/* * Clock Tick Device Driver * * This routine initializes LEON timer 1 which used for the clock tick. * * The tick frequency is directly programmed to the configured number of * microseconds per tick. * * COPYRIGHT (c) 1989-2006. * On-Line Applications Research Corporation (OAR). * * Modified for LEON3 BSP. * COPYRIGHT (c) 2004. * Gaisler Research. * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.rtems.org/license/LICENSE. */ #include #include #include #include #if SIMSPARC_FAST_IDLE==1 #define CLOCK_DRIVER_USE_FAST_IDLE 1 #endif /* * The Real Time Clock Counter Timer uses this trap type. */ volatile struct gptimer_regs *LEON3_Timer_Regs = 0; static int clkirq; #define CLOCK_VECTOR LEON_TRAP_TYPE( clkirq ) static void leon3_clock_profiling_interrupt_delay(void) { #ifdef RTEMS_PROFILING /* * We need a small state machine to ignore the first clock interrupt, since * it contains the sequential system initialization time. Do the timestamp * initialization on the fly. */ static int state = 1; volatile struct irqmp_timestamp_regs *irqmp_ts = &LEON3_IrqCtrl_Regs->timestamp[0]; unsigned int s1_s2 = (1U << 25) | (1U << 26); if (state == 0) { unsigned int first = irqmp_ts->assertion; unsigned int second = irqmp_ts->counter; irqmp_ts->control |= s1_s2; _Profiling_Update_max_interrupt_delay(_Per_CPU_Get(), second - first); } else if (state == 1 && leon3_irqmp_has_timestamp(irqmp_ts)) { unsigned int ks = 1U << 5; state = 0; irqmp_ts->control = ks | s1_s2 | (unsigned int) clkirq; } else if (state == 1) { state = 2; } #endif } #define Clock_driver_support_at_tick() \ do { \ leon3_clock_profiling_interrupt_delay(); \ } while (0) #if defined(RTEMS_MULTIPROCESSING) #define Adjust_clkirq_for_node() \ do { \ if (rtems_configuration_get_user_multiprocessing_table() != NULL) { \ clkirq += LEON3_Cpu_Index; \ } \ } while(0) #else #define Adjust_clkirq_for_node() do { clkirq += LEON3_CLOCK_INDEX; } while(0) #endif #define Clock_driver_support_find_timer() \ do { \ struct ambapp_dev *adev; \ \ /* Find first LEON3 GP Timer */ \ adev = (void *)ambapp_for_each(&ambapp_plb, (OPTIONS_ALL|OPTIONS_APB_SLVS),\ VENDOR_GAISLER, GAISLER_GPTIMER, ambapp_find_by_idx, NULL); \ if (adev) { \ /* Found APB GPTIMER Timer */ \ LEON3_Timer_Regs = (volatile struct gptimer_regs *) \ DEV_TO_APB(adev)->start; \ clkirq = (LEON3_Timer_Regs->cfg & 0xf8) >> 3; \ \ Adjust_clkirq_for_node(); \ } \ } while (0) #define Clock_driver_support_install_isr( _new, _old ) \ do { \ _old = set_vector( _new, CLOCK_VECTOR, 1 ); \ } while(0) #define Clock_driver_support_initialize_hardware() \ do { \ LEON3_Timer_Regs->timer[LEON3_CLOCK_INDEX].reload = \ rtems_configuration_get_microseconds_per_tick() - 1; \ \ LEON3_Timer_Regs->timer[LEON3_CLOCK_INDEX].ctrl = \ GPTIMER_TIMER_CTRL_EN | GPTIMER_TIMER_CTRL_RS | \ GPTIMER_TIMER_CTRL_LD | GPTIMER_TIMER_CTRL_IE; \ } while (0) #define Clock_driver_support_shutdown_hardware() \ do { \ LEON_Mask_interrupt(LEON_TRAP_TYPE(clkirq)); \ LEON3_Timer_Regs->timer[LEON3_CLOCK_INDEX].ctrl = 0; \ } while (0) static uint32_t bsp_clock_nanoseconds_since_last_tick(void) { uint32_t clicks; uint32_t usecs; if ( !LEON3_Timer_Regs ) return 0; clicks = LEON3_Timer_Regs->timer[LEON3_CLOCK_INDEX].value; if ( LEON_Is_interrupt_pending( clkirq ) ) { clicks = LEON3_Timer_Regs->timer[LEON3_CLOCK_INDEX].value; usecs = (2*rtems_configuration_get_microseconds_per_tick() - clicks); } else { usecs = (rtems_configuration_get_microseconds_per_tick() - clicks); } return usecs * 1000; } #define Clock_driver_nanoseconds_since_last_tick \ bsp_clock_nanoseconds_since_last_tick #include "../../../shared/clockdrv_shell.h"