt %l1, 2f nop wrpr %g0, 0, %pil mov T_SPILL, %o0 stx %o0, [%sp + SPOFF + CCFSZ + TF_TYPE] call trap add %sp, SPOFF + CCFSZ, %o0 ba,a %xcc, tl0_ret nop /* * Restore the out and most global registers from the trapframe. * The ins will become the outs when we restore below. */ 2: ldx [%sp + SPOFF + CCFSZ + TF_O0], %i0 ldx [%sp + SPOFF + CCFSZ + TF_O1], %i1 ldx [%sp + SPOFF + CCFSZ + TF_O2], %i2 ldx [%sp + SPOFF + CCFSZ + TF_O3], %i3 ldx [%sp + SPOFF + CCFSZ + TF_O4], %i4 ldx [%sp + SPOFF + CCFSZ + TF_O5], %i5 ldx [%sp + SPOFF + CCFSZ + TF_O6], %i6 ldx [%sp + SPOFF + CCFSZ + TF_O7], %i7 ldx [%sp + SPOFF + CCFSZ + TF_G1], %g1 ldx [%sp + SPOFF + CCFSZ + TF_G2], %g2 ldx [%sp + SPOFF + CCFSZ + TF_G3], %g3 ldx [%sp + SPOFF + CCFSZ + TF_G4], %g4 ldx [%sp + SPOFF + CCFSZ + TF_G5], %g5 /* * Load everything we need to restore below before disabling * interrupts. */ ldx [%sp + SPOFF + CCFSZ + TF_FPRS], %l0 ldx [%sp + SPOFF + CCFSZ + TF_GSR], %l1 ldx [%sp + SPOFF + CCFSZ + TF_TNPC], %l2 ldx [%sp + SPOFF + CCFSZ + TF_TPC], %l3 ldx [%sp + SPOFF + CCFSZ + TF_TSTATE], %l4 ldx [%sp + SPOFF + CCFSZ + TF_Y], %l5 ldx [%sp + SPOFF + CCFSZ + TF_WSTATE], %l6 /* * Disable interrupts to restore the special globals. They are not * saved and restored for all kernel traps, so an interrupt at the * wrong time would clobber them. */ wrpr %g0, PSTATE_NORMAL, %pstate ldx [%sp + SPOFF + CCFSZ + TF_G6], %g6 ldx [%sp + SPOFF + CCFSZ + TF_G7], %g7 /* * Switch to alternate globals. This frees up some registers we * can use after the restore changes our window. */ wrpr %g0, PSTATE_ALT, %pstate /* * Drop %pil to zero. It must have been zero at the time of the * trap, since we were in usermode, but it was raised above in * order to check for asts atomically. We have interrupts disabled * so any interrupts will not be serviced until we complete the * return to usermode. */ wrpr %g0, 0, %pil /* * Save %fprs in an alternate global so it can be restored after the * restore instruction below. If we restore it before the restore, * and the restore traps we may run for a while with floating point * enabled in the kernel, which we want to avoid. */ mov %l0, %g1 /* * Restore %fsr and %gsr. These need floating point enabled in %fprs, * so we set it temporarily and then clear it. */ wr %g0, FPRS_FEF, %fprs ldx [%sp + SPOFF + CCFSZ + TF_FSR], %fsr wr %l1, 0, %gsr wr %g0, 0, %fprs /* * Restore program counters. This could be done after the restore * but we're out of alternate globals to store them in... */ wrpr %l2, 0, %tnpc wrpr %l3, 0, %tpc /* * Save %tstate in an alternate global and clear the %cwp field. %cwp * will be affected by the restore below and we need to make sure it * points to the current window at that time, not the window that was * active at the time of the trap. */ andn %l4, TSTATE_CWP_MASK, %g2 /* * Save %y in an alternate global. */ mov %l5, %g4 /* * Setup %wstate for return. We need to restore the user window state * which we saved in wstate.other when we trapped. We also need to * set the transition bit so the restore will be handled specially * if it traps, use the xor feature of wrpr to do that. */ srlx %l6, WSTATE_OTHER_SHIFT, %g3 wrpr %g3, WSTATE_TRANSITION, %wstate /* * Setup window management registers for return. If not all user * windows were spilled in the kernel %otherwin will be non-zero, * so we need to transfer it to %canrestore to correctly restore * those windows. Otherwise everything gets set to zero and the * restore below will fill a window directly from the user stack. */ rdpr %otherwin, %o0 wrpr %o0, 0, %canrestore wrpr %g0, 0, %otherwin wrpr %o0, 0, %cleanwin /* * Now do the restore. If this instruction causes a fill trap which * fails to fill a window from the user stack, we will resume at * tl0_ret_fill_end and call back into the kernel. */ restore tl0_ret_fill: /* * We made it. We're back in the window that was active at the time * of the trap, and ready to return to usermode. */ /* * Restore %frps. This was saved in an alternate global above. */ wr %g1, 0, %fprs /* * Fixup %tstate so the saved %cwp points to the current window and * restore it. */ rdpr %cwp, %g1 wrpr %g2, %g1, %tstate /* * Restore the user window state. The transition bit was set above * for special handling of the restore, this clears it. */ wrpr %g3, 0, %wstate #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl0_ret: td=%#lx pil=%#lx pc=%#lx npc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] rdpr %pil, %g2 stx %g2, [%g1 + KTR_PARM2] rdpr %tpc, %g2 stx %g2, [%g1 + KTR_PARM3] rdpr %tnpc, %g2 stx %g2, [%g1 + KTR_PARM4] stx %sp, [%g1 + KTR_PARM5] 9: #endif /* * Restore %y. Note that the CATR above clobbered it. */ wr %g4, 0, %y /* * Return to usermode. */ retry tl0_ret_fill_end: #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl0_ret: fill magic ps=%#lx ws=%#lx sp=%#lx" , %l0, %l1, %l2, 7, 8, 9) rdpr %pstate, %l1 stx %l1, [%l0 + KTR_PARM1] stx %l6, [%l0 + KTR_PARM2] stx %sp, [%l0 + KTR_PARM3] 9: /* * Restore %y clobbered by the CATR. This was saved in %l5 above. */ wr %l5, 0, %y #endif /* * The restore above caused a fill trap and the fill handler was * unable to fill a window from the user stack. The special fill * handler recognized this and punted, sending us here. We need * to carefully undo any state that was restored before the restore * was executed and call trap again. Trap will copyin a window * from the user stack which will fault in the page we need so the * restore above will succeed when we try again. If this fails * the process has trashed its stack, so we kill it. */ /* * Restore the kernel window state. This was saved in %l6 above, and * since the restore failed we're back in the same window. */ wrpr %l6, 0, %wstate /* * Restore the normal globals which have predefined values in the * kernel. We clobbered them above restoring the user's globals * so this is very important. * XXX PSTATE_ALT must already be set. */ wrpr %g0, PSTATE_ALT, %pstate mov PCB_REG, %o0 mov PCPU_REG, %o1 wrpr %g0, PSTATE_NORMAL, %pstate mov %o0, PCB_REG mov %o1, PCPU_REG wrpr %g0, PSTATE_KERNEL, %pstate /* * Simulate a fill trap and then start the whole return sequence over * again. This is special because it only copies in 1 window, not 2 * as we would for a normal failed fill. This may be the first time * the process has been run, so there may not be 2 windows worth of * stack to copyin. */ mov T_FILL_RET, %o0 stx %o0, [%sp + SPOFF + CCFSZ + TF_TYPE] call trap add %sp, SPOFF + CCFSZ, %o0 ba,a %xcc, tl0_ret nop END(tl0_ret) /* * Kernel trap entry point * * void tl1_trap(u_int type, u_long o1, u_long o2, u_long tar, u_long sfar, * u_int sfsr) * * This is easy because the stack is already setup and the windows don't need * to be split. We build a trapframe and call trap(), the same as above, but * the outs don't need to be saved. */ ENTRY(tl1_trap) rdpr %tstate, %l0 rdpr %tpc, %l1 rdpr %tnpc, %l2 rdpr %pil, %l3 rd %y, %l4 rdpr %wstate, %l5 #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl1_trap: td=%p type=%#lx pil=%#lx pc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] stx %o0, [%g1 + KTR_PARM2] stx %l3, [%g1 + KTR_PARM3] stx %l1, [%g1 + KTR_PARM4] stx %i6, [%g1 + KTR_PARM5] 9: #endif wrpr %g0, 1, %tl and %l5, WSTATE_OTHER_MASK, %l5 wrpr %l5, WSTATE_KERNEL, %wstate stx %o0, [%sp + SPOFF + CCFSZ + TF_TYPE] stx %o1, [%sp + SPOFF + CCFSZ + TF_LEVEL] stx %o3, [%sp + SPOFF + CCFSZ + TF_TAR] stx %o4, [%sp + SPOFF + CCFSZ + TF_SFAR] stx %o5, [%sp + SPOFF + CCFSZ + TF_SFSR] stx %l0, [%sp + SPOFF + CCFSZ + TF_TSTATE] stx %l1, [%sp + SPOFF + CCFSZ + TF_TPC] stx %l2, [%sp + SPOFF + CCFSZ + TF_TNPC] stx %l3, [%sp + SPOFF + CCFSZ + TF_PIL] stx %l4, [%sp + SPOFF + CCFSZ + TF_Y] mov PCB_REG, %l0 mov PCPU_REG, %l1 wrpr %g0, PSTATE_NORMAL, %pstate stx %g6, [%sp + SPOFF + CCFSZ + TF_G6] stx %g7, [%sp + SPOFF + CCFSZ + TF_G7] mov %l0, PCB_REG mov %l1, PCPU_REG wrpr %g0, PSTATE_KERNEL, %pstate stx %i0, [%sp + SPOFF + CCFSZ + TF_O0] stx %i1, [%sp + SPOFF + CCFSZ + TF_O1] stx %i2, [%sp + SPOFF + CCFSZ + TF_O2] stx %i3, [%sp + SPOFF + CCFSZ + TF_O3] stx %i4, [%sp + SPOFF + CCFSZ + TF_O4] stx %i5, [%sp + SPOFF + CCFSZ + TF_O5] stx %i6, [%sp + SPOFF + CCFSZ + TF_O6] stx %i7, [%sp + SPOFF + CCFSZ + TF_O7] stx %g1, [%sp + SPOFF + CCFSZ + TF_G1] stx %g2, [%sp + SPOFF + CCFSZ + TF_G2] stx %g3, [%sp + SPOFF + CCFSZ + TF_G3] stx %g4, [%sp + SPOFF + CCFSZ + TF_G4] stx %g5, [%sp + SPOFF + CCFSZ + TF_G5] set tl1_ret - 8, %o7 jmpl %o2, %g0 add %sp, CCFSZ + SPOFF, %o0 END(tl1_trap) ENTRY(tl1_ret) ldx [%sp + SPOFF + CCFSZ + TF_O0], %i0 ldx [%sp + SPOFF + CCFSZ + TF_O1], %i1 ldx [%sp + SPOFF + CCFSZ + TF_O2], %i2 ldx [%sp + SPOFF + CCFSZ + TF_O3], %i3 ldx [%sp + SPOFF + CCFSZ + TF_O4], %i4 ldx [%sp + SPOFF + CCFSZ + TF_O5], %i5 ldx [%sp + SPOFF + CCFSZ + TF_O6], %i6 ldx [%sp + SPOFF + CCFSZ + TF_O7], %i7 ldx [%sp + SPOFF + CCFSZ + TF_G1], %g1 ldx [%sp + SPOFF + CCFSZ + TF_G2], %g2 ldx [%sp + SPOFF + CCFSZ + TF_G3], %g3 ldx [%sp + SPOFF + CCFSZ + TF_G4], %g4 ldx [%sp + SPOFF + CCFSZ + TF_G5], %g5 ldx [%sp + SPOFF + CCFSZ + TF_TSTATE], %l0 ldx [%sp + SPOFF + CCFSZ + TF_TPC], %l1 ldx [%sp + SPOFF + CCFSZ + TF_TNPC], %l2 ldx [%sp + SPOFF + CCFSZ + TF_PIL], %l3 ldx [%sp + SPOFF + CCFSZ + TF_Y], %l4 set VM_MIN_PROM_ADDRESS, %l5 cmp %l1, %l5 bl,a,pt %xcc, 1f nop set VM_MAX_PROM_ADDRESS, %l5 cmp %l1, %l5 bg,a,pt %xcc, 1f nop wrpr %g0, PSTATE_NORMAL, %pstate ldx [%sp + SPOFF + CCFSZ + TF_G6], %g6 ldx [%sp + SPOFF + CCFSZ + TF_G7], %g7 1: wrpr %g0, PSTATE_ALT, %pstate andn %l0, TSTATE_CWP_MASK, %g1 mov %l1, %g2 mov %l2, %g3 mov %l4, %g4 wrpr %l3, 0, %pil restore wrpr %g0, 2, %tl wrpr %g2, 0, %tpc wrpr %g3, 0, %tnpc rdpr %cwp, %g2 wrpr %g1, %g2, %tstate #if KTR_COMPILE & KTR_TRAP CATR(KTR_TRAP, "tl1_ret: td=%#lx pil=%#lx ts=%#lx pc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] rdpr %pil, %g2 stx %g2, [%g1 + KTR_PARM2] rdpr %tstate, %g2 stx %g2, [%g1 + KTR_PARM3] rdpr %tpc, %g2 stx %g2, [%g1 + KTR_PARM4] stx %sp, [%g1 + KTR_PARM5] 9: #endif wr %g4, 0, %y retry END(tl1_ret) /* * void tl1_intr(u_int level, u_int mask) */ ENTRY(tl1_intr) rdpr %tstate, %l0 rdpr %tpc, %l1 rdpr %tnpc, %l2 rdpr %pil, %l3 rd %y, %l4 rdpr %wstate, %l5 #if KTR_COMPILE & KTR_INTR CATR(KTR_INTR, "tl1_intr: td=%p level=%#x pil=%#lx pc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] stx %o0, [%g1 + KTR_PARM2] stx %l3, [%g1 + KTR_PARM3] stx %l1, [%g1 + KTR_PARM4] stx %i6, [%g1 + KTR_PARM5] 9: #endif wrpr %o0, 0, %pil wr %o1, 0, %clear_softint wrpr %g0, 1, %tl and %l5, WSTATE_OTHER_MASK, %l5 wrpr %l5, WSTATE_KERNEL, %wstate stx %l0, [%sp + SPOFF + CCFSZ + TF_TSTATE] stx %l1, [%sp + SPOFF + CCFSZ + TF_TPC] stx %l2, [%sp + SPOFF + CCFSZ + TF_TNPC] stx %l3, [%sp + SPOFF + CCFSZ + TF_PIL] stx %l4, [%sp + SPOFF + CCFSZ + TF_Y] mov %o0, %l7 mov T_INTERRUPT | T_KERNEL, %o1 stx %o0, [%sp + SPOFF + CCFSZ + TF_LEVEL] stx %o1, [%sp + SPOFF + CCFSZ + TF_TYPE] stx %i6, [%sp + SPOFF + CCFSZ + TF_O6] stx %i7, [%sp + SPOFF + CCFSZ + TF_O7] mov PCB_REG, %l4 mov PCPU_REG, %l5 wrpr %g0, PSTATE_NORMAL, %pstate stx %g1, [%sp + SPOFF + CCFSZ + TF_G1] stx %g2, [%sp + SPOFF + CCFSZ + TF_G2] stx %g3, [%sp + SPOFF + CCFSZ + TF_G3] stx %g4, [%sp + SPOFF + CCFSZ + TF_G4] stx %g5, [%sp + SPOFF + CCFSZ + TF_G5] mov %l4, PCB_REG mov %l5, PCPU_REG wrpr %g0, PSTATE_KERNEL, %pstate SET(intr_handlers, %l5, %l4) sllx %l7, IH_SHIFT, %l5 ldx [%l4 + %l5], %l5 KASSERT(%l5, "tl1_intr: ih null") call %l5 add %sp, CCFSZ + SPOFF, %o0 /* %l7 contains PIL */ SET(intrcnt, %l5, %l4) prefetcha [%l4] ASI_N, 1 SET(pil_countp, %l5, %l6) sllx %l7, 1, %l5 lduh [%l5 + %l6], %l5 sllx %l5, 3, %l5 add %l5, %l4, %l4 ldx [%l4], %l5 inc %l5 stx %l5, [%l4] lduw [PCPU(CNT) + V_INTR], %l4 inc %l4 stw %l4, [PCPU(CNT) + V_INTR] ldx [%sp + SPOFF + CCFSZ + TF_Y], %l4 ldx [%sp + SPOFF + CCFSZ + TF_G1], %g1 ldx [%sp + SPOFF + CCFSZ + TF_G2], %g2 ldx [%sp + SPOFF + CCFSZ + TF_G3], %g3 ldx [%sp + SPOFF + CCFSZ + TF_G4], %g4 ldx [%sp + SPOFF + CCFSZ + TF_G5], %g5 wrpr %g0, PSTATE_ALT, %pstate andn %l0, TSTATE_CWP_MASK, %g1 mov %l1, %g2 mov %l2, %g3 mov %l4, %g4 wrpr %l3, 0, %pil restore wrpr %g0, 2, %tl wrpr %g2, 0, %tpc wrpr %g3, 0, %tnpc rdpr %cwp, %g2 wrpr %g1, %g2, %tstate #if KTR_COMPILE & KTR_INTR CATR(KTR_INTR, "tl1_intr: td=%#x pil=%#lx ts=%#lx pc=%#lx sp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] rdpr %pil, %g2 stx %g2, [%g1 + KTR_PARM2] rdpr %tstate, %g2 stx %g2, [%g1 + KTR_PARM3] rdpr %tpc, %g2 stx %g2, [%g1 + KTR_PARM4] stx %sp, [%g1 + KTR_PARM5] 9: #endif wr %g4, 0, %y retry END(tl1_intr) .globl tl_text_end tl_text_end: nop /* * Freshly forked processes come here when switched to for the first time. * The arguments to fork_exit() have been setup in the locals, we must move * them to the outs. */ ENTRY(fork_trampoline) #if KTR_COMPILE & KTR_PROC CATR(KTR_PROC, "fork_trampoline: td=%p (%s) cwp=%#lx" , %g1, %g2, %g3, 7, 8, 9) ldx [PCPU(CURTHREAD)], %g2 stx %g2, [%g1 + KTR_PARM1] ldx [%g2 + TD_PROC], %g2 add %g2, P_COMM, %g2 stx %g2, [%g1 + KTR_PARM2] rdpr %cwp, %g2 stx %g2, [%g1 + KTR_PARM3] 9: #endif mov %l0, %o0 mov %l1, %o1 call fork_exit mov %l2, %o2 ba,a %xcc, tl0_ret nop END(fork_trampoline)