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 */
  6
  7#ifndef __MIPS_ASM_MIPS_CPS_H__
  8#define __MIPS_ASM_MIPS_CPS_H__
  9
 
 10#include <linux/io.h>
 11#include <linux/types.h>
 12
 13extern unsigned long __cps_access_bad_size(void)
 14	__compiletime_error("Bad size for CPS accessor");
 15
 16#define CPS_ACCESSOR_A(unit, off, name)					\
 17static inline void *addr_##unit##_##name(void)				\
 18{									\
 19	return mips_##unit##_base + (off);				\
 20}
 21
 22#define CPS_ACCESSOR_R(unit, sz, name)					\
 23static inline uint##sz##_t read_##unit##_##name(void)			\
 24{									\
 25	uint64_t val64;							\
 26									\
 27	switch (sz) {							\
 28	case 32:							\
 29		return __raw_readl(addr_##unit##_##name());		\
 30									\
 31	case 64:							\
 32		if (mips_cm_is64)					\
 33			return __raw_readq(addr_##unit##_##name());	\
 34									\
 35		val64 = __raw_readl(addr_##unit##_##name() + 4);	\
 36		val64 <<= 32;						\
 37		val64 |= __raw_readl(addr_##unit##_##name());		\
 38		return val64;						\
 39									\
 40	default:							\
 41		return __cps_access_bad_size();				\
 42	}								\
 43}
 44
 45#define CPS_ACCESSOR_W(unit, sz, name)					\
 46static inline void write_##unit##_##name(uint##sz##_t val)		\
 47{									\
 48	switch (sz) {							\
 49	case 32:							\
 50		__raw_writel(val, addr_##unit##_##name());		\
 51		break;							\
 52									\
 53	case 64:							\
 54		if (mips_cm_is64) {					\
 55			__raw_writeq(val, addr_##unit##_##name());	\
 56			break;						\
 57		}							\
 58									\
 59		__raw_writel((uint64_t)val >> 32,			\
 60			     addr_##unit##_##name() + 4);		\
 61		__raw_writel(val, addr_##unit##_##name());		\
 62		break;							\
 63									\
 64	default:							\
 65		__cps_access_bad_size();				\
 66		break;							\
 67	}								\
 68}
 69
 70#define CPS_ACCESSOR_M(unit, sz, name)					\
 71static inline void change_##unit##_##name(uint##sz##_t mask,		\
 72					  uint##sz##_t val)		\
 73{									\
 74	uint##sz##_t reg_val = read_##unit##_##name();			\
 75	reg_val &= ~mask;						\
 76	reg_val |= val;							\
 77	write_##unit##_##name(reg_val);					\
 78}									\
 79									\
 80static inline void set_##unit##_##name(uint##sz##_t val)		\
 81{									\
 82	change_##unit##_##name(val, val);				\
 83}									\
 84									\
 85static inline void clear_##unit##_##name(uint##sz##_t val)		\
 86{									\
 87	change_##unit##_##name(val, 0);					\
 88}
 89
 90#define CPS_ACCESSOR_RO(unit, sz, off, name)				\
 91	CPS_ACCESSOR_A(unit, off, name)					\
 92	CPS_ACCESSOR_R(unit, sz, name)
 93
 94#define CPS_ACCESSOR_WO(unit, sz, off, name)				\
 95	CPS_ACCESSOR_A(unit, off, name)					\
 96	CPS_ACCESSOR_W(unit, sz, name)
 97
 98#define CPS_ACCESSOR_RW(unit, sz, off, name)				\
 99	CPS_ACCESSOR_A(unit, off, name)					\
100	CPS_ACCESSOR_R(unit, sz, name)					\
101	CPS_ACCESSOR_W(unit, sz, name)					\
102	CPS_ACCESSOR_M(unit, sz, name)
103
104#include <asm/mips-cm.h>
105#include <asm/mips-cpc.h>
106#include <asm/mips-gic.h>
107
108/**
109 * mips_cps_numclusters - return the number of clusters present in the system
110 *
111 * Returns the number of clusters in the system.
112 */
113static inline unsigned int mips_cps_numclusters(void)
114{
115	unsigned int num_clusters;
116
117	if (mips_cm_revision() < CM_REV_CM3_5)
118		return 1;
119
120	num_clusters = read_gcr_config() & CM_GCR_CONFIG_NUM_CLUSTERS;
121	num_clusters >>= __ffs(CM_GCR_CONFIG_NUM_CLUSTERS);
122	return num_clusters;
123}
124
125/**
126 * mips_cps_cluster_config - return (GCR|CPC)_CONFIG from a cluster
127 * @cluster: the ID of the cluster whose config we want
128 *
129 * Read the value of GCR_CONFIG (or its CPC_CONFIG mirror) from a @cluster.
130 *
131 * Returns the value of GCR_CONFIG.
132 */
133static inline uint64_t mips_cps_cluster_config(unsigned int cluster)
134{
135	uint64_t config;
136
137	if (mips_cm_revision() < CM_REV_CM3_5) {
138		/*
139		 * Prior to CM 3.5 we don't have the notion of multiple
140		 * clusters so we can trivially read the GCR_CONFIG register
141		 * within this cluster.
142		 */
143		WARN_ON(cluster != 0);
144		config = read_gcr_config();
145	} else {
146		/*
147		 * From CM 3.5 onwards we read the CPC_CONFIG mirror of
148		 * GCR_CONFIG via the redirect region, since the CPC is always
149		 * powered up allowing us not to need to power up the CM.
150		 */
151		mips_cm_lock_other(cluster, 0, 0, CM_GCR_Cx_OTHER_BLOCK_GLOBAL);
152		config = read_cpc_redir_config();
153		mips_cm_unlock_other();
154	}
155
156	return config;
157}
158
159/**
160 * mips_cps_numcores - return the number of cores present in a cluster
161 * @cluster: the ID of the cluster whose core count we want
162 *
163 * Returns the value of the PCORES field of the GCR_CONFIG register plus 1, or
164 * zero if no Coherence Manager is present.
165 */
166static inline unsigned int mips_cps_numcores(unsigned int cluster)
167{
168	if (!mips_cm_present())
169		return 0;
170
171	/* Add one before masking to handle 0xff indicating no cores */
172	return (mips_cps_cluster_config(cluster) + 1) & CM_GCR_CONFIG_PCORES;
 
173}
174
175/**
176 * mips_cps_numiocu - return the number of IOCUs present in a cluster
177 * @cluster: the ID of the cluster whose IOCU count we want
178 *
179 * Returns the value of the NUMIOCU field of the GCR_CONFIG register, or zero
180 * if no Coherence Manager is present.
181 */
182static inline unsigned int mips_cps_numiocu(unsigned int cluster)
183{
184	unsigned int num_iocu;
185
186	if (!mips_cm_present())
187		return 0;
188
189	num_iocu = mips_cps_cluster_config(cluster) & CM_GCR_CONFIG_NUMIOCU;
190	num_iocu >>= __ffs(CM_GCR_CONFIG_NUMIOCU);
191	return num_iocu;
192}
193
194/**
195 * mips_cps_numvps - return the number of VPs (threads) supported by a core
196 * @cluster: the ID of the cluster containing the core we want to examine
197 * @core: the ID of the core whose VP count we want
198 *
199 * Returns the number of Virtual Processors (VPs, ie. hardware threads) that
200 * are supported by the given @core in the given @cluster. If the core or the
201 * kernel do not support hardware mutlti-threading this returns 1.
202 */
203static inline unsigned int mips_cps_numvps(unsigned int cluster, unsigned int core)
204{
205	unsigned int cfg;
206
207	if (!mips_cm_present())
208		return 1;
209
210	if ((!IS_ENABLED(CONFIG_MIPS_MT_SMP) || !cpu_has_mipsmt)
211		&& (!IS_ENABLED(CONFIG_CPU_MIPSR6) || !cpu_has_vp))
212		return 1;
213
214	mips_cm_lock_other(cluster, core, 0, CM_GCR_Cx_OTHER_BLOCK_LOCAL);
215
216	if (mips_cm_revision() < CM_REV_CM3_5) {
217		/*
218		 * Prior to CM 3.5 we can only have one cluster & don't have
219		 * CPC_Cx_CONFIG, so we read GCR_Cx_CONFIG.
220		 */
221		cfg = read_gcr_co_config();
222	} else {
223		/*
224		 * From CM 3.5 onwards we read CPC_Cx_CONFIG because the CPC is
225		 * always powered, which allows us to not worry about powering
226		 * up the cluster's CM here.
227		 */
228		cfg = read_cpc_co_config();
229	}
230
231	mips_cm_unlock_other();
232
233	return (cfg + 1) & CM_GCR_Cx_CONFIG_PVPE;
234}
235
236#endif /* __MIPS_ASM_MIPS_CPS_H__ */

  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 */
  6
  7#ifndef __MIPS_ASM_MIPS_CPS_H__
  8#define __MIPS_ASM_MIPS_CPS_H__
  9
 10#include <linux/bitfield.h>
 11#include <linux/io.h>
 12#include <linux/types.h>
 13
 14extern unsigned long __cps_access_bad_size(void)
 15	__compiletime_error("Bad size for CPS accessor");
 16
 17#define CPS_ACCESSOR_A(unit, off, name)					\
 18static inline void *addr_##unit##_##name(void)				\
 19{									\
 20	return mips_##unit##_base + (off);				\
 21}
 22
 23#define CPS_ACCESSOR_R(unit, sz, name)					\
 24static inline uint##sz##_t read_##unit##_##name(void)			\
 25{									\
 26	uint64_t val64;							\
 27									\
 28	switch (sz) {							\
 29	case 32:							\
 30		return __raw_readl(addr_##unit##_##name());		\
 31									\
 32	case 64:							\
 33		if (mips_cm_is64)					\
 34			return __raw_readq(addr_##unit##_##name());	\
 35									\
 36		val64 = __raw_readl(addr_##unit##_##name() + 4);	\
 37		val64 <<= 32;						\
 38		val64 |= __raw_readl(addr_##unit##_##name());		\
 39		return val64;						\
 40									\
 41	default:							\
 42		return __cps_access_bad_size();				\
 43	}								\
 44}
 45
 46#define CPS_ACCESSOR_W(unit, sz, name)					\
 47static inline void write_##unit##_##name(uint##sz##_t val)		\
 48{									\
 49	switch (sz) {							\
 50	case 32:							\
 51		__raw_writel(val, addr_##unit##_##name());		\
 52		break;							\
 53									\
 54	case 64:							\
 55		if (mips_cm_is64) {					\
 56			__raw_writeq(val, addr_##unit##_##name());	\
 57			break;						\
 58		}							\
 59									\
 60		__raw_writel((uint64_t)val >> 32,			\
 61			     addr_##unit##_##name() + 4);		\
 62		__raw_writel(val, addr_##unit##_##name());		\
 63		break;							\
 64									\
 65	default:							\
 66		__cps_access_bad_size();				\
 67		break;							\
 68	}								\
 69}
 70
 71#define CPS_ACCESSOR_M(unit, sz, name)					\
 72static inline void change_##unit##_##name(uint##sz##_t mask,		\
 73					  uint##sz##_t val)		\
 74{									\
 75	uint##sz##_t reg_val = read_##unit##_##name();			\
 76	reg_val &= ~mask;						\
 77	reg_val |= val;							\
 78	write_##unit##_##name(reg_val);					\
 79}									\
 80									\
 81static inline void set_##unit##_##name(uint##sz##_t val)		\
 82{									\
 83	change_##unit##_##name(val, val);				\
 84}									\
 85									\
 86static inline void clear_##unit##_##name(uint##sz##_t val)		\
 87{									\
 88	change_##unit##_##name(val, 0);					\
 89}
 90
 91#define CPS_ACCESSOR_RO(unit, sz, off, name)				\
 92	CPS_ACCESSOR_A(unit, off, name)					\
 93	CPS_ACCESSOR_R(unit, sz, name)
 94
 95#define CPS_ACCESSOR_WO(unit, sz, off, name)				\
 96	CPS_ACCESSOR_A(unit, off, name)					\
 97	CPS_ACCESSOR_W(unit, sz, name)
 98
 99#define CPS_ACCESSOR_RW(unit, sz, off, name)				\
100	CPS_ACCESSOR_A(unit, off, name)					\
101	CPS_ACCESSOR_R(unit, sz, name)					\
102	CPS_ACCESSOR_W(unit, sz, name)					\
103	CPS_ACCESSOR_M(unit, sz, name)
104
105#include <asm/mips-cm.h>
106#include <asm/mips-cpc.h>
107#include <asm/mips-gic.h>
108
109/**
110 * mips_cps_numclusters - return the number of clusters present in the system
111 *
112 * Returns the number of clusters in the system.
113 */
114static inline unsigned int mips_cps_numclusters(void)
115{
 
 
116	if (mips_cm_revision() < CM_REV_CM3_5)
117		return 1;
118
119	return FIELD_GET(CM_GCR_CONFIG_NUM_CLUSTERS, read_gcr_config());
 
 
120}
121
122/**
123 * mips_cps_cluster_config - return (GCR|CPC)_CONFIG from a cluster
124 * @cluster: the ID of the cluster whose config we want
125 *
126 * Read the value of GCR_CONFIG (or its CPC_CONFIG mirror) from a @cluster.
127 *
128 * Returns the value of GCR_CONFIG.
129 */
130static inline uint64_t mips_cps_cluster_config(unsigned int cluster)
131{
132	uint64_t config;
133
134	if (mips_cm_revision() < CM_REV_CM3_5) {
135		/*
136		 * Prior to CM 3.5 we don't have the notion of multiple
137		 * clusters so we can trivially read the GCR_CONFIG register
138		 * within this cluster.
139		 */
140		WARN_ON(cluster != 0);
141		config = read_gcr_config();
142	} else {
143		/*
144		 * From CM 3.5 onwards we read the CPC_CONFIG mirror of
145		 * GCR_CONFIG via the redirect region, since the CPC is always
146		 * powered up allowing us not to need to power up the CM.
147		 */
148		mips_cm_lock_other(cluster, 0, 0, CM_GCR_Cx_OTHER_BLOCK_GLOBAL);
149		config = read_cpc_redir_config();
150		mips_cm_unlock_other();
151	}
152
153	return config;
154}
155
156/**
157 * mips_cps_numcores - return the number of cores present in a cluster
158 * @cluster: the ID of the cluster whose core count we want
159 *
160 * Returns the value of the PCORES field of the GCR_CONFIG register plus 1, or
161 * zero if no Coherence Manager is present.
162 */
163static inline unsigned int mips_cps_numcores(unsigned int cluster)
164{
165	if (!mips_cm_present())
166		return 0;
167
168	/* Add one before masking to handle 0xff indicating no cores */
169	return FIELD_GET(CM_GCR_CONFIG_PCORES,
170			 mips_cps_cluster_config(cluster) + 1);
171}
172
173/**
174 * mips_cps_numiocu - return the number of IOCUs present in a cluster
175 * @cluster: the ID of the cluster whose IOCU count we want
176 *
177 * Returns the value of the NUMIOCU field of the GCR_CONFIG register, or zero
178 * if no Coherence Manager is present.
179 */
180static inline unsigned int mips_cps_numiocu(unsigned int cluster)
181{
 
 
182	if (!mips_cm_present())
183		return 0;
184
185	return FIELD_GET(CM_GCR_CONFIG_NUMIOCU,
186			 mips_cps_cluster_config(cluster));
 
187}
188
189/**
190 * mips_cps_numvps - return the number of VPs (threads) supported by a core
191 * @cluster: the ID of the cluster containing the core we want to examine
192 * @core: the ID of the core whose VP count we want
193 *
194 * Returns the number of Virtual Processors (VPs, ie. hardware threads) that
195 * are supported by the given @core in the given @cluster. If the core or the
196 * kernel do not support hardware mutlti-threading this returns 1.
197 */
198static inline unsigned int mips_cps_numvps(unsigned int cluster, unsigned int core)
199{
200	unsigned int cfg;
201
202	if (!mips_cm_present())
203		return 1;
204
205	if ((!IS_ENABLED(CONFIG_MIPS_MT_SMP) || !cpu_has_mipsmt)
206		&& (!IS_ENABLED(CONFIG_CPU_MIPSR6) || !cpu_has_vp))
207		return 1;
208
209	mips_cm_lock_other(cluster, core, 0, CM_GCR_Cx_OTHER_BLOCK_LOCAL);
210
211	if (mips_cm_revision() < CM_REV_CM3_5) {
212		/*
213		 * Prior to CM 3.5 we can only have one cluster & don't have
214		 * CPC_Cx_CONFIG, so we read GCR_Cx_CONFIG.
215		 */
216		cfg = read_gcr_co_config();
217	} else {
218		/*
219		 * From CM 3.5 onwards we read CPC_Cx_CONFIG because the CPC is
220		 * always powered, which allows us to not worry about powering
221		 * up the cluster's CM here.
222		 */
223		cfg = read_cpc_co_config();
224	}
225
226	mips_cm_unlock_other();
227
228	return FIELD_GET(CM_GCR_Cx_CONFIG_PVPE, cfg + 1);
229}
230
231#endif /* __MIPS_ASM_MIPS_CPS_H__ */