[linux.git] / include / asm-ppc / mmu_context.h

#ifdef __KERNEL__
#ifndef __PPC_MMU_CONTEXT_H
#define __PPC_MMU_CONTEXT_H

#include <linux/config.h>
#include <asm/atomic.h>
#include <asm/bitops.h>
#include <asm/mmu.h>
#include <asm/cputable.h>

/*
 * On 32-bit PowerPC 6xx/7xx/7xxx CPUs, we use a set of 16 VSIDs
 * (virtual segment identifiers) for each context.  Although the
 * hardware supports 24-bit VSIDs, and thus >1 million contexts,
 * we only use 32,768 of them.  That is ample, since there can be
 * at most around 30,000 tasks in the system anyway, and it means
 * that we can use a bitmap to indicate which contexts are in use.
 * Using a bitmap means that we entirely avoid all of the problems
 * that we used to have when the context number overflowed,
 * particularly on SMP systems.
 *  -- paulus.
 */

/*
 * This function defines the mapping from contexts to VSIDs (virtual
 * segment IDs).  We use a skew on both the context and the high 4 bits
 * of the 32-bit virtual address (the "effective segment ID") in order
 * to spread out the entries in the MMU hash table.  Note, if this
 * function is changed then arch/ppc/mm/hashtable.S will have to be
 * changed to correspond.
 */
#define CTX_TO_VSID(ctx, va)	(((ctx) * (897 * 16) + ((va) >> 28) * 0x111) \
				 & 0xffffff)

/*
   The MPC8xx has only 16 contexts.  We rotate through them on each
   task switch.  A better way would be to keep track of tasks that
   own contexts, and implement an LRU usage.  That way very active
   tasks don't always have to pay the TLB reload overhead.  The
   kernel pages are mapped shared, so the kernel can run on behalf
   of any task that makes a kernel entry.  Shared does not mean they
   are not protected, just that the ASID comparison is not performed.
        -- Dan

   The IBM4xx has 256 contexts, so we can just rotate through these
   as a way of "switching" contexts.  If the TID of the TLB is zero,
   the PID/TID comparison is disabled, so we can use a TID of zero
   to represent all kernel pages as shared among all contexts.
   	-- Dan
 */

static inline void enter_lazy_tlb(struct mm_struct *mm, struct task_struct *tsk)
{
}

#ifdef CONFIG_8xx
#define NO_CONTEXT      	16
#define LAST_CONTEXT    	15
#define FIRST_CONTEXT    	0

#elif defined(CONFIG_4xx)
#define NO_CONTEXT      	256
#define LAST_CONTEXT    	255
#define FIRST_CONTEXT    	1

#elif defined(CONFIG_E200) || defined(CONFIG_E500)
#define NO_CONTEXT      	256
#define LAST_CONTEXT    	255
#define FIRST_CONTEXT    	1

#else

/* PPC 6xx, 7xx CPUs */
#define NO_CONTEXT      	((mm_context_t) -1)
#define LAST_CONTEXT    	32767
#define FIRST_CONTEXT    	1
#endif

/*
 * Set the current MMU context.
 * On 32-bit PowerPCs (other than the 8xx embedded chips), this is done by
 * loading up the segment registers for the user part of the address space.
 *
 * Since the PGD is immediately available, it is much faster to simply
 * pass this along as a second parameter, which is required for 8xx and
 * can be used for debugging on all processors (if you happen to have
 * an Abatron).
 */
extern void set_context(mm_context_t context, pgd_t *pgd);

/*
 * Bitmap of contexts in use.
 * The size of this bitmap is LAST_CONTEXT + 1 bits.
 */
extern unsigned long context_map[];

/*
 * This caches the next context number that we expect to be free.
 * Its use is an optimization only, we can't rely on this context
 * number to be free, but it usually will be.
 */
extern mm_context_t next_mmu_context;

/*
 * If we don't have sufficient contexts to give one to every task
 * that could be in the system, we need to be able to steal contexts.
 * These variables support that.
 */
#if LAST_CONTEXT < 30000
#define FEW_CONTEXTS	1
extern atomic_t nr_free_contexts;
extern struct mm_struct *context_mm[LAST_CONTEXT+1];
extern void steal_context(void);
#endif

/*
 * Get a new mmu context for the address space described by `mm'.
 */
static inline void get_mmu_context(struct mm_struct *mm)
{
	mm_context_t ctx;

	if (mm->context != NO_CONTEXT)
		return;
#ifdef FEW_CONTEXTS
	while (atomic_dec_if_positive(&nr_free_contexts) < 0)
		steal_context();
#endif
	ctx = next_mmu_context;
	while (test_and_set_bit(ctx, context_map)) {
		ctx = find_next_zero_bit(context_map, LAST_CONTEXT+1, ctx);
		if (ctx > LAST_CONTEXT)
			ctx = 0;
	}
	next_mmu_context = (ctx + 1) & LAST_CONTEXT;
	mm->context = ctx;
#ifdef FEW_CONTEXTS
	context_mm[ctx] = mm;
#endif
}

/*
 * Set up the context for a new address space.
 */
#define init_new_context(tsk,mm)	(((mm)->context = NO_CONTEXT), 0)

/*
 * We're finished using the context for an address space.
 */
static inline void destroy_context(struct mm_struct *mm)
{
	if (mm->context != NO_CONTEXT) {
		clear_bit(mm->context, context_map);
		mm->context = NO_CONTEXT;
#ifdef FEW_CONTEXTS
		atomic_inc(&nr_free_contexts);
#endif
	}
}

static inline void switch_mm(struct mm_struct *prev, struct mm_struct *next,
			     struct task_struct *tsk)
{
#ifdef CONFIG_ALTIVEC
	asm volatile (
 BEGIN_FTR_SECTION
	"dssall;\n"
#ifndef CONFIG_POWER4
	 "sync;\n" /* G4 needs a sync here, G5 apparently not */
#endif
 END_FTR_SECTION_IFSET(CPU_FTR_ALTIVEC)
	 : : );
#endif /* CONFIG_ALTIVEC */

	tsk->thread.pgdir = next->pgd;

	/* No need to flush userspace segments if the mm doesnt change */
	if (prev == next)
		return;

	/* Setup new userspace context */
	get_mmu_context(next);
	set_context(next->context, next->pgd);
}

#define deactivate_mm(tsk,mm)	do { } while (0)

/*
 * After we have set current->mm to a new value, this activates
 * the context for the new mm so we see the new mappings.
 */
#define activate_mm(active_mm, mm)   switch_mm(active_mm, mm, current)

extern void mmu_context_init(void);

#endif /* __PPC_MMU_CONTEXT_H */
#endif /* __KERNEL__ */
Commit	Line	Data
1da177e4 LT	1	#ifdef __KERNEL__
	2	#ifndef __PPC_MMU_CONTEXT_H
	3	#define __PPC_MMU_CONTEXT_H
	4
	5	#include <linux/config.h>
	6	#include <asm/atomic.h>
	7	#include <asm/bitops.h>
	8	#include <asm/mmu.h>
	9	#include <asm/cputable.h>
	10
	11	/*
	12	* On 32-bit PowerPC 6xx/7xx/7xxx CPUs, we use a set of 16 VSIDs
	13	* (virtual segment identifiers) for each context. Although the
	14	* hardware supports 24-bit VSIDs, and thus >1 million contexts,
	15	* we only use 32,768 of them. That is ample, since there can be
	16	* at most around 30,000 tasks in the system anyway, and it means
	17	* that we can use a bitmap to indicate which contexts are in use.
	18	* Using a bitmap means that we entirely avoid all of the problems
	19	* that we used to have when the context number overflowed,
	20	* particularly on SMP systems.
	21	* -- paulus.
	22	*/
	23
	24	/*
	25	* This function defines the mapping from contexts to VSIDs (virtual
	26	* segment IDs). We use a skew on both the context and the high 4 bits
	27	* of the 32-bit virtual address (the "effective segment ID") in order
	28	* to spread out the entries in the MMU hash table. Note, if this
	29	* function is changed then arch/ppc/mm/hashtable.S will have to be
	30	* changed to correspond.
	31	*/
	32	#define CTX_TO_VSID(ctx, va) (((ctx) * (897 * 16) + ((va) >> 28) * 0x111) \
	33	& 0xffffff)
	34
	35	/*
	36	The MPC8xx has only 16 contexts. We rotate through them on each
	37	task switch. A better way would be to keep track of tasks that
	38	own contexts, and implement an LRU usage. That way very active
	39	tasks don't always have to pay the TLB reload overhead. The
	40	kernel pages are mapped shared, so the kernel can run on behalf
	41	of any task that makes a kernel entry. Shared does not mean they
	42	are not protected, just that the ASID comparison is not performed.
	43	-- Dan
	44
	45	The IBM4xx has 256 contexts, so we can just rotate through these
	46	as a way of "switching" contexts. If the TID of the TLB is zero,
	47	the PID/TID comparison is disabled, so we can use a TID of zero
	48	to represent all kernel pages as shared among all contexts.
	49	-- Dan
	50	*/
	51
	52	static inline void enter_lazy_tlb(struct mm_struct mm, struct task_struct tsk)
	53	{
	54	}
	55
	56	#ifdef CONFIG_8xx
	57	#define NO_CONTEXT 16
	58	#define LAST_CONTEXT 15
	59	#define FIRST_CONTEXT 0
	60
	61	#elif defined(CONFIG_4xx)
	62	#define NO_CONTEXT 256
	63	#define LAST_CONTEXT 255
	64	#define FIRST_CONTEXT 1
65
33d9e9b5	66	#elif defined(CONFIG_E200) \|\| defined(CONFIG_E500)
1da177e4 LT	67	#define NO_CONTEXT 256
	68	#define LAST_CONTEXT 255
	69	#define FIRST_CONTEXT 1
	70
	71	#else
	72
	73	/* PPC 6xx, 7xx CPUs */
	74	#define NO_CONTEXT ((mm_context_t) -1)
	75	#define LAST_CONTEXT 32767
	76	#define FIRST_CONTEXT 1
	77	#endif
	78
	79	/*
	80	* Set the current MMU context.
	81	* On 32-bit PowerPCs (other than the 8xx embedded chips), this is done by
	82	* loading up the segment registers for the user part of the address space.
	83	*
	84	* Since the PGD is immediately available, it is much faster to simply
	85	* pass this along as a second parameter, which is required for 8xx and
	86	* can be used for debugging on all processors (if you happen to have
	87	* an Abatron).
	88	*/
	89	extern void set_context(mm_context_t context, pgd_t *pgd);
	90
	91	/*
	92	* Bitmap of contexts in use.
	93	* The size of this bitmap is LAST_CONTEXT + 1 bits.
	94	*/
	95	extern unsigned long context_map[];
	96
	97	/*
	98	* This caches the next context number that we expect to be free.
	99	* Its use is an optimization only, we can't rely on this context
	100	* number to be free, but it usually will be.
	101	*/
	102	extern mm_context_t next_mmu_context;
	103
	104	/*
	105	* If we don't have sufficient contexts to give one to every task
	106	* that could be in the system, we need to be able to steal contexts.
	107	* These variables support that.
	108	*/
	109	#if LAST_CONTEXT < 30000
	110	#define FEW_CONTEXTS 1
	111	extern atomic_t nr_free_contexts;
	112	extern struct mm_struct *context_mm[LAST_CONTEXT+1];
	113	extern void steal_context(void);
	114	#endif
	115
	116	/*
	117	* Get a new mmu context for the address space described by `mm'.
	118	*/
	119	static inline void get_mmu_context(struct mm_struct *mm)
	120	{
	121	mm_context_t ctx;
	122
	123	if (mm->context != NO_CONTEXT)
	124	return;
	125	#ifdef FEW_CONTEXTS
	126	while (atomic_dec_if_positive(&nr_free_contexts) < 0)
	127	steal_context();
	128	#endif
	129	ctx = next_mmu_context;
	130	while (test_and_set_bit(ctx, context_map)) {
131	ctx = find_next_zero_bit(context_map, LAST_CONTEXT+1, ctx);
132	if (ctx > LAST_CONTEXT)
133	ctx = 0;
134	}
135	next_mmu_context = (ctx + 1) & LAST_CONTEXT;
136	mm->context = ctx;
137	#ifdef FEW_CONTEXTS
138	context_mm[ctx] = mm;
139	#endif
140	}
141
142	/*
143	* Set up the context for a new address space.
144	*/
145	#define init_new_context(tsk,mm) (((mm)->context = NO_CONTEXT), 0)
146
147	/*
148	* We're finished using the context for an address space.
149	*/
150	static inline void destroy_context(struct mm_struct *mm)
151	{
152	if (mm->context != NO_CONTEXT) {
153	clear_bit(mm->context, context_map);
154	mm->context = NO_CONTEXT;
155	#ifdef FEW_CONTEXTS
156	atomic_inc(&nr_free_contexts);
157	#endif
158	}
159	}
160
161	static inline void switch_mm(struct mm_struct prev, struct mm_struct next,
162	struct task_struct *tsk)
163	{
164	#ifdef CONFIG_ALTIVEC
165	asm volatile (
166	BEGIN_FTR_SECTION
167	"dssall;\n"
168	#ifndef CONFIG_POWER4
169	"sync;\n" /* G4 needs a sync here, G5 apparently not */
170	#endif
171	END_FTR_SECTION_IFSET(CPU_FTR_ALTIVEC)
172	: : );
173	#endif /* CONFIG_ALTIVEC */
174
175	tsk->thread.pgdir = next->pgd;
176
177	/* No need to flush userspace segments if the mm doesnt change */
178	if (prev == next)
179	return;
180
181	/* Setup new userspace context */
182	get_mmu_context(next);
183	set_context(next->context, next->pgd);
184	}
185
186	#define deactivate_mm(tsk,mm) do { } while (0)
187
188	/*
189	* After we have set current->mm to a new value, this activates
190	* the context for the new mm so we see the new mappings.
191	*/
192	#define activate_mm(active_mm, mm) switch_mm(active_mm, mm, current)
193
194	extern void mmu_context_init(void);
195
196	#endif /* __PPC_MMU_CONTEXT_H */
197	#endif /* __KERNEL__ */