mbed library sources. Supersedes mbed-src.
Fork of mbed-dev by
targets/TARGET_ublox/TARGET_HI2110/us_ticker.c
- Committer:
- <>
- Date:
- 2016-11-08
- Revision:
- 150:02e0a0aed4ec
- Child:
- 160:d5399cc887bb
File content as of revision 150:02e0a0aed4ec:
/* mbed Microcontroller Library * Copyright (c) 2016 u-blox * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* The usecond ticker is mapped to TIMER0. A few issues must be dealt * with in this driver: * * 1. The us_ticker API must count upwards, not down. * 2. The expected range/resolution is 32 bits each of 1 usecond, * whereas TIMER0 runs at 48 MHz (not 1 MHz) and so actually * has a range/resolution of 26 bits at 0.02 useconds. Software * has to compensate for this. */ #include "us_ticker_api.h" #include "critical.h" /* ---------------------------------------------------------------- * MACROS * ----------------------------------------------------------------*/ /* TIMER0 clock is 48 MHz */ #define CLOCK_TICKS_PER_US 48 /* The number of clock ticks in a full-run of * TIMER0, scaled to represent useconds */ #define USECONDS_PER_FULL_TIMER0_RUN 89478485 /* ---------------------------------------------------------------- * TYPES * ----------------------------------------------------------------*/ /* ---------------------------------------------------------------- * GLOBAL VARIABLES * ----------------------------------------------------------------*/ /* Are we ready? */ static bool g_initialised = false; /* Keep track of the number of useconds elapsed. */ static uint32_t g_us_overflow = 0; /* The number of useconds to increment the by at each interrupt */ static uint32_t g_us_overflow_increment = USECONDS_PER_FULL_TIMER0_RUN; /* Keep track of extra loops required to represent a particular time * as the HW timer runs faster than 1 MHz */ static uint32_t g_timer_extra_loops_required = 0; static uint32_t g_timer_extra_loops_done = 0; /* Keep track of any adjustment due to user interrupts . */ static uint32_t g_user_interrupt_offset = 0; /* Flag that a user timer is running */ static bool g_user_interrupt = false; /* ---------------------------------------------------------------- * FUNCTION PROTOTYPES * ----------------------------------------------------------------*/ static inline uint32_t divide_by_48(uint32_t x); /* ---------------------------------------------------------------- * NON-API FUNCTIONS * ----------------------------------------------------------------*/ /* Perform a divide-by-48 operation. * This is done as a multiply-shift operation to take advantage of * the ARM 32 bit single-cycle multiply and avoid using division; * 1/48 is equivalent to 1365/2^16. It is also done in two halves * to make sure that the multiplies fit into 32 bits. * * The principle is: * - divide the top 16 bits by 48 using multiply-shift (=> x1), * - work out the remainder of that operation and divide that by 48 (=> x1r), * - divide the bottom 16 bits by 48 using multiply-shift (=> x2), * - add the lot together to get the result. * * The cost is 29 instructions. */ static inline uint32_t divide_by_48(uint32_t x) { uint32_t x1 = ((x >> 16) * 1365) >> 16; uint32_t x1r = ((x & 0xFFFF0000) - ((x1 * 48) << 16)); x1r = (x1r * 1365) >> 16; uint32_t x2 = ((x & 0xFFFF) * 1365) >> 16; return (x1 << 16) + x1r + x2; } /* Timer0 handler */ void IRQ1_TMR0_Handler(void) { if (g_initialised) { /* Increment the overflow count and set the increment * value for next time */ g_us_overflow += g_us_overflow_increment; g_us_overflow_increment = USECONDS_PER_FULL_TIMER0_RUN; /* Now handle the user interrupt case */ if (g_user_interrupt) { if (g_timer_extra_loops_done < g_timer_extra_loops_required) { /* Let the timer go round again */ g_timer_extra_loops_done++; } else { /* We've done with looping around for a user interrupt */ g_user_interrupt = false; /* Call the mbed API */ us_ticker_irq_handler(); } } } NVIC_ClearPendingIRQ(Timer_IRQn); } /* ---------------------------------------------------------------- * MBED API CALLS * ----------------------------------------------------------------*/ void us_ticker_init(void) { if (!g_initialised) { /* Reset the globals */ g_timer_extra_loops_done = 0; g_timer_extra_loops_required = 0; g_us_overflow = 0; g_us_overflow_increment = USECONDS_PER_FULL_TIMER0_RUN; g_user_interrupt_offset = 0; g_user_interrupt = false; /* Get the timer running (starting at what is zero, * once inverted), with repeat */ NVIC_ClearPendingIRQ(Timer_IRQn); TIMER0_LOAD = 0xFFFFFFFF; TIMER0_CTRL = 0x03; NVIC_EnableIRQ(Timer_IRQn); g_initialised = true; } } uint32_t us_ticker_read() { uint32_t timeValue; /* This can be called before initialisation has been performed */ if (!g_initialised) { us_ticker_init(); } /* Disable interrupts to avoid collisions */ core_util_critical_section_enter(); /* Get the timer value, adding the offset in case we've been moved * around by user activity, inverting it (as a count-up timer is * expected), then scaling it to useconds and finally adding the * usecond overflow value to make up the 32-bit usecond total */ timeValue = divide_by_48(~(TIMER0_TIME + g_user_interrupt_offset)) + g_us_overflow; /* Put interrupts back */ core_util_critical_section_exit(); return timeValue; } /* NOTE: it seems to be an accepted fact that users * will never ask for a timeout of more than 2^31 useconds * and hence it's possible to do signed arithmetic */ void us_ticker_set_interrupt(timestamp_t timestamp) { g_timer_extra_loops_required = 0; g_timer_extra_loops_done = 0; int32_t timeDelta; /* Disable interrupts to avoid collisions */ core_util_critical_section_enter(); /* Establish how far we're being asked to move */ timeDelta = (int32_t) ((uint32_t) timestamp - us_ticker_read()); if (timeDelta <= 0) { /* Make delta positive if it's not, it will expire pretty quickly */ /* Note: can't just call us_ticker_irq_handler() directly as we * may already be in it and will overflow the stack */ timeDelta = 1; } /* The TIMER0 clock source is greater than 1 MHz, so * work out how many times we have to go around * and what the remainder is */ g_timer_extra_loops_required = (uint32_t) timeDelta / USECONDS_PER_FULL_TIMER0_RUN; timeDelta -= g_timer_extra_loops_required * USECONDS_PER_FULL_TIMER0_RUN; /* Next time we hit the interrupt the increment will be smaller */ g_us_overflow_increment = (uint32_t) timeDelta; /* We're about to modify the timer value; work out the * difference so that we can compensate for it when * the time is read */ timeDelta = timeDelta * CLOCK_TICKS_PER_US; g_user_interrupt_offset += TIMER0_TIME - timeDelta; /* Run for the remainder first, then we can loop for the full * USECONDS_PER_FULL_TIMER0_RUN afterwards */ TIMER0_LOAD = timeDelta; /* A user interrupt is now running */ g_user_interrupt = true; /* Put interrupts back */ core_util_critical_section_exit(); } void us_ticker_disable_interrupt(void) { /* Can't actually disable the interrupt here * as we need it to manage the timer overflow, * instead switch off the user interrupt part */ g_user_interrupt = false; g_timer_extra_loops_required = 0; g_us_overflow_increment = 0; } void us_ticker_clear_interrupt(void) { /* As above, can't clear the interrupt as it * may just be an overflow interrupt, instead * clear the variables */ g_user_interrupt = false; g_timer_extra_loops_required = 0; g_us_overflow_increment = 0; }