kernel-fxtec-pro1x/drivers/misc/sgi-gru/grutables.h
Jack Steiner eb5bd5e52a gru: update gru kernel self tests
Change the kernel self tests that can be optionally executed on GRU
initialization.  This is primarily for testing.

Eliminate the BUG statements on failure and return bad status.  Add ioctl
interface to execute the tests on demand.

Signed-off-by: Jack Steiner <steiner@sgi.com>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2009-06-18 13:04:02 -07:00

670 lines
22 KiB
C

/*
* SN Platform GRU Driver
*
* GRU DRIVER TABLES, MACROS, externs, etc
*
* Copyright (c) 2008 Silicon Graphics, Inc. All Rights Reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#ifndef __GRUTABLES_H__
#define __GRUTABLES_H__
/*
* GRU Chiplet:
* The GRU is a user addressible memory accelerator. It provides
* several forms of load, store, memset, bcopy instructions. In addition, it
* contains special instructions for AMOs, sending messages to message
* queues, etc.
*
* The GRU is an integral part of the node controller. It connects
* directly to the cpu socket. In its current implementation, there are 2
* GRU chiplets in the node controller on each blade (~node).
*
* The entire GRU memory space is fully coherent and cacheable by the cpus.
*
* Each GRU chiplet has a physical memory map that looks like the following:
*
* +-----------------+
* |/////////////////|
* |/////////////////|
* |/////////////////|
* |/////////////////|
* |/////////////////|
* |/////////////////|
* |/////////////////|
* |/////////////////|
* +-----------------+
* | system control |
* +-----------------+ _______ +-------------+
* |/////////////////| / | |
* |/////////////////| / | |
* |/////////////////| / | instructions|
* |/////////////////| / | |
* |/////////////////| / | |
* |/////////////////| / |-------------|
* |/////////////////| / | |
* +-----------------+ | |
* | context 15 | | data |
* +-----------------+ | |
* | ...... | \ | |
* +-----------------+ \____________ +-------------+
* | context 1 |
* +-----------------+
* | context 0 |
* +-----------------+
*
* Each of the "contexts" is a chunk of memory that can be mmaped into user
* space. The context consists of 2 parts:
*
* - an instruction space that can be directly accessed by the user
* to issue GRU instructions and to check instruction status.
*
* - a data area that acts as normal RAM.
*
* User instructions contain virtual addresses of data to be accessed by the
* GRU. The GRU contains a TLB that is used to convert these user virtual
* addresses to physical addresses.
*
* The "system control" area of the GRU chiplet is used by the kernel driver
* to manage user contexts and to perform functions such as TLB dropin and
* purging.
*
* One context may be reserved for the kernel and used for cross-partition
* communication. The GRU will also be used to asynchronously zero out
* large blocks of memory (not currently implemented).
*
*
* Tables:
*
* VDATA-VMA Data - Holds a few parameters. Head of linked list of
* GTS tables for threads using the GSEG
* GTS - Gru Thread State - contains info for managing a GSEG context. A
* GTS is allocated for each thread accessing a
* GSEG.
* GTD - GRU Thread Data - contains shadow copy of GRU data when GSEG is
* not loaded into a GRU
* GMS - GRU Memory Struct - Used to manage TLB shootdowns. Tracks GRUs
* where a GSEG has been loaded. Similar to
* an mm_struct but for GRU.
*
* GS - GRU State - Used to manage the state of a GRU chiplet
* BS - Blade State - Used to manage state of all GRU chiplets
* on a blade
*
*
* Normal task tables for task using GRU.
* - 2 threads in process
* - 2 GSEGs open in process
* - GSEG1 is being used by both threads
* - GSEG2 is used only by thread 2
*
* task -->|
* task ---+---> mm ->------ (notifier) -------+-> gms
* | |
* |--> vma -> vdata ---> gts--->| GSEG1 (thread1)
* | | |
* | +-> gts--->| GSEG1 (thread2)
* | |
* |--> vma -> vdata ---> gts--->| GSEG2 (thread2)
* .
* .
*
* GSEGs are marked DONTCOPY on fork
*
* At open
* file.private_data -> NULL
*
* At mmap,
* vma -> vdata
*
* After gseg reference
* vma -> vdata ->gts
*
* After fork
* parent
* vma -> vdata -> gts
* child
* (vma is not copied)
*
*/
#include <linux/rmap.h>
#include <linux/interrupt.h>
#include <linux/mutex.h>
#include <linux/wait.h>
#include <linux/mmu_notifier.h>
#include "gru.h"
#include "gruhandles.h"
extern struct gru_stats_s gru_stats;
extern struct gru_blade_state *gru_base[];
extern unsigned long gru_start_paddr, gru_end_paddr;
extern unsigned int gru_max_gids;
#define GRU_MAX_BLADES MAX_NUMNODES
#define GRU_MAX_GRUS (GRU_MAX_BLADES * GRU_CHIPLETS_PER_BLADE)
#define GRU_DRIVER_ID_STR "SGI GRU Device Driver"
#define GRU_DRIVER_VERSION_STR "0.80"
/*
* GRU statistics.
*/
struct gru_stats_s {
atomic_long_t vdata_alloc;
atomic_long_t vdata_free;
atomic_long_t gts_alloc;
atomic_long_t gts_free;
atomic_long_t vdata_double_alloc;
atomic_long_t gts_double_allocate;
atomic_long_t assign_context;
atomic_long_t assign_context_failed;
atomic_long_t free_context;
atomic_long_t load_user_context;
atomic_long_t load_kernel_context;
atomic_long_t lock_kernel_context;
atomic_long_t unlock_kernel_context;
atomic_long_t steal_user_context;
atomic_long_t steal_kernel_context;
atomic_long_t steal_context_failed;
atomic_long_t nopfn;
atomic_long_t break_cow;
atomic_long_t asid_new;
atomic_long_t asid_next;
atomic_long_t asid_wrap;
atomic_long_t asid_reuse;
atomic_long_t intr;
atomic_long_t intr_mm_lock_failed;
atomic_long_t call_os;
atomic_long_t call_os_offnode_reference;
atomic_long_t call_os_check_for_bug;
atomic_long_t call_os_wait_queue;
atomic_long_t user_flush_tlb;
atomic_long_t user_unload_context;
atomic_long_t user_exception;
atomic_long_t set_task_slice;
atomic_long_t migrate_check;
atomic_long_t migrated_retarget;
atomic_long_t migrated_unload;
atomic_long_t migrated_unload_delay;
atomic_long_t migrated_nopfn_retarget;
atomic_long_t migrated_nopfn_unload;
atomic_long_t tlb_dropin;
atomic_long_t tlb_dropin_fail_no_asid;
atomic_long_t tlb_dropin_fail_upm;
atomic_long_t tlb_dropin_fail_invalid;
atomic_long_t tlb_dropin_fail_range_active;
atomic_long_t tlb_dropin_fail_idle;
atomic_long_t tlb_dropin_fail_fmm;
atomic_long_t tlb_dropin_fail_no_exception;
atomic_long_t tlb_dropin_fail_no_exception_war;
atomic_long_t mmu_invalidate_range;
atomic_long_t mmu_invalidate_page;
atomic_long_t mmu_clear_flush_young;
atomic_long_t flush_tlb;
atomic_long_t flush_tlb_gru;
atomic_long_t flush_tlb_gru_tgh;
atomic_long_t flush_tlb_gru_zero_asid;
atomic_long_t copy_gpa;
atomic_long_t mesq_receive;
atomic_long_t mesq_receive_none;
atomic_long_t mesq_send;
atomic_long_t mesq_send_failed;
atomic_long_t mesq_noop;
atomic_long_t mesq_send_unexpected_error;
atomic_long_t mesq_send_lb_overflow;
atomic_long_t mesq_send_qlimit_reached;
atomic_long_t mesq_send_amo_nacked;
atomic_long_t mesq_send_put_nacked;
atomic_long_t mesq_qf_not_full;
atomic_long_t mesq_qf_locked;
atomic_long_t mesq_qf_noop_not_full;
atomic_long_t mesq_qf_switch_head_failed;
atomic_long_t mesq_qf_unexpected_error;
atomic_long_t mesq_noop_unexpected_error;
atomic_long_t mesq_noop_lb_overflow;
atomic_long_t mesq_noop_qlimit_reached;
atomic_long_t mesq_noop_amo_nacked;
atomic_long_t mesq_noop_put_nacked;
};
enum mcs_op {cchop_allocate, cchop_start, cchop_interrupt, cchop_interrupt_sync,
cchop_deallocate, tghop_invalidate, mcsop_last};
struct mcs_op_statistic {
atomic_long_t count;
atomic_long_t total;
unsigned long max;
};
extern struct mcs_op_statistic mcs_op_statistics[mcsop_last];
#define OPT_DPRINT 1
#define OPT_STATS 2
#define IRQ_GRU 110 /* Starting IRQ number for interrupts */
/* Delay in jiffies between attempts to assign a GRU context */
#define GRU_ASSIGN_DELAY ((HZ * 20) / 1000)
/*
* If a process has it's context stolen, min delay in jiffies before trying to
* steal a context from another process.
*/
#define GRU_STEAL_DELAY ((HZ * 200) / 1000)
#define STAT(id) do { \
if (gru_options & OPT_STATS) \
atomic_long_inc(&gru_stats.id); \
} while (0)
#ifdef CONFIG_SGI_GRU_DEBUG
#define gru_dbg(dev, fmt, x...) \
do { \
if (gru_options & OPT_DPRINT) \
dev_dbg(dev, "%s: " fmt, __func__, x); \
} while (0)
#else
#define gru_dbg(x...)
#endif
/*-----------------------------------------------------------------------------
* ASID management
*/
#define MAX_ASID 0xfffff0
#define MIN_ASID 8
#define ASID_INC 8 /* number of regions */
/* Generate a GRU asid value from a GRU base asid & a virtual address. */
#if defined CONFIG_IA64
#define VADDR_HI_BIT 64
#elif defined CONFIG_X86_64
#define VADDR_HI_BIT 48
#else
#error "Unsupported architecture"
#endif
#define GRUREGION(addr) ((addr) >> (VADDR_HI_BIT - 3) & 3)
#define GRUASID(asid, addr) ((asid) + GRUREGION(addr))
/*------------------------------------------------------------------------------
* File & VMS Tables
*/
struct gru_state;
/*
* This structure is pointed to from the mmstruct via the notifier pointer.
* There is one of these per address space.
*/
struct gru_mm_tracker { /* pack to reduce size */
unsigned int mt_asid_gen:24; /* ASID wrap count */
unsigned int mt_asid:24; /* current base ASID for gru */
unsigned short mt_ctxbitmap:16;/* bitmap of contexts using
asid */
} __attribute__ ((packed));
struct gru_mm_struct {
struct mmu_notifier ms_notifier;
atomic_t ms_refcnt;
spinlock_t ms_asid_lock; /* protects ASID assignment */
atomic_t ms_range_active;/* num range_invals active */
char ms_released;
wait_queue_head_t ms_wait_queue;
DECLARE_BITMAP(ms_asidmap, GRU_MAX_GRUS);
struct gru_mm_tracker ms_asids[GRU_MAX_GRUS];
};
/*
* One of these structures is allocated when a GSEG is mmaped. The
* structure is pointed to by the vma->vm_private_data field in the vma struct.
*/
struct gru_vma_data {
spinlock_t vd_lock; /* Serialize access to vma */
struct list_head vd_head; /* head of linked list of gts */
long vd_user_options;/* misc user option flags */
int vd_cbr_au_count;
int vd_dsr_au_count;
};
/*
* One of these is allocated for each thread accessing a mmaped GRU. A linked
* list of these structure is hung off the struct gru_vma_data in the mm_struct.
*/
struct gru_thread_state {
struct list_head ts_next; /* list - head at vma-private */
struct mutex ts_ctxlock; /* load/unload CTX lock */
struct mm_struct *ts_mm; /* mm currently mapped to
context */
struct vm_area_struct *ts_vma; /* vma of GRU context */
struct gru_state *ts_gru; /* GRU where the context is
loaded */
struct gru_mm_struct *ts_gms; /* asid & ioproc struct */
unsigned long ts_cbr_map; /* map of allocated CBRs */
unsigned long ts_dsr_map; /* map of allocated DATA
resources */
unsigned long ts_steal_jiffies;/* jiffies when context last
stolen */
long ts_user_options;/* misc user option flags */
pid_t ts_tgid_owner; /* task that is using the
context - for migration */
unsigned short ts_sizeavail; /* Pagesizes in use */
int ts_tsid; /* thread that owns the
structure */
int ts_tlb_int_select;/* target cpu if interrupts
enabled */
int ts_ctxnum; /* context number where the
context is loaded */
atomic_t ts_refcnt; /* reference count GTS */
unsigned char ts_dsr_au_count;/* Number of DSR resources
required for contest */
unsigned char ts_cbr_au_count;/* Number of CBR resources
required for contest */
char ts_blade; /* If >= 0, migrate context if
ref from diferent blade */
char ts_force_cch_reload;
char ts_force_unload;/* force context to be unloaded
after migration */
char ts_cbr_idx[GRU_CBR_AU];/* CBR numbers of each
allocated CB */
int ts_data_valid; /* Indicates if ts_gdata has
valid data */
unsigned long ts_gdata[0]; /* save area for GRU data (CB,
DS, CBE) */
};
/*
* Threaded programs actually allocate an array of GSEGs when a context is
* created. Each thread uses a separate GSEG. TSID is the index into the GSEG
* array.
*/
#define TSID(a, v) (((a) - (v)->vm_start) / GRU_GSEG_PAGESIZE)
#define UGRUADDR(gts) ((gts)->ts_vma->vm_start + \
(gts)->ts_tsid * GRU_GSEG_PAGESIZE)
#define NULLCTX (-1) /* if context not loaded into GRU */
/*-----------------------------------------------------------------------------
* GRU State Tables
*/
/*
* One of these exists for each GRU chiplet.
*/
struct gru_state {
struct gru_blade_state *gs_blade; /* GRU state for entire
blade */
unsigned long gs_gru_base_paddr; /* Physical address of
gru segments (64) */
void *gs_gru_base_vaddr; /* Virtual address of
gru segments (64) */
unsigned short gs_gid; /* unique GRU number */
unsigned short gs_blade_id; /* blade of GRU */
unsigned char gs_tgh_local_shift; /* used to pick TGH for
local flush */
unsigned char gs_tgh_first_remote; /* starting TGH# for
remote flush */
spinlock_t gs_asid_lock; /* lock used for
assigning asids */
spinlock_t gs_lock; /* lock used for
assigning contexts */
/* -- the following are protected by the gs_asid_lock spinlock ---- */
unsigned int gs_asid; /* Next availe ASID */
unsigned int gs_asid_limit; /* Limit of available
ASIDs */
unsigned int gs_asid_gen; /* asid generation.
Inc on wrap */
/* --- the following fields are protected by the gs_lock spinlock --- */
unsigned long gs_context_map; /* bitmap to manage
contexts in use */
unsigned long gs_cbr_map; /* bitmap to manage CB
resources */
unsigned long gs_dsr_map; /* bitmap used to manage
DATA resources */
unsigned int gs_reserved_cbrs; /* Number of kernel-
reserved cbrs */
unsigned int gs_reserved_dsr_bytes; /* Bytes of kernel-
reserved dsrs */
unsigned short gs_active_contexts; /* number of contexts
in use */
struct gru_thread_state *gs_gts[GRU_NUM_CCH]; /* GTS currently using
the context */
};
/*
* This structure contains the GRU state for all the GRUs on a blade.
*/
struct gru_blade_state {
void *kernel_cb; /* First kernel
reserved cb */
void *kernel_dsr; /* First kernel
reserved DSR */
struct rw_semaphore bs_kgts_sema; /* lock for kgts */
struct gru_thread_state *bs_kgts; /* GTS for kernel use */
/* ---- the following are used for managing kernel async GRU CBRs --- */
int bs_async_dsr_bytes; /* DSRs for async */
int bs_async_cbrs; /* CBRs AU for async */
struct completion *bs_async_wq;
/* ---- the following are protected by the bs_lock spinlock ---- */
spinlock_t bs_lock; /* lock used for
stealing contexts */
int bs_lru_ctxnum; /* STEAL - last context
stolen */
struct gru_state *bs_lru_gru; /* STEAL - last gru
stolen */
struct gru_state bs_grus[GRU_CHIPLETS_PER_BLADE];
};
/*-----------------------------------------------------------------------------
* Address Primitives
*/
#define get_tfm_for_cpu(g, c) \
((struct gru_tlb_fault_map *)get_tfm((g)->gs_gru_base_vaddr, (c)))
#define get_tfh_by_index(g, i) \
((struct gru_tlb_fault_handle *)get_tfh((g)->gs_gru_base_vaddr, (i)))
#define get_tgh_by_index(g, i) \
((struct gru_tlb_global_handle *)get_tgh((g)->gs_gru_base_vaddr, (i)))
#define get_cbe_by_index(g, i) \
((struct gru_control_block_extended *)get_cbe((g)->gs_gru_base_vaddr,\
(i)))
/*-----------------------------------------------------------------------------
* Useful Macros
*/
/* Given a blade# & chiplet#, get a pointer to the GRU */
#define get_gru(b, c) (&gru_base[b]->bs_grus[c])
/* Number of bytes to save/restore when unloading/loading GRU contexts */
#define DSR_BYTES(dsr) ((dsr) * GRU_DSR_AU_BYTES)
#define CBR_BYTES(cbr) ((cbr) * GRU_HANDLE_BYTES * GRU_CBR_AU_SIZE * 2)
/* Convert a user CB number to the actual CBRNUM */
#define thread_cbr_number(gts, n) ((gts)->ts_cbr_idx[(n) / GRU_CBR_AU_SIZE] \
* GRU_CBR_AU_SIZE + (n) % GRU_CBR_AU_SIZE)
/* Convert a gid to a pointer to the GRU */
#define GID_TO_GRU(gid) \
(gru_base[(gid) / GRU_CHIPLETS_PER_BLADE] ? \
(&gru_base[(gid) / GRU_CHIPLETS_PER_BLADE]-> \
bs_grus[(gid) % GRU_CHIPLETS_PER_BLADE]) : \
NULL)
/* Scan all active GRUs in a GRU bitmap */
#define for_each_gru_in_bitmap(gid, map) \
for ((gid) = find_first_bit((map), GRU_MAX_GRUS); (gid) < GRU_MAX_GRUS;\
(gid)++, (gid) = find_next_bit((map), GRU_MAX_GRUS, (gid)))
/* Scan all active GRUs on a specific blade */
#define for_each_gru_on_blade(gru, nid, i) \
for ((gru) = gru_base[nid]->bs_grus, (i) = 0; \
(i) < GRU_CHIPLETS_PER_BLADE; \
(i)++, (gru)++)
/* Scan all GRUs */
#define foreach_gid(gid) \
for ((gid) = 0; (gid) < gru_max_gids; (gid)++)
/* Scan all active GTSs on a gru. Note: must hold ss_lock to use this macro. */
#define for_each_gts_on_gru(gts, gru, ctxnum) \
for ((ctxnum) = 0; (ctxnum) < GRU_NUM_CCH; (ctxnum)++) \
if (((gts) = (gru)->gs_gts[ctxnum]))
/* Scan each CBR whose bit is set in a TFM (or copy of) */
#define for_each_cbr_in_tfm(i, map) \
for ((i) = find_first_bit(map, GRU_NUM_CBE); \
(i) < GRU_NUM_CBE; \
(i)++, (i) = find_next_bit(map, GRU_NUM_CBE, i))
/* Scan each CBR in a CBR bitmap. Note: multiple CBRs in an allocation unit */
#define for_each_cbr_in_allocation_map(i, map, k) \
for ((k) = find_first_bit(map, GRU_CBR_AU); (k) < GRU_CBR_AU; \
(k) = find_next_bit(map, GRU_CBR_AU, (k) + 1)) \
for ((i) = (k)*GRU_CBR_AU_SIZE; \
(i) < ((k) + 1) * GRU_CBR_AU_SIZE; (i)++)
/* Scan each DSR in a DSR bitmap. Note: multiple DSRs in an allocation unit */
#define for_each_dsr_in_allocation_map(i, map, k) \
for ((k) = find_first_bit((const unsigned long *)map, GRU_DSR_AU);\
(k) < GRU_DSR_AU; \
(k) = find_next_bit((const unsigned long *)map, \
GRU_DSR_AU, (k) + 1)) \
for ((i) = (k) * GRU_DSR_AU_CL; \
(i) < ((k) + 1) * GRU_DSR_AU_CL; (i)++)
#define gseg_physical_address(gru, ctxnum) \
((gru)->gs_gru_base_paddr + ctxnum * GRU_GSEG_STRIDE)
#define gseg_virtual_address(gru, ctxnum) \
((gru)->gs_gru_base_vaddr + ctxnum * GRU_GSEG_STRIDE)
/*-----------------------------------------------------------------------------
* Lock / Unlock GRU handles
* Use the "delresp" bit in the handle as a "lock" bit.
*/
/* Lock hierarchy checking enabled only in emulator */
/* 0 = lock failed, 1 = locked */
static inline int __trylock_handle(void *h)
{
return !test_and_set_bit(1, h);
}
static inline void __lock_handle(void *h)
{
while (test_and_set_bit(1, h))
cpu_relax();
}
static inline void __unlock_handle(void *h)
{
clear_bit(1, h);
}
static inline int trylock_cch_handle(struct gru_context_configuration_handle *cch)
{
return __trylock_handle(cch);
}
static inline void lock_cch_handle(struct gru_context_configuration_handle *cch)
{
__lock_handle(cch);
}
static inline void unlock_cch_handle(struct gru_context_configuration_handle
*cch)
{
__unlock_handle(cch);
}
static inline void lock_tgh_handle(struct gru_tlb_global_handle *tgh)
{
__lock_handle(tgh);
}
static inline void unlock_tgh_handle(struct gru_tlb_global_handle *tgh)
{
__unlock_handle(tgh);
}
static inline int is_kernel_context(struct gru_thread_state *gts)
{
return !gts->ts_mm;
}
/*-----------------------------------------------------------------------------
* Function prototypes & externs
*/
struct gru_unload_context_req;
extern struct vm_operations_struct gru_vm_ops;
extern struct device *grudev;
extern struct gru_vma_data *gru_alloc_vma_data(struct vm_area_struct *vma,
int tsid);
extern struct gru_thread_state *gru_find_thread_state(struct vm_area_struct
*vma, int tsid);
extern struct gru_thread_state *gru_alloc_thread_state(struct vm_area_struct
*vma, int tsid);
extern struct gru_state *gru_assign_gru_context(struct gru_thread_state *gts,
int blade);
extern void gru_load_context(struct gru_thread_state *gts);
extern void gru_steal_context(struct gru_thread_state *gts, int blade_id);
extern void gru_unload_context(struct gru_thread_state *gts, int savestate);
extern int gru_update_cch(struct gru_thread_state *gts, int force_unload);
extern void gts_drop(struct gru_thread_state *gts);
extern void gru_tgh_flush_init(struct gru_state *gru);
extern int gru_kservices_init(struct gru_state *gru);
extern void gru_kservices_exit(struct gru_state *gru);
extern int gru_dump_chiplet_request(unsigned long arg);
extern irqreturn_t gru_intr(int irq, void *dev_id);
extern int gru_handle_user_call_os(unsigned long address);
extern int gru_user_flush_tlb(unsigned long arg);
extern int gru_user_unload_context(unsigned long arg);
extern int gru_get_exception_detail(unsigned long arg);
extern int gru_set_task_slice(long address);
extern int gru_cpu_fault_map_id(void);
extern struct vm_area_struct *gru_find_vma(unsigned long vaddr);
extern void gru_flush_all_tlb(struct gru_state *gru);
extern int gru_proc_init(void);
extern void gru_proc_exit(void);
extern struct gru_thread_state *gru_alloc_gts(struct vm_area_struct *vma,
int cbr_au_count, int dsr_au_count, int options, int tsid);
extern unsigned long gru_reserve_cb_resources(struct gru_state *gru,
int cbr_au_count, char *cbmap);
extern unsigned long gru_reserve_ds_resources(struct gru_state *gru,
int dsr_au_count, char *dsmap);
extern int gru_fault(struct vm_area_struct *, struct vm_fault *vmf);
extern struct gru_mm_struct *gru_register_mmu_notifier(void);
extern void gru_drop_mmu_notifier(struct gru_mm_struct *gms);
extern int gru_ktest(unsigned long arg);
extern void gru_flush_tlb_range(struct gru_mm_struct *gms, unsigned long start,
unsigned long len);
extern unsigned long gru_options;
#endif /* __GRUTABLES_H__ */