| blob | 917009b80e6951dc7e2b308ad7fb42cd9fbbf7d7 |
1 /* SPDX-License-Identifier: GPL-2.0-or-later */
2 /*
3 * Copyright (C) 2017 Imagination Technologies
4 * Author: Paul Burton <paul.burton@mips.com>
5 */
7 #ifndef __MIPS_ASM_MIPS_CPS_H__
8 #define __MIPS_ASM_MIPS_CPS_H__
10 #include <linux/bitfield.h>
11 #include <linux/cpumask.h>
12 #include <linux/io.h>
13 #include <linux/types.h>
18 #define CPS_ACCESSOR_A(unit, off, name) \
19 static inline void *addr_##unit##_##name(void) \
20 { \
21 return mips_##unit##_base + (off); \
22 }
24 #define CPS_ACCESSOR_R(unit, sz, name) \
25 static inline uint##sz##_t read_##unit##_##name(void) \
26 { \
27 uint64_t val64; \
28 \
29 switch (sz) { \
30 case 32: \
31 return __raw_readl(addr_##unit##_##name()); \
32 \
33 case 64: \
34 if (mips_cm_is64) \
35 return __raw_readq(addr_##unit##_##name()); \
36 \
37 val64 = __raw_readl(addr_##unit##_##name() + 4); \
38 val64 <<= 32; \
39 val64 |= __raw_readl(addr_##unit##_##name()); \
40 return val64; \
41 \
42 default: \
43 return __cps_access_bad_size(); \
44 } \
45 }
47 #define CPS_ACCESSOR_W(unit, sz, name) \
48 static inline void write_##unit##_##name(uint##sz##_t val) \
49 { \
50 switch (sz) { \
51 case 32: \
52 __raw_writel(val, addr_##unit##_##name()); \
53 break; \
54 \
55 case 64: \
56 if (mips_cm_is64) { \
57 __raw_writeq(val, addr_##unit##_##name()); \
58 break; \
59 } \
60 \
61 __raw_writel((uint64_t)val >> 32, \
62 addr_##unit##_##name() + 4); \
63 __raw_writel(val, addr_##unit##_##name()); \
64 break; \
65 \
66 default: \
67 __cps_access_bad_size(); \
68 break; \
69 } \
70 }
72 #define CPS_ACCESSOR_M(unit, sz, name) \
73 static inline void change_##unit##_##name(uint##sz##_t mask, \
74 uint##sz##_t val) \
75 { \
76 uint##sz##_t reg_val = read_##unit##_##name(); \
77 reg_val &= ~mask; \
78 reg_val |= val; \
79 write_##unit##_##name(reg_val); \
80 } \
81 \
82 static inline void set_##unit##_##name(uint##sz##_t val) \
83 { \
84 change_##unit##_##name(val, val); \
85 } \
86 \
87 static inline void clear_##unit##_##name(uint##sz##_t val) \
88 { \
89 change_##unit##_##name(val, 0); \
90 }
92 #define CPS_ACCESSOR_RO(unit, sz, off, name) \
93 CPS_ACCESSOR_A(unit, off, name) \
94 CPS_ACCESSOR_R(unit, sz, name)
96 #define CPS_ACCESSOR_WO(unit, sz, off, name) \
97 CPS_ACCESSOR_A(unit, off, name) \
98 CPS_ACCESSOR_W(unit, sz, name)
100 #define CPS_ACCESSOR_RW(unit, sz, off, name) \
101 CPS_ACCESSOR_A(unit, off, name) \
102 CPS_ACCESSOR_R(unit, sz, name) \
103 CPS_ACCESSOR_W(unit, sz, name) \
104 CPS_ACCESSOR_M(unit, sz, name)
106 #include <asm/mips-cm.h>
107 #include <asm/mips-cpc.h>
108 #include <asm/mips-gic.h>
110 /**
111 * mips_cps_numclusters - return the number of clusters present in the system
112 *
113 * Returns the number of clusters in the system.
114 */
116 {
121 }
123 /**
124 * mips_cps_cluster_config - return (GCR|CPC)_CONFIG from a cluster
125 * @cluster: the ID of the cluster whose config we want
126 *
127 * Read the value of GCR_CONFIG (or its CPC_CONFIG mirror) from a @cluster.
128 *
129 * Returns the value of GCR_CONFIG.
130 */
132 {
136 /*
137 * Prior to CM 3.5 we don't have the notion of multiple
138 * clusters so we can trivially read the GCR_CONFIG register
139 * within this cluster.
140 */
144 /*
145 * From CM 3.5 onwards we read the CPC_CONFIG mirror of
146 * GCR_CONFIG via the redirect region, since the CPC is always
147 * powered up allowing us not to need to power up the CM.
148 */
152 }
155 }
157 /**
158 * mips_cps_numcores - return the number of cores present in a cluster
159 * @cluster: the ID of the cluster whose core count we want
160 *
161 * Returns the value of the PCORES field of the GCR_CONFIG register plus 1, or
162 * zero if no Coherence Manager is present.
163 */
165 {
169 /* Add one before masking to handle 0xff indicating no cores */
172 }
174 /**
175 * mips_cps_numiocu - return the number of IOCUs present in a cluster
176 * @cluster: the ID of the cluster whose IOCU count we want
177 *
178 * Returns the value of the NUMIOCU field of the GCR_CONFIG register, or zero
179 * if no Coherence Manager is present.
180 */
182 {
188 }
190 /**
191 * mips_cps_numvps - return the number of VPs (threads) supported by a core
192 * @cluster: the ID of the cluster containing the core we want to examine
193 * @core: the ID of the core whose VP count we want
194 *
195 * Returns the number of Virtual Processors (VPs, ie. hardware threads) that
196 * are supported by the given @core in the given @cluster. If the core or the
197 * kernel do not support hardware mutlti-threading this returns 1.
198 */
200 {
213 /*
214 * Prior to CM 3.5 we can only have one cluster & don't have
215 * CPC_Cx_CONFIG, so we read GCR_Cx_CONFIG.
216 */
219 /*
220 * From CM 3.5 onwards we read CPC_Cx_CONFIG because the CPC is
221 * always powered, which allows us to not worry about powering
222 * up the cluster's CM here.
223 */
225 }
230 }
232 /**
233 * mips_cps_multicluster_cpus() - Detect whether CPUs are in multiple clusters
234 *
235 * Determine whether the system includes CPUs in multiple clusters - ie.
236 * whether we can treat the system as single or multi-cluster as far as CPUs
237 * are concerned. Note that this is slightly different to simply checking
238 * whether multiple clusters are present - it is possible for there to be
239 * clusters which contain no CPUs, which this function will effectively ignore.
240 *
241 * Returns true if CPUs are spread across multiple clusters, else false.
242 */
244 {
247 /*
248 * CPUs are numbered sequentially by cluster - ie. CPUs 0..X will be in
249 * cluster 0, CPUs X+1..Y in cluster 1, CPUs Y+1..Z in cluster 2 etc.
250 *
251 * Thus we can detect multiple clusters trivially by checking whether
252 * the first & last CPUs belong to the same cluster.
253 */
257 }
259 /**
260 * mips_cps_first_online_in_cluster() - Detect if CPU is first online in cluster
261 *
262 * Determine whether the local CPU is the first to be brought online in its
263 * cluster - that is, whether there are any other online CPUs in the local
264 * cluster.
265 *
266 * Returns true if this CPU is first online, else false.
267 */