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bos_ucos_ii.c @ 2

Last change on this file since 2 was 2, checked in by phkim, 11 years ago

1.phkim

revision copy newcon3sk r27

Property svn:executable set to *

File size: 34.2 KB

Line
1	/***************************************************************
2	**
3	** Broadcom Corp. Confidential
4	** Copyright 1998-2000 Broadcom Corp. All Rights Reserved.
5	**
6	** THIS SOFTWARE MAY ONLY BE USED SUBJECT TO AN EXECUTED
7	** SOFTWARE LICENSE AGREEMENT BETWEEN THE USER AND BROADCOM.
8	** YOU HAVE NO RIGHT TO USE OR EXPLOIT THIS MATERIAL EXCEPT
9	** SUBJECT TO THE TERMS OF SUCH AN AGREEMENT.
10	**
11	** File: bos.c
12	** Description: encapsulate OS functions.
13	**
14	** Created: Mon Sep 25 18:12:35 PDT 2006 by Jeff Fisher
15	**
16	**
17	**
18	****************************************************************/
19
20	#define BOS_C
21	#include "bos.h"
22	#include "ucos_ii.h"
23	#include "bchp_timer.h"
24	#include "bstd.h"
25	#include "bchp_sun_top_ctrl.h"
26	#include "bchp_xpt_fe.h"
27	#include "bcm_mips.h"
28	#include "bcm_mips_defs.h"
29	#include "ministd.h"
30	#include "bcmmemmgr.h"
31	#ifdef UCOS_USB
32	#include "usbh_cfg.h"
33	#endif
34
35	BDBG_MODULE(bos);
36
37	struct b_task_stats g_os_task_stats[OS_LOWEST_PRIO+2];
38
39	extern uint32_t expt_stack;
40	#define INIT_STACK_SIZE 0x2000
41	#define B_OS_STK_FILL_BYTE 0xBB
42	#define B_OS_STK_FILL_INT32 0xBBBBBBBB
43	extern const char bsymtable_get_name(uint32_t addr, char buf, size_t buf_len);
44
45	void b_os_check_stack(b_task_stats *task, uint32_t pattern) __attribute__((always_inline));
46	//unsigned int calc_mips_freq(void) __attribute__((always_inline));
47	extern unsigned long MIPS_SetInterrupts(unsigned long new_sr);
48	#define OS_DISABLE 0
49
50	extern void bint_handler(void);
51	b_system_globals_t g_dsp;
52	b_system_globals_t *g_p_dsp = &g_dsp;
53
54
55	struct b_last_ctxsw
56	{
57	unsigned clock; /* value of MIPS clock when task was switched in */
58	unsigned instr;
59	} g_last_ctxsw;
60
61	static inline void dump(const char name, const void addr, size_t nelem)
62	{
63	unsigned off;
64
65	printf("%s: %u bytes from %p\n", name, nelem, addr);
66	for (off=0;off<nelem;)
67	{
68	unsigned i;
69
70	printf("0x%08X: ", off+(unsigned)addr);
71	for (i=0;i<16 && off<nelem;i++,off++)
72	{
73	printf("%02x ", ((uint8_t *)addr)[off]);
74	}
75	printf("\n");
76	}
77	printf("-----------------------------------------\n");
78	return;
79	}
80
81	/***************************************************************************
82	* Determine the MIPS frequency in HZ using a known timer
83	*/
84	#if (BCHP_CHIP==7550)
85	#define TIMER_DIVISOR 1
86	#define TIMER_SHIFT 9
87	/* bits 32-9 of this register increment at 90000Hz by default */
88	#define CLOCK_REGISTER (BCHP_XPT_FE_PARSER0_TIMESTAMP \| 0xB0000000)
89	#else
90	#define TIMER_DIVISOR 1
91	#define TIMER_SHIFT 9
92	#define CLOCK_REGISTER (BCHP_XPT_FE_ATS_TS_MOD300 \| 0xB0000000)
93	#include "bchp_timer.h"
94	#ifndef BCHP_K0_OFFSET
95	#define BCHP_K0_OFFSET (0xA0000000 \| 0x10000000)
96	#endif
97	#ifndef WriteReg32
98	#define WriteReg32(x,v) { ((volatile unsigned int)(BCHP_K0_OFFSET + (unsigned int)(x))) = (v); }
99	#endif
100	#ifndef ReadReg32
101	#define ReadReg32(x) ((volatile unsigned int)(BCHP_K0_OFFSET + (unsigned int)(x)))
102	#endif
103	#endif
104
105	inline unsigned int calc_mips_freq(void)
106	{
107	#if (BCHP_CHIP==7550)
108	/* we can't use register macros since BKNI is not initialized yet */
109	volatile uint32_t * clock_ptr = (uint32_t *)CLOCK_REGISTER;
110	uint32_t clock, end_clock;
111	uint32_t count;
112
113	clock = *clock_ptr >> TIMER_SHIFT;
114	count = bcm_read_cp0($9,0);
115	end_clock = clock + 90000/TIMER_DIVISOR;
116	do
117	{
118	clock = *clock_ptr >> TIMER_SHIFT;
119	}while (end_clock - clock);
120	count = bcm_read_cp0($9,0) - count;
121	return(count);
122	#else
123	uint32_t tenth_of_a_second = 0x2932E0; /* 27000000 */
124	uint32_t start_count,end_count,freq;
125	WriteReg32(BCHP_TIMER_TIMER0_CTRL,
126	tenth_of_a_second \| BCHP_TIMER_TIMER0_CTRL_MODE_MASK \| BCHP_TIMER_TIMER0_CTRL_ENA_MASK);
127
128	start_count = bcm_read_cp0($9,0);
129
130	WriteReg32(BCHP_TIMER_TIMER_IS,BCHP_TIMER_TIMER_IS_TMR0TO_MASK);
131
132	do
133	{
134	}while (!(ReadReg32(BCHP_TIMER_TIMER_IS) & BCHP_TIMER_TIMER_IS_TMR0TO_MASK));
135
136	end_count = bcm_read_cp0($9,0);
137	freq = (end_count - start_count) * 10;
138	return freq;
139	#endif
140	}
141
142
143	/******************************************************************************
144	* INPUTS: none
145	* OUTPUTS: none.
146	* RETURNS: none
147	* FUNCTION: initialize ucos
148	******************************************************************************/
149	void bos_unhandled_handler(register_t * registers)
150	{
151	g_p_dsp->b_in_interrupt = 1;
152	OSIntEnter();
153
154	gdb_handler((unsigned int*)registers, registers[ROFF_CAUSE]);
155
156	OSIntExit();
157	g_p_dsp->b_in_interrupt = 0;
158	}
159
160	/******************************************************************************
161	* INPUTS: none
162	* OUTPUTS: none.
163	* RETURNS: none
164	* FUNCTION: initialize ucos
165	******************************************************************************/
166	void bos_handler(register_t * registers)
167	{
168	register_t cause;
169	register_t compare;
170	register_t status;
171	uint32_t clock;
172	uint32_t exit_clock;
173	uint32_t instr_enter;
174	uint32_t instr_exit;
175	struct b_task_stats *cur_stats;
176
177	clock = bcm_read_cp0($9,0);
178	instr_enter = bcm_read_cp0($25, 2);
179
180	cur_stats = &g_os_task_stats[OSTCBCur->OSTCBPrio];
181
182	status = registers[ROFF_SR];
183	if (0 == (status & ST0_IE))
184	{
185	/* We are trying to enter critical section. Just return. */
186	return;
187	}
188
189	cause = registers[ROFF_CAUSE];
190
191	g_p_dsp->b_in_interrupt = 1;
192	OSIntEnter();
193	g_stat_isr_cnt++;
194
195	cause = (cause >> 8) & 0xFF;
196	if (cause & 0x80)
197	{ /* timer interrupt */
198	bos_trace(eTRACE_TICK,OSPrioHighRdy,OSTCBCur->OSTCBPrio,clock);
199	/* update 64 bit clock counter */
200	if (clock < g_running_clock.clock_low)
201	{ /* overflow */
202	g_running_clock.clock_hi++;
203	}
204	g_running_clock.clock_low = clock;
205	#if 0
206	{
207	compare = clock + OS_HW_TICKS; /* 939391 with 375 MH frequency */
208
209	__asm__("mtc0 %0, $11"::"r"(compare));
210	//__asm__("nop");
211	}
212	#else
213	__asm__("mfc0 %0, $11":"=r"(compare));
214	do
215	{
216	compare += OS_HW_TICKS;
217	} while ((compare - clock) > OS_HW_TICKS);
218	__asm__("mtc0 %0, $11"::"r"(compare));
219	__asm__("nop");
220	#endif
221	OSTimeTick();
222	}
223	if (0x4 & cause)
224	{ /* chip interrupt */
225	unsigned long status;
226	status = bcm_read_cp0($12,0);
227	bcm_write_cp0($12, 0, (status & 0xFFFFFFFCUL));
228
229	bint_handler();
230
231	bcm_write_cp0($12, 0, status);
232	}
233	if (~0x84 & cause)
234	{
235	bos_unhandled_handler(registers);
236	}
237	OSIntExit();
238	exit_clock = bcm_read_cp0($9,0);
239	instr_exit = bcm_read_cp0($25, 2);
240	if (!(cause & 0x20))
241	{
242	g_stat_isr_time += exit_clock - clock; /* update isr time */
243	g_p_dsp->stat_isr_cnt = instr_enter - instr_exit;
244	cur_stats->clock_cnt -= exit_clock - clock; /* adjust current task */
245	cur_stats->instr_cnt -= instr_enter - instr_exit;
246	}
247	g_p_dsp->b_in_interrupt = 0;
248	}
249
250
251	/******************************************************************************
252	* INPUTS: none
253	* OUTPUTS: none.
254	* RETURNS: none
255	* FUNCTION: initialize ucos
256	******************************************************************************/
257
258
259	static const char idle[]="idle";
260	static const char isr[]="ISR";
261	static const char stat[]="stat";
262	static const char usb_async[]="usb";
263
264	void bos_init(void)
265	{
266	int i;
267	unsigned int mips_freq;
268
269	mips_freq = calc_mips_freq();
270
271	memset(g_p_dsp,0,sizeof(b_system_globals_t));
272
273	g_p_dsp->b_ticks_per_second = g_ticks_per_second;
274	g_running_clock.clock_freq = mips_freq;
275	g_cycles_per_tick = (mips_freq/g_ticks_per_second);
276	OSRegisterException(0, bos_handler, NULL);
277	for (i = 1; i < 32; ++i)
278	{
279	/* Skip Syscall */
280	if (i != 8)
281	OSRegisterException(i, bos_unhandled_handler, NULL);
282	}
283
284	/* wipe out task statistics */
285	memset(g_os_task_stats, 0, sizeof(g_os_task_stats));
286
287	/* initialize ISR pseudo task */
288	g_os_task_stats[OS_LOWEST_PRIO+1].last_time = g_os_task_stats[OS_LOWEST_PRIO].last_time;
289	memcpy(g_os_task_stats[OS_LOWEST_PRIO+1].name, isr, sizeof(isr));
290	g_os_task_stats[OS_LOWEST_PRIO+1].stack = &expt_stack;
291	g_os_task_stats[OS_LOWEST_PRIO+1].stack_size = INIT_STACK_SIZE/sizeof(uint32_t);
292	g_os_task_stats[OS_LOWEST_PRIO+1].stack_left = INIT_STACK_SIZE/sizeof(uint32_t);
293	g_os_task_stats[OS_LOWEST_PRIO+1].stack_fast_scan = 0;
294
295	bcm_write_cp0($25, 6, 0x80000211); /* DCACHE and Instruction/Cycle counter */
296	bcm_write_cp0($25, 4, 0x80288024);
297	bcm_write_cp0($25, 5, 0x80488044);
298
299	bcm_write_cp0($25, 0, 0) /* PerfCount0 reset to 0 (it is a decrementing count) */
300	bcm_write_cp0($25, 1, 0) /* PerfCount1 reset to 0 (it is a decrementing count) */
301	bcm_write_cp0($25, 2, 0) /* PerfCount2 reset to 0 (it is a decrementing count) */
302	bcm_write_cp0($25, 3, 0) /* PerfCount3 reset to 0 (it is a decrementing count) */
303
304	OSInit();
305
306	return;
307	}
308
309
310	static struct
311	{
312	b_timeval last_time;
313	unsigned calib_idle_ticks;
314	unsigned calib_ms;
315	unsigned last_idle_ctr;
316	unsigned last_ctxsw_ctr;
317	unsigned last_isr_cnt;
318	unsigned last_isr_time;
319	} b_os_load_data;
320
321	/* returns difference between two timevals in ms */
322	static unsigned
323	b_os_tv_diff(const b_timeval end, const b_timeval begin)
324	{
325	unsigned ms;
326
327	ms = ((int)(end->tv_usec - begin->tv_usec))/1000;
328	ms += (end->tv_sec - begin->tv_sec)*1000;
329	if (ms==0)
330	{
331	ms=1;
332	}
333	return ms;
334	}
335
336	#ifdef CONFIG_ENABLE_EMU
337	#define B_OS_IDLE_SCALE 10
338	#else
339	#define B_OS_IDLE_SCALE 1
340	#endif
341
342	/* this function calibrates how fast IDLE task runs */
343	void
344	bos_calibrate(void)
345	{
346	unsigned int flags;
347	#ifndef CONFIG_ENABLE_SIM
348	b_timeval start;
349	unsigned int idle_ctr;
350
351	GETTIMEOFDAY(&start);
352	idle_ctr = OSIdleCtr;
353	bos_sleep(100/B_OS_IDLE_SCALE);
354	#endif
355	GETTIMEOFDAY(&b_os_load_data.last_time);
356
357	flags=bos_enter_critical();
358	b_os_load_data.last_idle_ctr = OSIdleCtr;
359	b_os_load_data.last_ctxsw_ctr = OSCtxSwCtr;
360	b_os_load_data.last_isr_time = g_stat_isr_time;
361	b_os_load_data.last_isr_cnt = g_stat_isr_cnt;
362	#ifndef CONFIG_ENABLE_SIM
363	b_os_load_data.calib_idle_ticks = (b_os_load_data.last_idle_ctr - idle_ctr)B_OS_IDLE_SCALE; / prescale idle_ticks, 20 */
364	b_os_load_data.calib_ms = b_os_tv_diff(&b_os_load_data.last_time, &start)B_OS_IDLE_SCALE; / 96 ms */
365	#else
366
367	/* These values assume the mips is running at 250MHz (i.e. STRAP_CPU_SPEED_1) */
368	b_os_load_data.calib_idle_ticks = 364;
369	b_os_load_data.calib_ms = 95;
370	#endif
371	bos_exit_critical(flags);
372	BDBG_MSG(("calib_idle_ticks %u calib_ms %u\n", b_os_load_data.calib_idle_ticks, b_os_load_data.calib_ms));
373	return;
374	}
375
376	/******************************************************************************
377	* INPUTS: none
378	* OUTPUTS: none.
379	* RETURNS: none
380	* FUNCTION: start ucos
381	******************************************************************************/
382	void bos_start(void)
383	{
384	#if 0
385	unsigned int count;
386
387	/* Ensure timer interrupt does not fire before OSStart has completed. If it does
388	then we will see a race condition where the realExcHandler will try and dereference
389	OSTCBCur before it has been initialised. This will result in a TLB exception being
390	generated because of a NULL pointer exception. */
391	count = bcm_read_cp0($9,0);
392	count += (g_cycles_per_tick * g_ticks_per_second) / 1000; /* 1ms wait */
393	bcm_write_cp0($11,0,count);
394	#endif
395	OSStart();
396	};
397
398	void OSTaskCreateHook(OS_TCB *ptcb)
399	{
400	struct b_task_stats *stat = &g_os_task_stats[ptcb->OSTCBPrio];
401
402	BDBG_ASSERT(ptcb->OSTCBPrio <= OS_LOWEST_PRIO);
403
404	if (ptcb->OSTCBPrio == 2)
405	{
406	printf("Stack[%03d] = 0x%08x-0x%08x %d words\n",ptcb->OSTCBPrio,stat->stack,ptcb->OSTCBStkPtr,stat->stack_size);
407	}
408
409
410	if (!stat->stack && (ptcb->OSTCBStkSize > 0))
411	{
412	stat->stack = (const uint32_t*)ptcb->OSTCBStkBottom;
413	stat->clock_cnt = 0;
414	stat->instr_cnt = 0;
415	stat->active_cnt = 0;
416	stat->stack_size = ptcb->OSTCBStkSize;
417	stat->stack_left = ptcb->OSTCBStkSize;
418	stat->stack_fast_scan = 0;
419	#if (OS_TASK_STAT_STK_CHK_EN == 0)
420	memset((void)stat->stack, B_OS_STK_FILL_BYTE,((ptcb->OSTCBStkSize - OS_FRAME_SIZE ) 4) - 4);
421	#endif
422	#if OS_TASK_NAME_SIZE > 1
423	strncpy(stat->name,ptcb->OSTCBTaskName,16);
424	#endif
425	}
426	printf("Stack[%03d] = 0x%08x-0x%08x %d words\n",ptcb->OSTCBPrio,stat->stack,ptcb->OSTCBStkPtr,stat->stack_size);
427	}
428
429
430	/******************************************************************************
431	* Create a task
432	******************************************************************************/
433	bresult bos_start_task(
434	b_task_t handle, / [out] new thread handle, passed to b_stop_task when finished */
435	const b_task_params params, / optional param structure containing Priority, task name, and stack size */
436	b_task_func func, /* function to be called by new thread */
437	void data / data passed func */
438	)
439	{
440	struct b_task_stats *stat = &g_os_task_stats[params->priority];
441	stat->name[sizeof(stat->name)-1]='\0';
442	memcpy(stat->name, params->name, sizeof(stat->name)-2);
443	#if (OS_TASK_STAT_STK_CHK_EN == 0)
444	memset(params->stack, B_OS_STK_FILL_BYTE, params->stack_size*sizeof(uint32_t));
445	#endif
446
447	/* check to make sure no duplicate use of same task */
448	#if 0//BKTEMP
449	if(NULL == stat->stack)
450	BDBG_WRN(("\n\nERR: task stack [%s] %d\n\n",stat->name, params->priority));
451	#else
452	BDBG_ASSERT(NULL == stat->stack);
453	#endif
454	stat->stack = (const uint32_t*)params->stack;
455	stat->stack_size = params->stack_size;
456	stat->stack_left = params->stack_size;
457	stat->clock_cnt = 0;
458	stat->instr_cnt = 0;
459	stat->active_cnt = 0;
460	stat->stack_fast_scan = 0;
461	BDBG_WRN(("TASK [%s] %d\n", stat->name, params->priority ));
462
463	*handle = params->priority;
464
465	if (OSTaskCreateExt(func,data,(OS_STK*)&params->stack[params->stack_size - 1],
466	params->priority,params->priority,(OS_STK*)params->stack,params->stack_size,
467	NULL,OS_TASK_OPT_STK_CHK \| OS_TASK_OPT_STK_CLR) != OS_NO_ERR)
468	{
469	return berr_invalid_parameter;
470	}
471	return b_ok;
472	}
473
474	/******************************************************************************
475	* Stop/delete a task
476	******************************************************************************/
477	void bos_stop_task(b_task_t handle)
478	{
479	#if OS_TASK_DEL_EN > 0
480	INT8U err;
481	INT8U prio = (handle == OS_PRIO_SELF)?OSTCBCur->OSTCBPrio:handle;
482	memset(&g_os_task_stats[prio],0, sizeof(b_task_stats));
483	err = OSTaskDel(handle);
484	if(OS_ERR_NONE != err){
485	BDBG_ERR(("%d:%02x",__LINE__,err));
486	}
487	#endif
488	}
489
490	/******************************************************************************
491	* create an event queue using the even pool provided.
492	******************************************************************************/
493	bresult bos_create_queue(
494	b_queue_t handle, / new event queue */
495	b_event_t events, / event buffer of size num_events */
496	int num_events /* number of events in event buffer */
497	)
498	{
499	/* TODO check queue size does not exceed UINT16 */
500	OS_EVENT* p_os_event = OSQCreate((void**)events,(INT16U)(num_events));
501	if (p_os_event)
502	{
503	*handle = (b_queue_t)p_os_event;
504	return b_ok;
505	}
506	*handle = (b_queue_t)NULL;
507	return berr_out_of_memory;
508	}
509
510	/******************************************************************************
511	* delete an event queue..
512	******************************************************************************/
513	void bos_delete_queue(
514	b_queue_t handle / event queue */
515	)
516	{
517	#if OS_Q_DEL_EN > 0
518	INT8U err;
519	handle = (b_queue_t)OSQDel((OS_EVENT)(*handle),OS_DEL_ALWAYS,&err);
520	if(OS_ERR_NONE != err){
521	BDBG_ERR(("%d:%02x",__LINE__,err));
522	}
523	#endif
524	}
525
526	/******************************************************************************
527	* Post and event to the queue..
528	******************************************************************************/
529	bresult bos_post_event(
530	b_queue_t handle, /* event queue */
531	b_event_t event / event to post */
532	)
533	{
534	INT8U err;
535	if ((err = OSQPost((OS_EVENT*)handle,event)) != OS_NO_ERR)
536	{
537	//BKNI_Printf("OSQPost err = %d\n",err);
538
539	return berr_external_error;
540	}
541	return b_ok;
542	}
543
544	/******************************************************************************
545	* Wait for an event..
546	******************************************************************************/
547	b_event_t *bos_pend_event(
548	b_queue_t handle, /* event queue */
549	int timeout_ms /* timeout in milliseconds */
550	)
551	{
552	INT8U err;
553	if (!handle)
554	{
555	volatile int null=0;null=*null;
556	}
557
558	if (timeout_ms == 0)
559	{
560	return(b_event_t)OSQAccept((OS_EVENT)handle,&err);
561	}
562	else if (timeout_ms < 0)
563	{
564	b_event_t *p_evt;
565	while ((p_evt = (b_event_t)OSQPend((OS_EVENT)handle,0xFFFF,&err)) == NULL)
566	{
567	if ((err != OS_ERR_NONE) && (err != OS_ERR_TIMEOUT))
568	{
569	//BKNI_Printf("OSQPend err = %d\n",err);
570	//__asm__("sdbbp");
571	p_evt = NULL;
572
573	break;
574	}
575	}
576	return p_evt;
577	}
578	else if (timeout_ms < TICKS_TO_MS(1))
579	{ /* set timeout as 1 tick if timeout_ms is lower than 1 tick time */
580	timeout_ms = TICKS_TO_MS(1);
581	}
582	return(b_event_t)OSQPend((OS_EVENT)handle,MS_TO_TICKS(timeout_ms),&err);
583	}
584
585	/******************************************************************************
586	* create an event queue using the even pool provided.
587	******************************************************************************/
588	bresult bos_create_mutex(
589	b_mutex_t handle / mutex reference */
590	)
591	{
592	OS_EVENT* p_os_event = OSQCreate((void**)&handle->event_queue,1);
593	if (p_os_event)
594	{
595	handle->queue = (b_queue_t)p_os_event;
596	return bos_post_event(handle->queue,&(handle->event));
597	}
598	return berr_out_of_memory;
599	}
600
601	/******************************************************************************
602	* delete an event queue..
603	******************************************************************************/
604	void bos_delete_mutex(
605	b_mutex_t handle / mutex reference */
606	)
607	{
608	#if OS_Q_DEL_EN > 0
609	INT8U err;
610	OSQDel((OS_EVENT*)handle->queue,OS_DEL_ALWAYS,&err);
611	if(OS_ERR_NONE != err){
612	BDBG_ERR(("%d:%02x",__LINE__,err));
613	}
614	#endif
615	}
616
617	/******************************************************************************
618	* Post and event to the queue..
619	******************************************************************************/
620	bresult bos_acquire_mutex(
621	b_mutex_t handle, / mutex reference */
622	int timeout_ms /* timeout in milliseconds */
623	)
624	{
625	return(bos_pend_event(handle->queue,timeout_ms) != NULL) ? b_ok : berr_timeout;
626	}
627
628	/******************************************************************************
629	* Wait for an event..
630	******************************************************************************/
631	bresult bos_release_mutex(
632	b_mutex_t handle / event queue */
633	)
634	{
635	return bos_post_event(handle->queue,&handle->event);
636	}
637
638	/******************************************************************************
639	* Sleep for sleep_ms milliseconds..
640	******************************************************************************/
641
642	void bos_sleep(
643	unsigned int sleep_ms /* number of milliseconds to delay */
644	)
645	{
646	unsigned int ticks = MS_TO_TICKS(sleep_ms);
647	if (ticks <= 0)
648	{
649	ticks = 1;
650	}
651	OSTimeDly(ticks);
652	}
653	/******************************************************************************
654	* Enter critical section..
655	******************************************************************************/
656	unsigned int bos_enter_critical(void)
657	{
658	unsigned int flags;
659	//OS_ENTER_CRITICAL(flags);
660	flags = MIPS_SetInterrupts(OS_DISABLE);
661	return flags;
662	}
663	/******************************************************************************
664	* Exit critical section..
665	******************************************************************************/
666	void bos_exit_critical(unsigned int flags)
667	{
668	MIPS_SetInterrupts(flags);
669	//OS_EXIT_CRITICAL(flags);
670	}
671
672	/******************************************************************************
673	* Return the current OS tick count.
674	******************************************************************************/
675
676	unsigned int bos_getticks(void)
677	{
678	return OSTimeGet();
679	}
680
681	/******************************************************************************
682	* Return the current clock.
683	******************************************************************************/
684
685	void bos_getclock(b_clock *clock)
686	{
687	unsigned int flags;
688	uint32_t mips_clock;
689
690	flags = bos_enter_critical();
691	mips_clock = bcm_read_cp0($9,0);
692	/* update 64 bit clock counter */
693	if (mips_clock < g_running_clock.clock_low)
694	{ /* overflow */
695	g_running_clock.clock_hi++;
696	}
697	g_running_clock.clock_low = mips_clock;
698	clock->clock_hi = g_running_clock.clock_hi;
699	bos_exit_critical(flags);
700	clock->clock_low = mips_clock;
701	clock->clock_freq = g_running_clock.clock_freq;
702	}
703
704
705	void bos_getload(b_cpu_load *load)
706	{
707	b_timeval now;
708	unsigned long flags;
709	unsigned idle_ctr;
710	unsigned mips_freq;
711
712	if ((b_os_load_data.calib_ms==0) \|\| (0 == b_os_load_data.calib_idle_ticks))
713	{
714	BDBG_WRN(("calib_ms = %d, calib_idle_ticks = %d\n",b_os_load_data.calib_ms,b_os_load_data.calib_idle_ticks));
715	goto error;
716	}
717	GETTIMEOFDAY(&now);
718	flags = bos_enter_critical();
719	idle_ctr = OSIdleCtr - b_os_load_data.last_idle_ctr;
720	load->ctxsw_rate = OSCtxSwCtr - b_os_load_data.last_ctxsw_ctr;
721	load->isr = g_stat_isr_time - b_os_load_data.last_isr_time;
722	load->isr_rate = g_stat_isr_cnt - b_os_load_data.last_isr_cnt;
723	b_os_load_data.last_idle_ctr = OSIdleCtr;
724	b_os_load_data.last_ctxsw_ctr = OSCtxSwCtr;
725	b_os_load_data.last_isr_time = g_stat_isr_time;
726	b_os_load_data.last_isr_cnt = g_stat_isr_cnt;
727	load->duration = b_os_tv_diff(&now, &b_os_load_data.last_time);
728	if (load->duration==0)
729	{
730	bos_exit_critical(flags);
731	BDBG_WRN(("load->duration = %d\n",load->duration));
732	goto error;
733	}
734	b_os_load_data.last_time = now;
735	g_os_task_stats[OS_LOWEST_PRIO+1].last_time=now;
736	bos_exit_critical(flags);
737	/*
738	BDBG_MSG(("calib_idle_ticks %u calib_ms %u\n", b_os_load_data.calib_idle_ticks, b_os_load_data.calib_ms));
739	BDBG_MSG(("idle_ctr %u duration %u\n", idle_ctr, load->duration));
740	*/
741	/*
742	* below we calculate this
743	* 100 * (idle_ctr/load->duration) / (b_os_load_data.calib_idle_ticks/b_os_load_data.calib_ms)
744	* and carefully rearrange it to both prevent rounding and overflows
745	*/
746	load->ctxsw_rate = (load->ctxsw_rate*1000)/load->duration;
747	load->isr_rate = (load->isr_rate*1000)/load->duration;
748	/* ISR load is
749	* (isr_time * 100)/(clock * (load->duration/1000))
750	* rearranged to keep it from overflowing and maintain accuracy */
751	mips_freq = g_running_clock.clock_freq/(1000*(100/10));
752	if (mips_freq==0)
753	{
754	BDBG_WRN(("g_running_clock.clock_freq = %d\n",g_running_clock.clock_freq));
755	goto error;
756	}
757	load->isr = 10*load->isr;
758	load->isr_us = load->isr/(mips_freq/10);
759	load->isr = load->isr/(mips_freq*load->duration);
760	load->idle = ((idle_ctr/32)((b_os_load_data.calib_ms100*32)/load->duration))/b_os_load_data.calib_idle_ticks;
761	return;
762	error:
763	load->isr = 0;
764	load->duration = 0;
765	load->idle = 0;
766	load->isr_rate = 0;
767	load->ctxsw_rate = 0;
768	return;
769	}
770
771	extern inline void b_os_check_stack(b_task_stats *task, uint32_t pattern)
772	{
773	unsigned i;
774	unsigned left;
775	unsigned virgin;
776
777	for (virgin=0, left=i=task->stack_left;i>0;i--)
778	{
779	if (task->stack[i] != pattern)
780	{
781	left = i;
782	virgin = 0;
783	}
784	else
785	{
786	virgin++;
787	if (task->stack_fast_scan>0 && left == task->stack_left && virgin>=4)
788	{ /* if dirty marker didn't move and have seen 4 markers in a row, quit */
789	break;
790	}
791	}
792	}
793	if (left!=task->stack_left)
794	{
795	task->stack_fast_scan = 0; /* don't use fast scan for the next round */
796	task->stack_left = left;
797	}
798	else
799	{
800	if (task->stack_fast_scan==0)
801	{
802	task->stack_fast_scan = 16;
803	}
804	else
805	{
806	task->stack_fast_scan --;
807	}
808	}
809	return;
810	}
811	struct b_task_stats *bos_taskinfo(int priority)
812	{
813	return &g_os_task_stats[priority];
814	}
815
816	void bos_print_taskinfo(void)
817	{
818	unsigned i;
819	unsigned mips_freq = g_running_clock.clock_freq/(1000); /* prescaled frequency */
820	char *pname;
821
822	for (i=0;i<OS_LOWEST_PRIO+2;i++)
823	{
824	struct b_task_stats *stats = &g_os_task_stats[i];
825	b_timeval now;
826	unsigned ms;
827	unsigned task_ms;
828	unsigned task_cnt;
829	unsigned task_load;
830	unsigned flags;
831	unsigned stack_use;
832	unsigned issue_rate;
833	uint32_t pc=0;
834
835	if (!stats->stack)
836	{
837	continue;
838	}
839	GETTIMEOFDAY(&now);
840	ms = b_os_tv_diff(&now, &stats->last_time);
841	/* capture and reset counters */
842	flags = bos_enter_critical();
843	if (i==OS_LOWEST_PRIO+1)
844	{ /* isr pseudo task */
845	task_cnt = g_stat_isr_cnt - b_os_load_data.last_isr_cnt;
846	task_ms = g_stat_isr_time - b_os_load_data.last_isr_time;
847	}
848	else
849	{
850	task_ms = stats->clock_cnt;
851	task_cnt = stats->active_cnt;
852	if (OSTCBPrioTbl[i] && OSTCBPrioTbl[i]->OSTCBStkPtr)
853	{
854	pc = ((uint32_t )OSTCBPrioTbl[i]->OSTCBStkPtr)[ROFF_PC/-ROFF_NUM_REG*/];
855	}
856	}
857	issue_rate = stats->instr_cnt;
858	if (task_cnt)
859	{
860	stats->instr_cnt = 0;
861	stats->clock_cnt = 0;
862	stats->active_cnt = 0;
863	stats->last_time = now;
864	}
865	bos_exit_critical(flags);
866	if (task_ms>1000)
867	{
868	issue_rate /= (task_ms/1000);
869	}
870	else
871	{
872	issue_rate = 0;
873	}
874	#if (OS_TASK_STAT_STK_CHK_EN > 0) && (OS_TASK_CREATE_EXT_EN > 0)
875	{ OS_STK_DATA stk_data;
876	if (OSTaskStkChk(i, &stk_data) != OS_ERR_NONE)
877	{
878	printf("error performing stack check for Priority %d\n",i);
879	}
880	else
881	{
882	stats->stack_size = stk_data.OSUsed/4 + stk_data.OSFree/4;
883	stats->stack_left = stk_data.OSFree/4;
884	}
885	}
886	#else
887	b_os_check_stack(stats,B_OS_STK_FILL_INT32);
888	#endif
889
890	/* normalize information */
891	task_load = task_ms / (((mips_freq10)/10000)ms);
892	task_ms = task_ms/mips_freq;
893	if (stats->stack_size>0)
894	{
895	stack_use = (100*(stats->stack_size - stats->stack_left))/stats->stack_size;
896	}
897	else
898	{
899	stack_use = 100;
900	}
901	#if OS_TASK_NAME_SIZE > 1
902	if (strlen(stats->name) > 1)
903	pname = stats->name;
904	else
905	pname = OSTCBPrioTbl[i]->OSTCBTaskName;
906	#else
907	pname = stats->name;
908	#endif
909	printf("TASK(%3u):%-16s CPU %2u.%1u%%(%5ums) RATE %2u.%1u%% CTXSW %5u(%5u/s %7uus) STACK %2u%% (%4u:%4u)\n",
910	i, pname, (task_load/10), (task_load%10) , task_ms, issue_rate/10, issue_rate%10, task_cnt, (task_cnt*1000)/ms,
911	(task_ms*1000)/(task_cnt?task_cnt:1), stack_use, (stats->stack_size-stats->stack_left), stats->stack_size);
912	}
913	return;
914	}
915
916	const void *
917	bos_task_from_stack(const uint32_t *stack)
918	{
919	unsigned i;
920
921	for (i=0;i<OS_LOWEST_PRIO+2;i++)
922	{
923	if ( (stack >= g_os_task_stats[i].stack && stack <= g_os_task_stats[i].stack + g_os_task_stats[i].stack_size))
924	{
925	return g_os_task_stats[i].name;
926	}
927	}
928	return NULL;
929	}
930
931	void bos_check_stacks(char* str)
932	{
933	unsigned i;
934	unsigned mips_freq = g_running_clock.clock_freq/(1000); /* prescaled frequency */
935	#if 0
936	if (mem_validate(&g_p_dsp->sdram_heap) == 0)
937	{
938	printf("###### mem_validate failure %s\n",str);
939	}
940	#endif
941	for (i=0;i<OS_LOWEST_PRIO+2;i++)
942	{
943	struct b_task_stats *stats = &g_os_task_stats[i];
944	b_timeval now;
945	unsigned ms;
946	unsigned task_ms;
947	unsigned task_cnt;
948	unsigned task_load;
949	unsigned flags;
950	unsigned stack_use;
951	unsigned issue_rate;
952	uint32_t pc=0;
953	const char *name="";
954	#if defined(BCM_DEBUG)
955	char buf[24];
956	#endif
957
958	if (!stats->stack)
959	{
960	continue;
961	}
962	GETTIMEOFDAY(&now);
963	ms = b_os_tv_diff(&now, &stats->last_time);
964	/* capture and reset counters */
965	flags = bos_enter_critical();
966	if (i==OS_LOWEST_PRIO+1)
967	{ /* isr pseudo task */
968	task_cnt = g_stat_isr_cnt - b_os_load_data.last_isr_cnt;
969	task_ms = g_stat_isr_time - b_os_load_data.last_isr_time;
970	stats->instr_cnt = g_stat_isr_cnt;
971	}
972	else
973	{
974	task_ms = stats->clock_cnt;
975	task_cnt = stats->active_cnt;
976	if (OSTCBPrioTbl[i] && OSTCBPrioTbl[i]->OSTCBStkPtr)
977	{
978	pc = ((uint32_t )OSTCBPrioTbl[i]->OSTCBStkPtr)[ROFF_PC/-ROFF_NUM_REG*/];
979	}
980	}
981	issue_rate = stats->instr_cnt;
982	if (task_cnt)
983	{
984	stats->instr_cnt = 0;
985	stats->clock_cnt = 0;
986	stats->active_cnt = 0;
987	stats->last_time = now;
988	}
989	bos_exit_critical(flags);
990	if (task_ms>1000)
991	{
992	issue_rate /= (task_ms/1000);
993	}
994	else
995	{
996	issue_rate = 0;
997	}
998	#if defined(BCM_DEBUG)
999	if (pc)
1000	{
1001	name = bsymtable_get_name(pc, buf, sizeof(buf));
1002	}
1003	#endif
1004	/* check stack */
1005	#if (OS_TASK_STAT_STK_CHK_EN > 0) && (OS_TASK_CREATE_EXT_EN > 0)
1006	{
1007	OS_STK_DATA stk_data;
1008	if (OSTaskStkChk(i, &stk_data) != OS_ERR_NONE)
1009	{
1010	printf("error performing stack check for Priority %d\n",i);
1011	}
1012	else
1013	{
1014	stats->stack_size = stk_data.OSUsed/4 + stk_data.OSFree/4;
1015	stats->stack_left = stk_data.OSFree/4;
1016	}
1017	}
1018	#else
1019	b_os_check_stack(stats,B_OS_STK_FILL_INT32);
1020	#endif
1021
1022	/* normalize information */
1023	task_load = task_ms / ((mips_freq/100)*ms);
1024	task_ms = task_ms/mips_freq;
1025	if (stats->stack_size>0)
1026	{
1027	stack_use = (100*(stats->stack_size - stats->stack_left))/stats->stack_size;
1028	}
1029	else
1030	{
1031	stack_use = 100;
1032	}
1033	if (stack_use > 90)
1034	{
1035	printf("TASK(%2u):%-12s CPU %2u%%(%4ums) RATE %2u.%1u%% CTXSW %5u(%5u/s %7uus) STACK %2u%% (%u:%u) %s@%s\n", i, stats->name, task_load, task_ms, issue_rate/10, issue_rate%10, task_cnt, (task_cnt1000)/ms, (task_ms1000)/(task_cnt?task_cnt:1), stack_use, (stats->stack_size-stats->stack_left), stats->stack_size, name,str);
1036	}
1037	}
1038	}
1039
1040	#define RAM_SIZE_MAGIC 0xBABEBAD0
1041	unsigned int bos_ram_size(void)
1042	{
1043	unsigned int base;
1044	unsigned int alias;
1045	unsigned int size;
1046	unsigned int magic;
1047
1048	magic = RAM_SIZE_MAGIC;
1049
1050	base = MEM_SIZE_8M;
1051	do
1052	{
1053	alias = base << 1;
1054	(unsigned int)BCM_PHYS_TO_KSEG1(base - 0x100) = magic;
1055	if (magic == (unsigned int)BCM_PHYS_TO_KSEG1(alias - 0x100))
1056	{
1057	size = base;
1058	break;
1059	}
1060	base = alias;
1061	magic++;
1062	}while (1);
1063	return size;
1064	}
1065
1066	/*
1067	If you define PROFILE and would like to use this function, change
1068	OS_TASK_IDLE_HOOK_EN to 2 in os_cfg.h in ucos_ii directory so this
1069	function is used instead of builtin.
1070	*/
1071	#if (PROFILE && !OS_TASK_IDLE_HOOK_EN)
1072
1073	#define OS_TASK_IDLE_CNT 4096
1074	static unsigned s_addr[OS_TASK_IDLE_CNT/4 + 8];
1075
1076	void OSTaskIdleHook(void)
1077	{
1078	volatile unsigned *addr = s_addr;
1079	unsigned i;
1080
1081	for (i=0;i<n;i+=8)
1082	{
1083	(void)addr[i+0];
1084	(void)addr[i+1];
1085	(void)addr[i+2];
1086	(void)addr[i+3];
1087	(void)addr[i+4];
1088	(void)addr[i+5];
1089	(void)addr[i+6];
1090	(void)addr[i+7];
1091	}
1092	return;
1093	}
1094	#endif
1095
1096	extern void bint_handler(void);
1097
1098	/* update task accounting here */
1099	void OSTaskSwHook(void)
1100	{
1101	uint32_t count;
1102	struct b_task_stats * old;
1103	unsigned instr_cnt;
1104
1105	count = bcm_read_cp0($9,0);
1106	instr_cnt = bcm_read_cp0($25, 2);
1107	old = &g_os_task_stats[OSTCBCur->OSTCBPrio];
1108	old->clock_cnt += count - g_last_ctxsw.clock;
1109	old->instr_cnt += g_last_ctxsw.instr - instr_cnt;
1110	old->active_cnt++;
1111	g_last_ctxsw.clock = count;
1112	g_last_ctxsw.instr = instr_cnt;
1113
1114	}
1115
1116	#if SUPPORT_DST_PLATFORM
1117
1118	b_task_stats *bos_get_task_info(b_task_t id)
1119	{
1120	if(id>=OS_MAX_TASKS) return NULL;
1121
1122	return &g_os_task_stats[id];
1123	}
1124
1125	void bos_print_taskinfo_ex(int level, char (callback)(void , char , int))
1126	{
1127	#if 0//BKTODO
1128	unsigned i;
1129	unsigned mips_freq = g_running_clock.clock_freq/(1000); /* prescaled frequency */
1130	int max_name_len = 0;
1131	char task_name[17] = {0, };
1132	// get longest task name
1133	for(i=0;i<OS_MAX_TASKS+2;i++) {
1134	int n;
1135	struct b_task_stats *stats = &g_os_task_stats[i];
1136	if(!stats->stack) continue;
1137	n = strlen(stats->name);
1138	if (max_name_len < n) max_name_len = n;
1139	}
1140
1141	for(i=0;i<OS_MAX_TASKS+2;i++) {
1142	struct b_task_stats *stats = &g_os_task_stats[i];
1143	b_timeval now;
1144	unsigned ms;
1145	unsigned task_ms;
1146	unsigned task_cnt;
1147	unsigned task_load;
1148	unsigned flags;
1149	unsigned stack_use;
1150	unsigned issue_rate;
1151	uint32_t pc=0, r_sp=0, r_ra=0;
1152	const char *name="";
1153	char buf[24];
1154	uint32_t task_runtime;
1155	char task_runtime_buf[32];
1156
1157	if(!stats->stack) {
1158	continue;
1159	}
1160	gettimeofday(&now);
1161	ms = b_os_tv_diff(&now, &stats->last_time);
1162	/* capture and reset counters */
1163	flags = bos_enter_critical();
1164	if(i==OS_MAX_TASKS+1) { /* isr pseudo task */
1165	task_cnt = g_stat_isr_cnt - b_os_load_data.last_isr_cnt;
1166	task_ms = g_stat_isr_time - b_os_load_data.last_isr_time;
1167	} else {
1168	task_ms = stats->clock_cnt;
1169	task_cnt = stats->active_cnt;
1170	if(OSTCBPrioTbl[i] && OSTCBPrioTbl[i]->OSTCBStkPtr) {
1171	pc = ((uint32_t )OSTCBPrioTbl[i]->OSTCBStkPtr)[ROFF_PC/-ROFF_NUM_REG*/];
1172	r_sp = ((uint32_t )OSTCBPrioTbl[i]->OSTCBStkPtr)[ROFF_SP/-ROFF_NUM_REG*/];
1173	r_ra = ((uint32_t )OSTCBPrioTbl[i]->OSTCBStkPtr)[ROFF_RA/-ROFF_NUM_REG*/];
1174	}
1175	}
1176	issue_rate = stats->instr_cnt;
1177	if (task_cnt) {
1178	stats->instr_cnt = 0;
1179	stats->clock_cnt = 0;
1180	stats->active_cnt = 0;
1181	stats->last_time = now;
1182	}
1183	bos_exit_critical(flags);
1184	if (task_ms>1000) {
1185	issue_rate /= (task_ms/1000);
1186	} else {
1187	issue_rate = 0;
1188	}
1189	if (pc) {
1190	name = bsymtable_get_name(pc, buf, sizeof(buf));
1191	}
1192	/* check stack */
1193	b_os_check_stack(stats,i<OS_MAX_TASKS?B_OS_STK_FILL_INT32:0);
1194	/* normalize information */
1195	task_load = task_ms / ((mips_freq/100)*ms);
1196	task_ms = task_ms/mips_freq;
1197	if(stats->stack_size>0) {
1198	stack_use = (100*(stats->stack_size - stats->stack_left))/stats->stack_size;
1199	} else {
1200	stack_use = 100;
1201	}
1202
1203	// print task name with fixed width. adapt to longest name.
1204	memset(task_name, ' ', sizeof(task_name));
1205	strncpy(task_name, stats->name, strlen(stats->name));
1206	task_name[max_name_len] = 0; // null terminator.
1207
1208	// average task run time per context switch
1209	task_runtime = (task_ms*1000)/(task_cnt?task_cnt:1);
1210	if (task_runtime >= 10000)
1211	sprintf(task_runtime_buf, "%4ums", task_runtime/1000);
1212	else
1213	sprintf(task_runtime_buf, "%4uus", task_runtime);
1214
1215	if (level == 1 \|\| level == 2) {
1216	char prefix[8] = {0, };
1217	memset(prefix, ' ', sizeof(prefix)-1);
1218	printf("TASK(%2u):%s CPU %2u%%(%4ums) STACK %2u%% (%u:%u) ",
1219	i, task_name, task_load, task_ms,
1220	stack_use, (stats->stack_size-stats->stack_left), stats->stack_size,
1221	0);
1222	if (level == 1 && callback && i<OS_MAX_TASKS) { // task 63,64 is not normal task.
1223	OS_EVENT *pevent;
1224	char outbuf[100];
1225	flags = bos_enter_critical();
1226	pevent = OSTCBPrioTbl[i]->OSTCBEventPtr;
1227	bos_exit_critical(flags);
1228	/* this 'pevent' is the event that this task is waiting..
1229	show more detail info about this event.
1230	*/
1231	printf("%s\n", callback(pevent, outbuf, sizeof(outbuf)));
1232	}
1233	else if (level == 2 && pc && r_sp && r_ra) {
1234	printf("\n");
1235	stack_backtrace((unsigned int )r_sp, (unsigned int )pc, (unsigned int *)r_ra, prefix);
1236	}
1237	else
1238	printf("\n");
1239	}
1240	else { // default
1241	printf("TASK(%2u):%s CPU %2u%%(%4ums) RATE %2u.%1u%% CTXSW %5u(%4u/s %s) STACK %2u%% (%u:%u)\n",
1242	i, task_name, task_load, task_ms,
1243	issue_rate/10, issue_rate%10, // rate
1244	task_cnt, (task_cnt*1000)/ms, task_runtime_buf, // context switch
1245	stack_use, (stats->stack_size-stats->stack_left), stats->stack_size,
1246	0);
1247	}
1248	}
1249
1250	#if 0
1251	/* cafrii 080919, separate pending list */
1252	if (level == 1 && callback)
1253	{
1254	OS_EVENT *pevent;
1255	//unsigned flags;
1256	printf("Pending List:\n");
1257
1258	for(i=0;i<OS_MAX_TASKS;i++) // task 63,64 is not normal task.
1259	{
1260	struct b_task_stats *stats = &g_os_task_stats[i];
1261	if(!stats->stack) // no task.
1262	continue;
1263	//flags = bos_enter_critical();
1264	pevent = OSTCBPrioTbl[i]->OSTCBEventPtr;
1265	//bos_exit_critical(flags);
1266	/* this 'pevent' is the event that this task is waiting..
1267	show more detail info about this event.
1268	*/
1269	callback(i, stats->name, pevent);
1270	}
1271	}
1272	#endif // 0
1273	#endif
1274	return;
1275	}
1276
1277	extern unsigned char OSLockNesting;
1278
1279	INT8U OSSchedLockCount(void)
1280	{
1281	return OSLockNesting;
1282	}
1283
1284
1285	#if 0
1286	/*
1287	User can use OSUser field for their convenience.
1288	*/
1289	void OSSaveUserData(OS_EVENT pevent, void pUser)
1290	{
1291	pevent->OSUser = pUser;
1292	}
1293
1294	void OSGetUserData(OS_EVENT pevent)
1295	{
1296	return pevent->OSUser;
1297	}
1298	#endif
1299	#endif
1300

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source: svn/trunk/newcon3bcm2_21bu/dta/src/bos_ucos_ii.c @ 2

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