freebsd-nq/sys/arm/include/cpu-v6.h
Ian Lepore a66dc0c52b Include machine/acle-compat.h in cdefs.h on arm if the compiler doesn't
have ACLE support built in.  The ACLE (ARM C Language Extensions) defines
a set of standardized symbols which indicate the architecture version and
features available.  ACLE support is built in to modern compilers (both
clang and gcc), but absent from gcc prior to 4.4.

ARM (the company) provides the acle-compat.h header file to define the
right symbols for older versions of gcc.  Basically, acle-compat.h does
for arm about the same thing cdefs.h does for freebsd: defines
standardized macros that work no matter which compiler you use.  If ARM
hadn't provided this file we would have ended up with a big #ifdef __arm__
section in cdefs.h with our own compatibility shims.

Remove #include <machine/acle-compat.h> from the zillion other places (an
ever-growing list) that it appears.  Since style(9) requires sys/types.h
or sys/param.h early in the include list, and both of those lead to
including cdefs.h, only a couple special cases still need to include
acle-compat.h directly.

Loves it:     imp
2016-05-25 19:44:26 +00:00

634 lines
17 KiB
C

/*-
* Copyright 2014 Svatopluk Kraus <onwahe@gmail.com>
* Copyright 2014 Michal Meloun <meloun@miracle.cz>
* 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.
*
* $FreeBSD$
*/
#ifndef MACHINE_CPU_V6_H
#define MACHINE_CPU_V6_H
/* There are no user serviceable parts here, they may change without notice */
#ifndef _KERNEL
#error Only include this file in the kernel
#endif
#include <machine/atomic.h>
#include <machine/cpufunc.h>
#include <machine/cpuinfo.h>
#include <machine/sysreg.h>
#if __ARM_ARCH < 6
#error Only include this file for ARMv6
#else
#define CPU_ASID_KERNEL 0
void dcache_wbinv_poc_all(void); /* !!! NOT SMP coherent function !!! */
vm_offset_t dcache_wb_pou_checked(vm_offset_t, vm_size_t);
vm_offset_t icache_inv_pou_checked(vm_offset_t, vm_size_t);
#ifdef DEV_PMU
#include <sys/pcpu.h>
#define PMU_OVSR_C 0x80000000 /* Cycle Counter */
extern uint32_t ccnt_hi[MAXCPU];
extern int pmu_attched;
#endif /* DEV_PMU */
/*
* Macros to generate CP15 (system control processor) read/write functions.
*/
#define _FX(s...) #s
#define _RF0(fname, aname...) \
static __inline register_t \
fname(void) \
{ \
register_t reg; \
__asm __volatile("mrc\t" _FX(aname): "=r" (reg)); \
return(reg); \
}
#define _R64F0(fname, aname) \
static __inline uint64_t \
fname(void) \
{ \
uint64_t reg; \
__asm __volatile("mrrc\t" _FX(aname): "=r" (reg)); \
return(reg); \
}
#define _WF0(fname, aname...) \
static __inline void \
fname(void) \
{ \
__asm __volatile("mcr\t" _FX(aname)); \
}
#define _WF1(fname, aname...) \
static __inline void \
fname(register_t reg) \
{ \
__asm __volatile("mcr\t" _FX(aname):: "r" (reg)); \
}
#define _W64F1(fname, aname...) \
static __inline void \
fname(uint64_t reg) \
{ \
__asm __volatile("mcrr\t" _FX(aname):: "r" (reg)); \
}
/*
* Raw CP15 maintenance operations
* !!! not for external use !!!
*/
/* TLB */
_WF0(_CP15_TLBIALL, CP15_TLBIALL) /* Invalidate entire unified TLB */
#if __ARM_ARCH >= 7 && defined SMP
_WF0(_CP15_TLBIALLIS, CP15_TLBIALLIS) /* Invalidate entire unified TLB IS */
#endif
_WF1(_CP15_TLBIASID, CP15_TLBIASID(%0)) /* Invalidate unified TLB by ASID */
#if __ARM_ARCH >= 7 && defined SMP
_WF1(_CP15_TLBIASIDIS, CP15_TLBIASIDIS(%0)) /* Invalidate unified TLB by ASID IS */
#endif
_WF1(_CP15_TLBIMVAA, CP15_TLBIMVAA(%0)) /* Invalidate unified TLB by MVA, all ASID */
#if __ARM_ARCH >= 7 && defined SMP
_WF1(_CP15_TLBIMVAAIS, CP15_TLBIMVAAIS(%0)) /* Invalidate unified TLB by MVA, all ASID IS */
#endif
_WF1(_CP15_TLBIMVA, CP15_TLBIMVA(%0)) /* Invalidate unified TLB by MVA */
_WF1(_CP15_TTB_SET, CP15_TTBR0(%0))
/* Cache and Branch predictor */
_WF0(_CP15_BPIALL, CP15_BPIALL) /* Branch predictor invalidate all */
#if __ARM_ARCH >= 7 && defined SMP
_WF0(_CP15_BPIALLIS, CP15_BPIALLIS) /* Branch predictor invalidate all IS */
#endif
_WF1(_CP15_BPIMVA, CP15_BPIMVA(%0)) /* Branch predictor invalidate by MVA */
_WF1(_CP15_DCCIMVAC, CP15_DCCIMVAC(%0)) /* Data cache clean and invalidate by MVA PoC */
_WF1(_CP15_DCCISW, CP15_DCCISW(%0)) /* Data cache clean and invalidate by set/way */
_WF1(_CP15_DCCMVAC, CP15_DCCMVAC(%0)) /* Data cache clean by MVA PoC */
#if __ARM_ARCH >= 7
_WF1(_CP15_DCCMVAU, CP15_DCCMVAU(%0)) /* Data cache clean by MVA PoU */
#endif
_WF1(_CP15_DCCSW, CP15_DCCSW(%0)) /* Data cache clean by set/way */
_WF1(_CP15_DCIMVAC, CP15_DCIMVAC(%0)) /* Data cache invalidate by MVA PoC */
_WF1(_CP15_DCISW, CP15_DCISW(%0)) /* Data cache invalidate by set/way */
_WF0(_CP15_ICIALLU, CP15_ICIALLU) /* Instruction cache invalidate all PoU */
#if __ARM_ARCH >= 7 && defined SMP
_WF0(_CP15_ICIALLUIS, CP15_ICIALLUIS) /* Instruction cache invalidate all PoU IS */
#endif
_WF1(_CP15_ICIMVAU, CP15_ICIMVAU(%0)) /* Instruction cache invalidate */
/*
* Publicly accessible functions
*/
/* CP14 Debug Registers */
_RF0(cp14_dbgdidr_get, CP14_DBGDIDR(%0))
_RF0(cp14_dbgprsr_get, CP14_DBGPRSR(%0))
_RF0(cp14_dbgoslsr_get, CP14_DBGOSLSR(%0))
_RF0(cp14_dbgosdlr_get, CP14_DBGOSDLR(%0))
_RF0(cp14_dbgdscrint_get, CP14_DBGDSCRint(%0))
_WF1(cp14_dbgdscr_v6_set, CP14_DBGDSCRext_V6(%0))
_WF1(cp14_dbgdscr_v7_set, CP14_DBGDSCRext_V7(%0))
_WF1(cp14_dbgvcr_set, CP14_DBGVCR(%0))
_WF1(cp14_dbgoslar_set, CP14_DBGOSLAR(%0))
/* Various control registers */
_RF0(cp15_cpacr_get, CP15_CPACR(%0))
_WF1(cp15_cpacr_set, CP15_CPACR(%0))
_RF0(cp15_dfsr_get, CP15_DFSR(%0))
_RF0(cp15_ifsr_get, CP15_IFSR(%0))
_WF1(cp15_prrr_set, CP15_PRRR(%0))
_WF1(cp15_nmrr_set, CP15_NMRR(%0))
_RF0(cp15_ttbr_get, CP15_TTBR0(%0))
_RF0(cp15_dfar_get, CP15_DFAR(%0))
#if __ARM_ARCH >= 7
_RF0(cp15_ifar_get, CP15_IFAR(%0))
_RF0(cp15_l2ctlr_get, CP15_L2CTLR(%0))
#endif
_RF0(cp15_actlr_get, CP15_ACTLR(%0))
_WF1(cp15_actlr_set, CP15_ACTLR(%0))
_WF1(cp15_ats1cpr_set, CP15_ATS1CPR(%0))
_WF1(cp15_ats1cpw_set, CP15_ATS1CPW(%0))
_WF1(cp15_ats1cur_set, CP15_ATS1CUR(%0))
_WF1(cp15_ats1cuw_set, CP15_ATS1CUW(%0))
_RF0(cp15_par_get, CP15_PAR(%0))
_RF0(cp15_sctlr_get, CP15_SCTLR(%0))
/*CPU id registers */
_RF0(cp15_midr_get, CP15_MIDR(%0))
_RF0(cp15_ctr_get, CP15_CTR(%0))
_RF0(cp15_tcmtr_get, CP15_TCMTR(%0))
_RF0(cp15_tlbtr_get, CP15_TLBTR(%0))
_RF0(cp15_mpidr_get, CP15_MPIDR(%0))
_RF0(cp15_revidr_get, CP15_REVIDR(%0))
_RF0(cp15_ccsidr_get, CP15_CCSIDR(%0))
_RF0(cp15_clidr_get, CP15_CLIDR(%0))
_RF0(cp15_aidr_get, CP15_AIDR(%0))
_WF1(cp15_csselr_set, CP15_CSSELR(%0))
_RF0(cp15_id_pfr0_get, CP15_ID_PFR0(%0))
_RF0(cp15_id_pfr1_get, CP15_ID_PFR1(%0))
_RF0(cp15_id_dfr0_get, CP15_ID_DFR0(%0))
_RF0(cp15_id_afr0_get, CP15_ID_AFR0(%0))
_RF0(cp15_id_mmfr0_get, CP15_ID_MMFR0(%0))
_RF0(cp15_id_mmfr1_get, CP15_ID_MMFR1(%0))
_RF0(cp15_id_mmfr2_get, CP15_ID_MMFR2(%0))
_RF0(cp15_id_mmfr3_get, CP15_ID_MMFR3(%0))
_RF0(cp15_id_isar0_get, CP15_ID_ISAR0(%0))
_RF0(cp15_id_isar1_get, CP15_ID_ISAR1(%0))
_RF0(cp15_id_isar2_get, CP15_ID_ISAR2(%0))
_RF0(cp15_id_isar3_get, CP15_ID_ISAR3(%0))
_RF0(cp15_id_isar4_get, CP15_ID_ISAR4(%0))
_RF0(cp15_id_isar5_get, CP15_ID_ISAR5(%0))
_RF0(cp15_cbar_get, CP15_CBAR(%0))
/* Performance Monitor registers */
#if __ARM_ARCH == 6 && defined(CPU_ARM1176)
_RF0(cp15_pmuserenr_get, CP15_PMUSERENR(%0))
_WF1(cp15_pmuserenr_set, CP15_PMUSERENR(%0))
_RF0(cp15_pmcr_get, CP15_PMCR(%0))
_WF1(cp15_pmcr_set, CP15_PMCR(%0))
_RF0(cp15_pmccntr_get, CP15_PMCCNTR(%0))
_WF1(cp15_pmccntr_set, CP15_PMCCNTR(%0))
#elif __ARM_ARCH > 6
_RF0(cp15_pmcr_get, CP15_PMCR(%0))
_WF1(cp15_pmcr_set, CP15_PMCR(%0))
_RF0(cp15_pmcnten_get, CP15_PMCNTENSET(%0))
_WF1(cp15_pmcnten_set, CP15_PMCNTENSET(%0))
_WF1(cp15_pmcnten_clr, CP15_PMCNTENCLR(%0))
_RF0(cp15_pmovsr_get, CP15_PMOVSR(%0))
_WF1(cp15_pmovsr_set, CP15_PMOVSR(%0))
_WF1(cp15_pmswinc_set, CP15_PMSWINC(%0))
_RF0(cp15_pmselr_get, CP15_PMSELR(%0))
_WF1(cp15_pmselr_set, CP15_PMSELR(%0))
_RF0(cp15_pmccntr_get, CP15_PMCCNTR(%0))
_WF1(cp15_pmccntr_set, CP15_PMCCNTR(%0))
_RF0(cp15_pmxevtyper_get, CP15_PMXEVTYPER(%0))
_WF1(cp15_pmxevtyper_set, CP15_PMXEVTYPER(%0))
_RF0(cp15_pmxevcntr_get, CP15_PMXEVCNTRR(%0))
_WF1(cp15_pmxevcntr_set, CP15_PMXEVCNTRR(%0))
_RF0(cp15_pmuserenr_get, CP15_PMUSERENR(%0))
_WF1(cp15_pmuserenr_set, CP15_PMUSERENR(%0))
_RF0(cp15_pminten_get, CP15_PMINTENSET(%0))
_WF1(cp15_pminten_set, CP15_PMINTENSET(%0))
_WF1(cp15_pminten_clr, CP15_PMINTENCLR(%0))
#endif
_RF0(cp15_tpidrurw_get, CP15_TPIDRURW(%0))
_WF1(cp15_tpidrurw_set, CP15_TPIDRURW(%0))
_RF0(cp15_tpidruro_get, CP15_TPIDRURO(%0))
_WF1(cp15_tpidruro_set, CP15_TPIDRURO(%0))
_RF0(cp15_tpidrpwr_get, CP15_TPIDRPRW(%0))
_WF1(cp15_tpidrpwr_set, CP15_TPIDRPRW(%0))
/* Generic Timer registers - only use when you know the hardware is available */
_RF0(cp15_cntfrq_get, CP15_CNTFRQ(%0))
_WF1(cp15_cntfrq_set, CP15_CNTFRQ(%0))
_RF0(cp15_cntkctl_get, CP15_CNTKCTL(%0))
_WF1(cp15_cntkctl_set, CP15_CNTKCTL(%0))
_RF0(cp15_cntp_tval_get, CP15_CNTP_TVAL(%0))
_WF1(cp15_cntp_tval_set, CP15_CNTP_TVAL(%0))
_RF0(cp15_cntp_ctl_get, CP15_CNTP_CTL(%0))
_WF1(cp15_cntp_ctl_set, CP15_CNTP_CTL(%0))
_RF0(cp15_cntv_tval_get, CP15_CNTV_TVAL(%0))
_WF1(cp15_cntv_tval_set, CP15_CNTV_TVAL(%0))
_RF0(cp15_cntv_ctl_get, CP15_CNTV_CTL(%0))
_WF1(cp15_cntv_ctl_set, CP15_CNTV_CTL(%0))
_RF0(cp15_cnthctl_get, CP15_CNTHCTL(%0))
_WF1(cp15_cnthctl_set, CP15_CNTHCTL(%0))
_RF0(cp15_cnthp_tval_get, CP15_CNTHP_TVAL(%0))
_WF1(cp15_cnthp_tval_set, CP15_CNTHP_TVAL(%0))
_RF0(cp15_cnthp_ctl_get, CP15_CNTHP_CTL(%0))
_WF1(cp15_cnthp_ctl_set, CP15_CNTHP_CTL(%0))
_R64F0(cp15_cntpct_get, CP15_CNTPCT(%Q0, %R0))
_R64F0(cp15_cntvct_get, CP15_CNTVCT(%Q0, %R0))
_R64F0(cp15_cntp_cval_get, CP15_CNTP_CVAL(%Q0, %R0))
_W64F1(cp15_cntp_cval_set, CP15_CNTP_CVAL(%Q0, %R0))
_R64F0(cp15_cntv_cval_get, CP15_CNTV_CVAL(%Q0, %R0))
_W64F1(cp15_cntv_cval_set, CP15_CNTV_CVAL(%Q0, %R0))
_R64F0(cp15_cntvoff_get, CP15_CNTVOFF(%Q0, %R0))
_W64F1(cp15_cntvoff_set, CP15_CNTVOFF(%Q0, %R0))
_R64F0(cp15_cnthp_cval_get, CP15_CNTHP_CVAL(%Q0, %R0))
_W64F1(cp15_cnthp_cval_set, CP15_CNTHP_CVAL(%Q0, %R0))
#undef _FX
#undef _RF0
#undef _WF0
#undef _WF1
/*
* TLB maintenance operations.
*/
/* Local (i.e. not broadcasting ) operations. */
/* Flush all TLB entries (even global). */
static __inline void
tlb_flush_all_local(void)
{
dsb();
_CP15_TLBIALL();
dsb();
}
/* Flush all not global TLB entries. */
static __inline void
tlb_flush_all_ng_local(void)
{
dsb();
_CP15_TLBIASID(CPU_ASID_KERNEL);
dsb();
}
/* Flush single TLB entry (even global). */
static __inline void
tlb_flush_local(vm_offset_t va)
{
KASSERT((va & PAGE_MASK) == 0, ("%s: va %#x not aligned", __func__, va));
dsb();
_CP15_TLBIMVA(va | CPU_ASID_KERNEL);
dsb();
}
/* Flush range of TLB entries (even global). */
static __inline void
tlb_flush_range_local(vm_offset_t va, vm_size_t size)
{
vm_offset_t eva = va + size;
KASSERT((va & PAGE_MASK) == 0, ("%s: va %#x not aligned", __func__, va));
KASSERT((size & PAGE_MASK) == 0, ("%s: size %#x not aligned", __func__,
size));
dsb();
for (; va < eva; va += PAGE_SIZE)
_CP15_TLBIMVA(va | CPU_ASID_KERNEL);
dsb();
}
/* Broadcasting operations. */
#if __ARM_ARCH >= 7 && defined SMP
static __inline void
tlb_flush_all(void)
{
dsb();
_CP15_TLBIALLIS();
dsb();
}
static __inline void
tlb_flush_all_ng(void)
{
dsb();
_CP15_TLBIASIDIS(CPU_ASID_KERNEL);
dsb();
}
static __inline void
tlb_flush(vm_offset_t va)
{
KASSERT((va & PAGE_MASK) == 0, ("%s: va %#x not aligned", __func__, va));
dsb();
_CP15_TLBIMVAAIS(va);
dsb();
}
static __inline void
tlb_flush_range(vm_offset_t va, vm_size_t size)
{
vm_offset_t eva = va + size;
KASSERT((va & PAGE_MASK) == 0, ("%s: va %#x not aligned", __func__, va));
KASSERT((size & PAGE_MASK) == 0, ("%s: size %#x not aligned", __func__,
size));
dsb();
for (; va < eva; va += PAGE_SIZE)
_CP15_TLBIMVAAIS(va);
dsb();
}
#else /* SMP */
#define tlb_flush_all() tlb_flush_all_local()
#define tlb_flush_all_ng() tlb_flush_all_ng_local()
#define tlb_flush(va) tlb_flush_local(va)
#define tlb_flush_range(va, size) tlb_flush_range_local(va, size)
#endif /* SMP */
/*
* Cache maintenance operations.
*/
/* Sync I and D caches to PoU */
static __inline void
icache_sync(vm_offset_t va, vm_size_t size)
{
vm_offset_t eva = va + size;
dsb();
va &= ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
#if __ARM_ARCH >= 7 && defined SMP
_CP15_DCCMVAU(va);
#else
_CP15_DCCMVAC(va);
#endif
}
dsb();
#if __ARM_ARCH >= 7 && defined SMP
_CP15_ICIALLUIS();
#else
_CP15_ICIALLU();
#endif
dsb();
isb();
}
/* Invalidate I cache */
static __inline void
icache_inv_all(void)
{
#if __ARM_ARCH >= 7 && defined SMP
_CP15_ICIALLUIS();
#else
_CP15_ICIALLU();
#endif
dsb();
isb();
}
/* Invalidate branch predictor buffer */
static __inline void
bpb_inv_all(void)
{
#if __ARM_ARCH >= 7 && defined SMP
_CP15_BPIALLIS();
#else
_CP15_BPIALL();
#endif
dsb();
isb();
}
/* Write back D-cache to PoU */
static __inline void
dcache_wb_pou(vm_offset_t va, vm_size_t size)
{
vm_offset_t eva = va + size;
dsb();
va &= ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
#if __ARM_ARCH >= 7 && defined SMP
_CP15_DCCMVAU(va);
#else
_CP15_DCCMVAC(va);
#endif
}
dsb();
}
/*
* Invalidate D-cache to PoC
*
* Caches are invalidated from outermost to innermost as fresh cachelines
* flow in this direction. In given range, if there was no dirty cacheline
* in any cache before, no stale cacheline should remain in them after this
* operation finishes.
*/
static __inline void
dcache_inv_poc(vm_offset_t va, vm_paddr_t pa, vm_size_t size)
{
vm_offset_t eva = va + size;
dsb();
/* invalidate L2 first */
cpu_l2cache_inv_range(pa, size);
/* then L1 */
va &= ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
_CP15_DCIMVAC(va);
}
dsb();
}
/*
* Discard D-cache lines to PoC, prior to overwrite by DMA engine.
*
* Normal invalidation does L2 then L1 to ensure that stale data from L2 doesn't
* flow into L1 while invalidating. This routine is intended to be used only
* when invalidating a buffer before a DMA operation loads new data into memory.
* The concern in this case is that dirty lines are not evicted to main memory,
* overwriting the DMA data. For that reason, the L1 is done first to ensure
* that an evicted L1 line doesn't flow to L2 after the L2 has been cleaned.
*/
static __inline void
dcache_inv_poc_dma(vm_offset_t va, vm_paddr_t pa, vm_size_t size)
{
vm_offset_t eva = va + size;
/* invalidate L1 first */
dsb();
va &= ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
_CP15_DCIMVAC(va);
}
dsb();
/* then L2 */
cpu_l2cache_inv_range(pa, size);
}
/*
* Write back D-cache to PoC
*
* Caches are written back from innermost to outermost as dirty cachelines
* flow in this direction. In given range, no dirty cacheline should remain
* in any cache after this operation finishes.
*/
static __inline void
dcache_wb_poc(vm_offset_t va, vm_paddr_t pa, vm_size_t size)
{
vm_offset_t eva = va + size;
dsb();
va &= ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
_CP15_DCCMVAC(va);
}
dsb();
cpu_l2cache_wb_range(pa, size);
}
/* Write back and invalidate D-cache to PoC */
static __inline void
dcache_wbinv_poc(vm_offset_t sva, vm_paddr_t pa, vm_size_t size)
{
vm_offset_t va;
vm_offset_t eva = sva + size;
dsb();
/* write back L1 first */
va = sva & ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
_CP15_DCCMVAC(va);
}
dsb();
/* then write back and invalidate L2 */
cpu_l2cache_wbinv_range(pa, size);
/* then invalidate L1 */
va = sva & ~cpuinfo.dcache_line_mask;
for ( ; va < eva; va += cpuinfo.dcache_line_size) {
_CP15_DCIMVAC(va);
}
dsb();
}
/* Set TTB0 register */
static __inline void
cp15_ttbr_set(uint32_t reg)
{
dsb();
_CP15_TTB_SET(reg);
dsb();
_CP15_BPIALL();
dsb();
isb();
tlb_flush_all_ng_local();
}
/*
* Functions for address checking:
*
* cp15_ats1cpr_check() ... check stage 1 privileged (PL1) read access
* cp15_ats1cpw_check() ... check stage 1 privileged (PL1) write access
* cp15_ats1cur_check() ... check stage 1 unprivileged (PL0) read access
* cp15_ats1cuw_check() ... check stage 1 unprivileged (PL0) write access
*
* They must be called while interrupts are disabled to get consistent result.
*/
static __inline int
cp15_ats1cpr_check(vm_offset_t addr)
{
cp15_ats1cpr_set(addr);
isb();
return (cp15_par_get() & 0x01 ? EFAULT : 0);
}
static __inline int
cp15_ats1cpw_check(vm_offset_t addr)
{
cp15_ats1cpw_set(addr);
isb();
return (cp15_par_get() & 0x01 ? EFAULT : 0);
}
static __inline int
cp15_ats1cur_check(vm_offset_t addr)
{
cp15_ats1cur_set(addr);
isb();
return (cp15_par_get() & 0x01 ? EFAULT : 0);
}
static __inline int
cp15_ats1cuw_check(vm_offset_t addr)
{
cp15_ats1cuw_set(addr);
isb();
return (cp15_par_get() & 0x01 ? EFAULT : 0);
}
#endif /* !__ARM_ARCH < 6 */
#endif /* !MACHINE_CPU_V6_H */