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1 /*
2  * lppaca.h
3  * Copyright (C) 2001  Mike Corrigan IBM Corporation
4  *
5  * This program is free software; you can redistribute it and/or modify
6  * it under the terms of the GNU General Public License as published by
7  * the Free Software Foundation; either version 2 of the License, or
8  * (at your option) any later version.
9  *
10  * This program is distributed in the hope that it will be useful,
11  * but WITHOUT ANY WARRANTY; without even the implied warranty of
12  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
13  * GNU General Public License for more details.
14  *
15  * You should have received a copy of the GNU General Public License
16  * along with this program; if not, write to the Free Software
17  * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307 USA
18  */
19 #ifndef _ASM_POWERPC_LPPACA_H
20 #define _ASM_POWERPC_LPPACA_H
21 #ifdef __KERNEL__
22 
23 /* These definitions relate to hypervisors that only exist when using
24  * a server type processor
25  */
26 #ifdef CONFIG_PPC_BOOK3S
27 
28 //=============================================================================
29 //
30 //	This control block contains the data that is shared between the
31 //	hypervisor (PLIC) and the OS.
32 //
33 //
34 //----------------------------------------------------------------------------
35 #include <linux/cache.h>
36 #include <linux/threads.h>
37 #include <asm/types.h>
38 #include <asm/mmu.h>
39 
40 /*
41  * We only have to have statically allocated lppaca structs on
42  * legacy iSeries, which supports at most 64 cpus.
43  */
44 #define NR_LPPACAS	1
45 
46 
47 /* The Hypervisor barfs if the lppaca crosses a page boundary.  A 1k
48  * alignment is sufficient to prevent this */
49 struct lppaca {
50 //=============================================================================
51 // CACHE_LINE_1 0x0000 - 0x007F Contains read-only data
52 // NOTE: The xDynXyz fields are fields that will be dynamically changed by
53 // PLIC when preparing to bring a processor online or when dispatching a
54 // virtual processor!
55 //=============================================================================
56 	u32	desc;			// Eye catcher 0xD397D781	x00-x03
57 	u16	size;			// Size of this struct		x04-x05
58 	u16	reserved1;		// Reserved			x06-x07
59 	u16	reserved2:14;		// Reserved			x08-x09
60 	u8	shared_proc:1;		// Shared processor indicator	...
61 	u8	secondary_thread:1;	// Secondary thread indicator	...
62 	volatile u8 dyn_proc_status:8;	// Dynamic Status of this proc	x0A-x0A
63 	u8	secondary_thread_count;	// Secondary thread count	x0B-x0B
64 	volatile u16 dyn_hv_phys_proc_index;// Dynamic HV Physical Proc Index0C-x0D
65 	volatile u16 dyn_hv_log_proc_index;// Dynamic HV Logical Proc Indexx0E-x0F
66 	u32	decr_val;   		// Value for Decr programming 	x10-x13
67 	u32	pmc_val;       		// Value for PMC regs         	x14-x17
68 	volatile u32 dyn_hw_node_id;	// Dynamic Hardware Node id	x18-x1B
69 	volatile u32 dyn_hw_proc_id;	// Dynamic Hardware Proc Id	x1C-x1F
70 	volatile u32 dyn_pir;		// Dynamic ProcIdReg value	x20-x23
71 	u32	dsei_data;           	// DSEI data                  	x24-x27
72 	u64	sprg3;               	// SPRG3 value                	x28-x2F
73 	u8	reserved3[40];		// Reserved			x30-x57
74 	volatile u8 vphn_assoc_counts[8]; // Virtual processor home node
75 					// associativity change counters x58-x5F
76 	u8	reserved4[32];		// Reserved			x60-x7F
77 
78 //=============================================================================
79 // CACHE_LINE_2 0x0080 - 0x00FF Contains local read-write data
80 //=============================================================================
81 	// This Dword contains a byte for each type of interrupt that can occur.
82 	// The IPI is a count while the others are just a binary 1 or 0.
83 	union {
84 		u64	any_int;
85 		struct {
86 			u16	reserved;	// Reserved - cleared by #mpasmbl
87 			u8	xirr_int;	// Indicates xXirrValue is valid or Immed IO
88 			u8	ipi_cnt;	// IPI Count
89 			u8	decr_int;	// DECR interrupt occurred
90 			u8	pdc_int;	// PDC interrupt occurred
91 			u8	quantum_int;	// Interrupt quantum reached
92 			u8	old_plic_deferred_ext_int;	// Old PLIC has a deferred XIRR pending
93 		} fields;
94 	} int_dword;
95 
96 	// Whenever any fields in this Dword are set then PLIC will defer the
97 	// processing of external interrupts.  Note that PLIC will store the
98 	// XIRR directly into the xXirrValue field so that another XIRR will
99 	// not be presented until this one clears.  The layout of the low
100 	// 4-bytes of this Dword is up to SLIC - PLIC just checks whether the
101 	// entire Dword is zero or not.  A non-zero value in the low order
102 	// 2-bytes will result in SLIC being granted the highest thread
103 	// priority upon return.  A 0 will return to SLIC as medium priority.
104 	u64	plic_defer_ints_area;	// Entire Dword
105 
106 	// Used to pass the real SRR0/1 from PLIC to SLIC as well as to
107 	// pass the target SRR0/1 from SLIC to PLIC on a SetAsrAndRfid.
108 	u64	saved_srr0;		// Saved SRR0                   x10-x17
109 	u64	saved_srr1;		// Saved SRR1                   x18-x1F
110 
111 	// Used to pass parms from the OS to PLIC for SetAsrAndRfid
112 	u64	saved_gpr3;		// Saved GPR3                   x20-x27
113 	u64	saved_gpr4;		// Saved GPR4                   x28-x2F
114 	union {
115 		u64	saved_gpr5;	/* Saved GPR5               x30-x37 */
116 		struct {
117 			u8	cede_latency_hint;  /*			x30 */
118 			u8	reserved[7];        /*		    x31-x36 */
119 		} fields;
120 	} gpr5_dword;
121 
122 
123 	u8	dtl_enable_mask;	// Dispatch Trace Log mask	x38-x38
124 	u8	donate_dedicated_cpu;	// Donate dedicated CPU cycles  x39-x39
125 	u8	fpregs_in_use;		// FP regs in use               x3A-x3A
126 	u8	pmcregs_in_use;		// PMC regs in use              x3B-x3B
127 	volatile u32 saved_decr;	// Saved Decr Value             x3C-x3F
128 	volatile u64 emulated_time_base;// Emulated TB for this thread  x40-x47
129 	volatile u64 cur_plic_latency;	// Unaccounted PLIC latency     x48-x4F
130 	u64	tot_plic_latency;	// Accumulated PLIC latency     x50-x57
131 	u64	wait_state_cycles;	// Wait cycles for this proc    x58-x5F
132 	u64	end_of_quantum;		// TB at end of quantum         x60-x67
133 	u64	pdc_saved_sprg1;	// Saved SPRG1 for PMC int      x68-x6F
134 	u64	pdc_saved_srr0;		// Saved SRR0 for PMC int       x70-x77
135 	volatile u32 virtual_decr;	// Virtual DECR for shared procsx78-x7B
136 	u16	slb_count;		// # of SLBs to maintain        x7C-x7D
137 	u8	idle;			// Indicate OS is idle          x7E
138 	u8	vmxregs_in_use;		// VMX registers in use         x7F
139 
140 
141 //=============================================================================
142 // CACHE_LINE_3 0x0100 - 0x017F: This line is shared with other processors
143 //=============================================================================
144 	// This is the yield_count.  An "odd" value (low bit on) means that
145 	// the processor is yielded (either because of an OS yield or a PLIC
146 	// preempt).  An even value implies that the processor is currently
147 	// executing.
148 	// NOTE: This value will ALWAYS be zero for dedicated processors and
149 	// will NEVER be zero for shared processors (ie, initialized to a 1).
150 	volatile u32 yield_count;	// PLIC increments each dispatchx00-x03
151 	volatile u32 dispersion_count;	// dispatch changed phys cpu    x04-x07
152 	volatile u64 cmo_faults;	// CMO page fault count         x08-x0F
153 	volatile u64 cmo_fault_time;	// CMO page fault time          x10-x17
154 	u8	reserved7[104];		// Reserved                     x18-x7F
155 
156 //=============================================================================
157 // CACHE_LINE_4-5 0x0180 - 0x027F Contains PMC interrupt data
158 //=============================================================================
159 	u32	page_ins;		// CMO Hint - # page ins by OS  x00-x03
160 	u8	reserved8[148];		// Reserved                     x04-x97
161 	volatile u64 dtl_idx;		// Dispatch Trace Log head idx	x98-x9F
162 	u8	reserved9[96];		// Reserved                     xA0-xFF
163 } __attribute__((__aligned__(0x400)));
164 
165 extern struct lppaca lppaca[];
166 
167 #define lppaca_of(cpu)	(*paca[cpu].lppaca_ptr)
168 
169 /*
170  * SLB shadow buffer structure as defined in the PAPR.  The save_area
171  * contains adjacent ESID and VSID pairs for each shadowed SLB.  The
172  * ESID is stored in the lower 64bits, then the VSID.
173  */
174 struct slb_shadow {
175 	u32	persistent;		// Number of persistent SLBs	x00-x03
176 	u32	buffer_length;		// Total shadow buffer length	x04-x07
177 	u64	reserved;		// Alignment			x08-x0f
178 	struct	{
179 		u64     esid;
180 		u64	vsid;
181 	} save_area[SLB_NUM_BOLTED];	//				x10-x40
182 } ____cacheline_aligned;
183 
184 extern struct slb_shadow slb_shadow[];
185 
186 /*
187  * Layout of entries in the hypervisor's dispatch trace log buffer.
188  */
189 struct dtl_entry {
190 	u8	dispatch_reason;
191 	u8	preempt_reason;
192 	u16	processor_id;
193 	u32	enqueue_to_dispatch_time;
194 	u32	ready_to_enqueue_time;
195 	u32	waiting_to_ready_time;
196 	u64	timebase;
197 	u64	fault_addr;
198 	u64	srr0;
199 	u64	srr1;
200 };
201 
202 #define DISPATCH_LOG_BYTES	4096	/* bytes per cpu */
203 #define N_DISPATCH_LOG		(DISPATCH_LOG_BYTES / sizeof(struct dtl_entry))
204 
205 extern struct kmem_cache *dtl_cache;
206 
207 /*
208  * When CONFIG_VIRT_CPU_ACCOUNTING = y, the cpu accounting code controls
209  * reading from the dispatch trace log.  If other code wants to consume
210  * DTL entries, it can set this pointer to a function that will get
211  * called once for each DTL entry that gets processed.
212  */
213 extern void (*dtl_consumer)(struct dtl_entry *entry, u64 index);
214 
215 #endif /* CONFIG_PPC_BOOK3S */
216 #endif /* __KERNEL__ */
217 #endif /* _ASM_POWERPC_LPPACA_H */
218