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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libbsp/] [or1k/] [bender/] [clock/] [ckinit.c] - Rev 173
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/* ckinit.c * * This file provides a template for the clock device driver initialization. * * COPYRIGHT (c) 1989-1999. * On-Line Applications Research Corporation (OAR). * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * $Id: ckinit.c,v 1.1 2001-09-27 12:00:27 chris Exp $ */ #include <stdlib.h> #include <rtems.h> #include <rtems/libio.h> #include <bsp.h> static void (*old_handler)(unsigned int,unsigned int,unsigned int,unsigned int); void Clock_exit( void ); void Clock_isr( rtems_vector_number vector,unsigned int pc, unsigned int address, unsigned int sr); /* * The interrupt vector number associated with the clock tick device * driver. */ #define CLOCK_VECTOR 8 /* * Clock_driver_ticks is a monotonically increasing counter of the * number of clock ticks since the driver was initialized. */ volatile rtems_unsigned32 Clock_driver_ticks; /* * Clock_isrs is the number of clock ISRs until the next invocation of * the RTEMS clock tick routine. The clock tick device driver * gets an interrupt once a millisecond and counts down until the * length of time between the user configured microseconds per tick * has passed. */ rtems_unsigned32 Clock_isrs; /* ISRs until next tick */ /* * These are set by clock driver during its init */ rtems_device_major_number rtems_clock_major = ~0; rtems_device_minor_number rtems_clock_minor; void Clock_exit( void ); /* Write this to restart the Timer. Sets mode = 01, interrupts enabled, interrupt not pending, report at 200,000 (1 msec on 200 MHz CPU) */ static const unsigned int TTMR_RESET = 0x60030D40; /* * Isr Handler */ void Clock_isr(unsigned32 vector, unsigned32 pc, unsigned32 ear, unsigned32 sr) { register int pending; register int value = 0x60002710; /* Was it us? */ asm volatile ("l.mfspr %0,r0,0x4802 \n\t" /* Read the PIC status */ "l.andi %0,%0,0x8 \n\t" : "=r" (pending)); if(pending) { rtems_clock_tick(); asm ("l.mtspr r0,%0,0x5000 \n\t" :: "r" (value)); } if(old_handler) (*old_handler)(vector,pc,ear,sr); } /* * Install_clock * * Install a clock tick handler and reprograms the chip. This * is used to initially establish the clock tick. */ void Install_clock() { unsigned32 tmp,sr,ttmr,ttcr; extern unsigned32 Or1k_Interrupt_Vectors[16]; ttmr = TTMR_RESET; /* Reset value */ ttcr = 0; /* Start at 0 */ /* * Initialize the clock tick device driver variables */ /* Make sure the Timer (interrupt 3) is enabled and reports a high prority interrupt */ asm volatile ("l.mfspr %0,r0,0x4800 \n\t" /* Get the PIC mask */ "l.ori %0,%0,0x8 \n\t" /* Enable int 3 */ "l.mtspr r0,%0,0x4800 \n\t" /* Write back mask */ "l.mfspr %0,r0,0x4801 \n\t" /* Get priority mask */ "l.ori %0,%0,0x8 \n\t" /* Set us to high */ "l.mtspr r0,%0,0x4801 \n\t" /* Write back to PICPR */ : "=r" (tmp)); /* Generate a 1 kHz interrupt */ asm volatile ("l.mfspr %0,r0,0x11 \n\t" /* Get the current setting */ "l.addi %1,r0,-5 \n\t" "l.and %1,%1,%0 \n\t" /* Turn off interrupts */ "l.mtspr r0,%1,0x11 \n\t" /* Set it in SR */ "l.mtspr r0,%2,0x5000\n\t" /* Set TTMR */ "l.mtspr r0,%3,0x5100\n\t" /* Set TTCR */ : "=&r" (sr), "=&r" (tmp) : "r" (ttmr), "r" (ttcr)); old_handler = (void(*)(unsigned int,unsigned int,unsigned int,unsigned int)) Or1k_Interrupt_Vectors[8]; Or1k_Interrupt_Vectors[8] = (unsigned32)Clock_isr; asm volatile ("l.mtspr r0,%0,0x11\n\t":: "r" (sr)); Clock_driver_ticks = 0; /* * Schedule the clock cleanup routine to execute if the application exits. */ atexit( Clock_exit ); } /* * Clean up before the application exits */ void Clock_exit( void ) { register int temp1; register int temp2; /* In the case of a fatal error, we should shut down all the interrupts so we don't get woken up again. */ /* First, turn off the clock in the PIC */ asm volatile ("l.mfspr %0,r0,0x4800 \n\t" /* Get the PIC mask */ "l.addi %1,%1,-9 \n\t" /* Create a mask to disable */ "l.and %0,%1,%0 \n\t" /* Mask us out */ "l.mtspr r0,%0,0x4800 \n\t" /* Write back mask */ "l.mfspr %0,r0,0x4801 \n\t" /* Get priority mask */ "l.and %0,%1,%0 \n\t" /* Set us to low */ "l.mtspr r0,%0,0x4801 \n\t" /* Write back to PICPR */ : "=r" (temp1), "=r" (temp2)); /* Now turn off the clock at the timer */ asm volatile ("l.mtspr r0,r0,0x5000\n\t" /* Clear TTMR */ "l.mtspr r0,r0,0x5100\n\t"); /* Clear TTCR */ } /* * Clock_initialize * * Device driver entry point for clock tick driver initialization. */ rtems_device_driver Clock_initialize( rtems_device_major_number major, rtems_device_minor_number minor, void *pargp ) { Install_clock(); /* * make major/minor avail to others such as shared memory driver */ rtems_clock_major = major; rtems_clock_minor = minor; return RTEMS_SUCCESSFUL; } rtems_device_driver Clock_control( rtems_device_major_number major, rtems_device_minor_number minor, void *pargp ) { rtems_unsigned32 isrlevel; rtems_libio_ioctl_args_t *args = pargp; if (args == 0) goto done; /* * This is hokey, but until we get a defined interface * to do this, it will just be this simple... */ if (args->command == rtems_build_name('I', 'S', 'R', ' ')) { Clock_isr(CLOCK_VECTOR,0,0,0); } else if (args->command == rtems_build_name('N', 'E', 'W', ' ')) { rtems_interrupt_disable( isrlevel ); (void) set_vector( args->buffer, CLOCK_VECTOR, 1 ); rtems_interrupt_enable( isrlevel ); } done: return RTEMS_SUCCESSFUL; }