time.c source code [linux/arch/hexagon/kernel/time.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* Time related functions for Hexagon architecture
4	*
5	* Copyright (c) 2010-2011, The Linux Foundation. All rights reserved.
6	*/
7
8	#include <linux/init.h>
9	#include <linux/clockchips.h>
10	#include <linux/clocksource.h>
11	#include <linux/interrupt.h>
12	#include <linux/err.h>
13	#include <linux/platform_device.h>
14	#include <linux/ioport.h>
15	#include <linux/of.h>
16	#include <linux/of_address.h>
17	#include <linux/of_irq.h>
18	#include <linux/module.h>
19
20	#include <asm/delay.h>
21	#include <asm/hexagon_vm.h>
22	#include <asm/time.h>
23
24	#define TIMER_ENABLE BIT(0)
25
26	/*
27	* For the clocksource we need:
28	* pcycle frequency (600MHz)
29	* For the loops_per_jiffy we need:
30	* thread/cpu frequency (100MHz)
31	* And for the timer, we need:
32	* sleep clock rate
33	*/
34
35	cycles_t pcycle_freq_mhz;
36	cycles_t thread_freq_mhz;
37	cycles_t sleep_clk_freq;
38
39	/*
40	* 8x50 HDD Specs 5-8. Simulator co-sim not fixed until
41	* release 1.1, and then it's "adjustable" and probably not defaulted.
42	*/
43	#define RTOS_TIMER_INT 3
44	#define RTOS_TIMER_REGS_ADDR 0xAB000000UL
45
46	static struct resource rtos_timer_resources[] = {
47	{
48	.start = RTOS_TIMER_REGS_ADDR,
49	.end = RTOS_TIMER_REGS_ADDR+PAGE_SIZE-`1`,
50	.flags = IORESOURCE_MEM,
51	},
52	};
53
54	static struct platform_device rtos_timer_device = {
55	.name = "rtos_timer",
56	.id = -`1`,
57	.num_resources = ARRAY_SIZE(rtos_timer_resources),
58	.resource = rtos_timer_resources,
59	};
60
61	/ A lot of this stuff should move into a platform specific section. /
62	struct adsp_hw_timer_struct {
63	u32 match; / Match value /
64	u32 count;
65	u32 enable; / [1] - CLR_ON_MATCH_EN, [0] - EN /
66	u32 clear; / one-shot register that clears the count /
67	};
68
69	/ Look for "TCX0" for related constants. /
70	static __iomem struct adsp_hw_timer_struct *rtos_timer;
71
72	static u64 timer_get_cycles(struct clocksource *cs)
73	{
74	return (u64) __vmgettime();
75	}
76
77	static struct clocksource hexagon_clocksource = {
78	.name = "pcycles",
79	.rating = `250`,
80	.read = timer_get_cycles,
81	.mask = CLOCKSOURCE_MASK(`64`),
82	.flags = CLOCK_SOURCE_IS_CONTINUOUS,
83	};
84
85	static int set_next_event(unsigned long delta, struct clock_event_device *evt)
86	{
87	/ Assuming the timer will be disabled when we enter here. /
88
89	iowrite32(`1`, &rtos_timer->clear);
90	iowrite32(`0`, &rtos_timer->clear);
91
92	iowrite32(delta, &rtos_timer->match);
93	iowrite32(TIMER_ENABLE, &rtos_timer->enable);
94	return `0`;
95	}
96
97	#ifdef CONFIG_SMP
98	/ Broadcast mechanism /
99	static void broadcast(const struct cpumask *mask)
100	{
101	send_ipi(mask, IPI_TIMER);
102	}
103	#endif
104
105	/ XXX Implement set_state_shutdown() /
106	static struct clock_event_device hexagon_clockevent_dev = {
107	.name = "clockevent",
108	.features = CLOCK_EVT_FEAT_ONESHOT,
109	.rating = `400`,
110	.irq = RTOS_TIMER_INT,
111	.set_next_event = set_next_event,
112	#ifdef CONFIG_SMP
113	.broadcast = broadcast,
114	#endif
115	};
116
117	#ifdef CONFIG_SMP
118	static DEFINE_PER_CPU(struct clock_event_device, clock_events);
119
120	void setup_percpu_clockdev(void)
121	{
122	int cpu = smp_processor_id();
123	struct clock_event_device *ce_dev = &hexagon_clockevent_dev;
124	struct clock_event_device *dummy_clock_dev =
125	&per_cpu(clock_events, cpu);
126
127	memcpy(dummy_clock_dev, ce_dev, sizeof(*dummy_clock_dev));
128	INIT_LIST_HEAD(list: &dummy_clock_dev->list);
129
130	dummy_clock_dev->features = CLOCK_EVT_FEAT_DUMMY;
131	dummy_clock_dev->cpumask = cpumask_of(cpu);
132
133	clockevents_register_device(dev: dummy_clock_dev);
134	}
135
136	/ Called from smp.c for each CPU's timer ipi call /
137	void ipi_timer(void)
138	{
139	int cpu = smp_processor_id();
140	struct clock_event_device *ce_dev = &per_cpu(clock_events, cpu);
141
142	ce_dev->event_handler(ce_dev);
143	}
144	#endif /* CONFIG_SMP */
145
146	static irqreturn_t timer_interrupt(int irq, void *devid)
147	{
148	struct clock_event_device *ce_dev = &hexagon_clockevent_dev;
149
150	iowrite32(`0`, &rtos_timer->enable);
151	ce_dev->event_handler(ce_dev);
152
153	return IRQ_HANDLED;
154	}
155
156	/*
157	* time_init_deferred - called by start_kernel to set up timer/clock source
158	*
159	* Install the IRQ handler for the clock, setup timers.
160	* This is done late, as that way, we can use ioremap().
161	*
162	* This runs just before the delay loop is calibrated, and
163	* is used for delay calibration.
164	*/
165	static void __init time_init_deferred(void)
166	{
167	struct resource *resource = NULL;
168	struct clock_event_device *ce_dev = &hexagon_clockevent_dev;
169	unsigned long flag = IRQF_TIMER \| IRQF_TRIGGER_RISING;
170
171	ce_dev->cpumask = cpu_all_mask;
172
173	if (!resource)
174	resource = rtos_timer_device.resource;
175
176	/ ioremap here means this has to run later, after paging init /
177	rtos_timer = ioremap(offset: resource->start, size: resource_size(res: resource));
178
179	if (!rtos_timer) {
180	release_mem_region(resource->start, resource_size(resource));
181	}
182	clocksource_register_khz(cs: &hexagon_clocksource, khz: pcycle_freq_mhz * `1000`);
183
184	/ Note: the sim generic RTOS clock is apparently really 18750Hz /
185
186	/*
187	* Last arg is some guaranteed seconds for which the conversion will
188	* work without overflow.
189	*/
190	clockevents_calc_mult_shift(ce: ce_dev, freq: sleep_clk_freq, maxsec: `4`);
191
192	ce_dev->max_delta_ns = clockevent_delta2ns(latch: `0x7fffffff`, evt: ce_dev);
193	ce_dev->max_delta_ticks = `0x7fffffff`;
194	ce_dev->min_delta_ns = clockevent_delta2ns(latch: `0xf`, evt: ce_dev);
195	ce_dev->min_delta_ticks = `0xf`;
196
197	#ifdef CONFIG_SMP
198	setup_percpu_clockdev();
199	#endif
200
201	clockevents_register_device(dev: ce_dev);
202	if (request_irq(irq: ce_dev->irq, handler: timer_interrupt, flags: flag, name: "rtos_timer", NULL))
203	pr_err("Failed to register rtos_timer interrupt\n");
204	}
205
206	void __init time_init(void)
207	{
208	late_time_init = time_init_deferred;
209	}
210
211	void __delay(unsigned long cycles)
212	{
213	unsigned long long start = __vmgettime();
214
215	while ((__vmgettime() - start) < cycles)
216	cpu_relax();
217	}
218	EXPORT_SYMBOL(__delay);
219
220	/*
221	* This could become parametric or perhaps even computed at run-time,
222	* but for now we take the observed simulator jitter.
223	*/
224	static long long fudgefactor = `350`; / Maybe lower if kernel optimized. /
225
226	void __udelay(unsigned long usecs)
227	{
228	unsigned long long start = __vmgettime();
229	unsigned long long finish = (pcycle_freq_mhz * usecs) - fudgefactor;
230
231	while ((__vmgettime() - start) < finish)
232	cpu_relax(); / not sure how this improves readability /
233	}
234	EXPORT_SYMBOL(__udelay);
235

source code of linux/arch/hexagon/kernel/time.c