fsl_rcpm.c source code [linux/arch/powerpc/sysdev/fsl_rcpm.c]

1	// SPDX-License-Identifier: GPL-2.0-or-later
2	/*
3	* RCPM(Run Control/Power Management) support
4	*
5	* Copyright 2012-2015 Freescale Semiconductor Inc.
6	*
7	* Author: Chenhui Zhao <chenhui.zhao@freescale.com>
8	*/
9
10	#define pr_fmt(fmt) "%s: " fmt, __func__
11
12	#include <linux/types.h>
13	#include <linux/errno.h>
14	#include <linux/of_address.h>
15	#include <linux/export.h>
16
17	#include <asm/io.h>
18	#include <linux/fsl/guts.h>
19	#include <asm/cputhreads.h>
20	#include <asm/fsl_pm.h>
21	#include <asm/smp.h>
22
23	static struct ccsr_rcpm_v1 __iomem *rcpm_v1_regs;
24	static struct ccsr_rcpm_v2 __iomem *rcpm_v2_regs;
25	static unsigned int fsl_supported_pm_modes;
26
27	static void rcpm_v1_irq_mask(int cpu)
28	{
29	int hw_cpu = get_hard_smp_processor_id(cpu);
30	unsigned int mask = `1` << hw_cpu;
31
32	setbits32(&rcpm_v1_regs->cpmimr, mask);
33	setbits32(&rcpm_v1_regs->cpmcimr, mask);
34	setbits32(&rcpm_v1_regs->cpmmcmr, mask);
35	setbits32(&rcpm_v1_regs->cpmnmimr, mask);
36	}
37
38	static void rcpm_v2_irq_mask(int cpu)
39	{
40	int hw_cpu = get_hard_smp_processor_id(cpu);
41	unsigned int mask = `1` << hw_cpu;
42
43	setbits32(&rcpm_v2_regs->tpmimr0, mask);
44	setbits32(&rcpm_v2_regs->tpmcimr0, mask);
45	setbits32(&rcpm_v2_regs->tpmmcmr0, mask);
46	setbits32(&rcpm_v2_regs->tpmnmimr0, mask);
47	}
48
49	static void rcpm_v1_irq_unmask(int cpu)
50	{
51	int hw_cpu = get_hard_smp_processor_id(cpu);
52	unsigned int mask = `1` << hw_cpu;
53
54	clrbits32(&rcpm_v1_regs->cpmimr, mask);
55	clrbits32(&rcpm_v1_regs->cpmcimr, mask);
56	clrbits32(&rcpm_v1_regs->cpmmcmr, mask);
57	clrbits32(&rcpm_v1_regs->cpmnmimr, mask);
58	}
59
60	static void rcpm_v2_irq_unmask(int cpu)
61	{
62	int hw_cpu = get_hard_smp_processor_id(cpu);
63	unsigned int mask = `1` << hw_cpu;
64
65	clrbits32(&rcpm_v2_regs->tpmimr0, mask);
66	clrbits32(&rcpm_v2_regs->tpmcimr0, mask);
67	clrbits32(&rcpm_v2_regs->tpmmcmr0, mask);
68	clrbits32(&rcpm_v2_regs->tpmnmimr0, mask);
69	}
70
71	static void rcpm_v1_set_ip_power(bool enable, u32 mask)
72	{
73	if (enable)
74	setbits32(&rcpm_v1_regs->ippdexpcr, mask);
75	else
76	clrbits32(&rcpm_v1_regs->ippdexpcr, mask);
77	}
78
79	static void rcpm_v2_set_ip_power(bool enable, u32 mask)
80	{
81	if (enable)
82	setbits32(&rcpm_v2_regs->ippdexpcr[`0`], mask);
83	else
84	clrbits32(&rcpm_v2_regs->ippdexpcr[`0`], mask);
85	}
86
87	static void rcpm_v1_cpu_enter_state(int cpu, int state)
88	{
89	int hw_cpu = get_hard_smp_processor_id(cpu);
90	unsigned int mask = `1` << hw_cpu;
91
92	switch (state) {
93	case E500_PM_PH10:
94	setbits32(&rcpm_v1_regs->cdozcr, mask);
95	break;
96	case E500_PM_PH15:
97	setbits32(&rcpm_v1_regs->cnapcr, mask);
98	break;
99	default:
100	pr_warn("Unknown cpu PM state (%d)\n", state);
101	break;
102	}
103	}
104
105	static void rcpm_v2_cpu_enter_state(int cpu, int state)
106	{
107	int hw_cpu = get_hard_smp_processor_id(cpu);
108	u32 mask = `1` << cpu_core_index_of_thread(cpu);
109
110	switch (state) {
111	case E500_PM_PH10:
112	/ one bit corresponds to one thread for PH10 of 6500 /
113	setbits32(&rcpm_v2_regs->tph10setr0, `1` << hw_cpu);
114	break;
115	case E500_PM_PH15:
116	setbits32(&rcpm_v2_regs->pcph15setr, mask);
117	break;
118	case E500_PM_PH20:
119	setbits32(&rcpm_v2_regs->pcph20setr, mask);
120	break;
121	case E500_PM_PH30:
122	setbits32(&rcpm_v2_regs->pcph30setr, mask);
123	break;
124	default:
125	pr_warn("Unknown cpu PM state (%d)\n", state);
126	}
127	}
128
129	static void rcpm_v1_cpu_die(int cpu)
130	{
131	rcpm_v1_cpu_enter_state(cpu, state: E500_PM_PH15);
132	}
133
134	#ifdef CONFIG_PPC64
135	static void qoriq_disable_thread(int cpu)
136	{
137	int thread = cpu_thread_in_core(cpu);
138
139	book3e_stop_thread(thread);
140	}
141	#endif
142
143	static void rcpm_v2_cpu_die(int cpu)
144	{
145	#ifdef CONFIG_PPC64
146	int primary;
147
148	if (threads_per_core == `2`) {
149	primary = cpu_first_thread_sibling(cpu);
150	if (cpu_is_offline(primary) && cpu_is_offline(primary + `1`)) {
151	/ if both threads are offline, put the cpu in PH20 /
152	rcpm_v2_cpu_enter_state(cpu, E500_PM_PH20);
153	} else {
154	/ if only one thread is offline, disable the thread /
155	qoriq_disable_thread(cpu);
156	}
157	}
158	#endif
159
160	if (threads_per_core == `1`)
161	rcpm_v2_cpu_enter_state(cpu, state: E500_PM_PH20);
162	}
163
164	static void rcpm_v1_cpu_exit_state(int cpu, int state)
165	{
166	int hw_cpu = get_hard_smp_processor_id(cpu);
167	unsigned int mask = `1` << hw_cpu;
168
169	switch (state) {
170	case E500_PM_PH10:
171	clrbits32(&rcpm_v1_regs->cdozcr, mask);
172	break;
173	case E500_PM_PH15:
174	clrbits32(&rcpm_v1_regs->cnapcr, mask);
175	break;
176	default:
177	pr_warn("Unknown cpu PM state (%d)\n", state);
178	break;
179	}
180	}
181
182	static void rcpm_v1_cpu_up_prepare(int cpu)
183	{
184	rcpm_v1_cpu_exit_state(cpu, state: E500_PM_PH15);
185	rcpm_v1_irq_unmask(cpu);
186	}
187
188	static void rcpm_v2_cpu_exit_state(int cpu, int state)
189	{
190	int hw_cpu = get_hard_smp_processor_id(cpu);
191	u32 mask = `1` << cpu_core_index_of_thread(cpu);
192
193	switch (state) {
194	case E500_PM_PH10:
195	setbits32(&rcpm_v2_regs->tph10clrr0, `1` << hw_cpu);
196	break;
197	case E500_PM_PH15:
198	setbits32(&rcpm_v2_regs->pcph15clrr, mask);
199	break;
200	case E500_PM_PH20:
201	setbits32(&rcpm_v2_regs->pcph20clrr, mask);
202	break;
203	case E500_PM_PH30:
204	setbits32(&rcpm_v2_regs->pcph30clrr, mask);
205	break;
206	default:
207	pr_warn("Unknown cpu PM state (%d)\n", state);
208	}
209	}
210
211	static void rcpm_v2_cpu_up_prepare(int cpu)
212	{
213	rcpm_v2_cpu_exit_state(cpu, state: E500_PM_PH20);
214	rcpm_v2_irq_unmask(cpu);
215	}
216
217	static int rcpm_v1_plat_enter_state(int state)
218	{
219	u32 *pmcsr_reg = &rcpm_v1_regs->powmgtcsr;
220	int ret = `0`;
221	int result;
222
223	switch (state) {
224	case PLAT_PM_SLEEP:
225	setbits32(pmcsr_reg, RCPM_POWMGTCSR_SLP);
226
227	/ Upon resume, wait for RCPM_POWMGTCSR_SLP bit to be clear. /
228	result = spin_event_timeout(
229	!(in_be32(pmcsr_reg) & RCPM_POWMGTCSR_SLP), `10000`, `10`);
230	if (!result) {
231	pr_err("timeout waiting for SLP bit to be cleared\n");
232	ret = -ETIMEDOUT;
233	}
234	break;
235	default:
236	pr_warn("Unknown platform PM state (%d)", state);
237	ret = -EINVAL;
238	}
239
240	return ret;
241	}
242
243	static int rcpm_v2_plat_enter_state(int state)
244	{
245	u32 *pmcsr_reg = &rcpm_v2_regs->powmgtcsr;
246	int ret = `0`;
247	int result;
248
249	switch (state) {
250	case PLAT_PM_LPM20:
251	/ clear previous LPM20 status /
252	setbits32(pmcsr_reg, RCPM_POWMGTCSR_P_LPM20_ST);
253	/ enter LPM20 status /
254	setbits32(pmcsr_reg, RCPM_POWMGTCSR_LPM20_RQ);
255
256	/ At this point, the device is in LPM20 status. /
257
258	/ resume ... /
259	result = spin_event_timeout(
260	!(in_be32(pmcsr_reg) & RCPM_POWMGTCSR_LPM20_ST), `10000`, `10`);
261	if (!result) {
262	pr_err("timeout waiting for LPM20 bit to be cleared\n");
263	ret = -ETIMEDOUT;
264	}
265	break;
266	default:
267	pr_warn("Unknown platform PM state (%d)\n", state);
268	ret = -EINVAL;
269	}
270
271	return ret;
272	}
273
274	static int rcpm_v1_plat_enter_sleep(void)
275	{
276	return rcpm_v1_plat_enter_state(state: PLAT_PM_SLEEP);
277	}
278
279	static int rcpm_v2_plat_enter_sleep(void)
280	{
281	return rcpm_v2_plat_enter_state(state: PLAT_PM_LPM20);
282	}
283
284	static void rcpm_common_freeze_time_base(u32 tben_reg, int* freeze)
285	{
286	static u32 mask;
287
288	if (freeze) {
289	mask = in_be32(tben_reg);
290	clrbits32(tben_reg, mask);
291	} else {
292	setbits32(tben_reg, mask);
293	}
294
295	/ read back to push the previous write /
296	in_be32(tben_reg);
297	}
298
299	static void rcpm_v1_freeze_time_base(bool freeze)
300	{
301	rcpm_common_freeze_time_base(tben_reg: &rcpm_v1_regs->ctbenr, freeze);
302	}
303
304	static void rcpm_v2_freeze_time_base(bool freeze)
305	{
306	rcpm_common_freeze_time_base(tben_reg: &rcpm_v2_regs->pctbenr, freeze);
307	}
308
309	static unsigned int rcpm_get_pm_modes(void)
310	{
311	return fsl_supported_pm_modes;
312	}
313
314	static const struct fsl_pm_ops qoriq_rcpm_v1_ops = {
315	.irq_mask = rcpm_v1_irq_mask,
316	.irq_unmask = rcpm_v1_irq_unmask,
317	.cpu_enter_state = rcpm_v1_cpu_enter_state,
318	.cpu_exit_state = rcpm_v1_cpu_exit_state,
319	.cpu_up_prepare = rcpm_v1_cpu_up_prepare,
320	.cpu_die = rcpm_v1_cpu_die,
321	.plat_enter_sleep = rcpm_v1_plat_enter_sleep,
322	.set_ip_power = rcpm_v1_set_ip_power,
323	.freeze_time_base = rcpm_v1_freeze_time_base,
324	.get_pm_modes = rcpm_get_pm_modes,
325	};
326
327	static const struct fsl_pm_ops qoriq_rcpm_v2_ops = {
328	.irq_mask = rcpm_v2_irq_mask,
329	.irq_unmask = rcpm_v2_irq_unmask,
330	.cpu_enter_state = rcpm_v2_cpu_enter_state,
331	.cpu_exit_state = rcpm_v2_cpu_exit_state,
332	.cpu_up_prepare = rcpm_v2_cpu_up_prepare,
333	.cpu_die = rcpm_v2_cpu_die,
334	.plat_enter_sleep = rcpm_v2_plat_enter_sleep,
335	.set_ip_power = rcpm_v2_set_ip_power,
336	.freeze_time_base = rcpm_v2_freeze_time_base,
337	.get_pm_modes = rcpm_get_pm_modes,
338	};
339
340	static const struct of_device_id rcpm_matches[] = {
341	{
342	.compatible = "fsl,qoriq-rcpm-1.0",
343	.data = &qoriq_rcpm_v1_ops,
344	},
345	{
346	.compatible = "fsl,qoriq-rcpm-2.0",
347	.data = &qoriq_rcpm_v2_ops,
348	},
349	{
350	.compatible = "fsl,qoriq-rcpm-2.1",
351	.data = &qoriq_rcpm_v2_ops,
352	},
353	{},
354	};
355
356	int __init fsl_rcpm_init(void)
357	{
358	struct device_node *np;
359	const struct of_device_id *match;
360	void __iomem *base;
361
362	np = of_find_matching_node_and_match(NULL, matches: rcpm_matches, match: &match);
363	if (!np)
364	return `0`;
365
366	base = of_iomap(node: np, index: `0`);
367	of_node_put(node: np);
368	if (!base) {
369	pr_err("of_iomap() error.\n");
370	return -ENOMEM;
371	}
372
373	rcpm_v1_regs = base;
374	rcpm_v2_regs = base;
375
376	/ support sleep by default /
377	fsl_supported_pm_modes = FSL_PM_SLEEP;
378
379	qoriq_pm_ops = match->data;
380
381	return `0`;
382	}
383

source code of linux/arch/powerpc/sysdev/fsl_rcpm.c