machine/stm32f103xx: implementation of RTC/TIM based timers

Signed-off-by: Ron Evans <ron@hybridgroup.com>
2018-12-27 07:57:26 +01:00 · 2018-12-27 07:57:26 +01:00 · f71e1bcf03
--- a/src/device/stm32/stm32f103xx-bitfields.go
+++ b/src/device/stm32/stm32f103xx-bitfields.go
@ -12,20 +12,32 @@ const (
 	FLASH_ACR_LATENCY_2 = 0x00000004
 	// Reset and Clock Control Control Register flag values.
 	// System Clock source
 	RCC_CFGR_SW_HSI = 0
 	RCC_CFGR_SW_HSE = 1
 	RCC_CFGR_SW_PLL = 2
 	// Flags for when System Clock source is set.
 	RCC_CFGR_SWS_HSI = 0x00000000
 	RCC_CFGR_SWS_HSE = 0x00000004
 	RCC_CFGR_SWS_PLL = 0x00000008
 	// Sets PCLK1
 	RCC_CFGR_PPRE1_DIV_NONE = 0x00000000
 	RCC_CFGR_PPRE1_DIV_2    = 0x00000400
 	RCC_CFGR_PPRE1_DIV_4    = 0x00000500
 	RCC_CFGR_PPRE1_DIV_8    = 0x00000600
 	RCC_CFGR_PPRE1_DIV_16   = 0x00000700
 	// Sets PCLK2
 	RCC_CFGR_PPRE2_DIV_NONE = 0x00000000
 	RCC_CFGR_PPRE2_DIV_2    = 0x00002000
 	RCC_CFGR_PPRE2_DIV_4    = 0x00002800
 	RCC_CFGR_PPRE2_DIV_8    = 0x00003000
 	RCC_CFGR_PPRE2_DIV_16   = 0x00003800
 	// Sets PLL multiplier
 	RCC_CFGR_PLLMUL_2  = 0x00000000
 	RCC_CFGR_PLLMUL_3  = 0x00040000
 	RCC_CFGR_PLLMUL_4  = 0x00080000
@ -41,4 +53,9 @@ const (
 	RCC_CFGR_PLLMUL_14 = 0x00300000
 	RCC_CFGR_PLLMUL_15 = 0x00340000
 	RCC_CFGR_PLLMUL_16 = 0x00380000
 	// RTC clock source
 	RCC_RTCCLKSource_LSE        = 0x00000100
 	RCC_RTCCLKSource_LSI        = 0x00000200
 	RCC_RTCCLKSource_HSE_Div128 = 0x00000300
 )
--- a/src/machine/machine_stm32f103xx.go
+++ b/src/machine/machine_stm32f103xx.go
@ -137,6 +137,7 @@ func (uart UART) Configure(config UARTConfig) {
 	stm32.USART1.CR1 = stm32.USART_CR1_TE | stm32.USART_CR1_RE | stm32.USART_CR1_RXNEIE | stm32.USART_CR1_UE
 	// Enable RX IRQ.
 	arm.SetPriority(stm32.IRQ_USART1, 0xc0)
 	arm.EnableIRQ(stm32.IRQ_USART1)
 }
--- a/src/runtime/runtime_stm32f103xx.go
+++ b/src/runtime/runtime_stm32f103xx.go
@ -8,10 +8,10 @@ import (
 	"machine"
 )
 const tickMicros = 1 // TODO
 func init() {
 	initCLK()
 	initRTC()
 	initTIM()
 	machine.UART0.Configure(machine.UARTConfig{})
 }
@ -44,13 +44,145 @@ func initCLK() {
 	}
 }
-func sleepTicks(d timeUnit) {
+const tickMicros = 1000
-	// TODO: use a real timer here
+
-	for i := 0; i < int(d/535); i++ {
+var (
-		arm.Asm("")
+	timestamp        timeUnit // microseconds since boottime
 	timerLastCounter uint64
 )
 //go:volatile
 type isrFlag bool
 var timerWakeup isrFlag
 func initRTC() {
 	// Enable the PWR and BKP.
 	stm32.RCC.APB1ENR |= stm32.RCC_APB1ENR_PWREN | stm32.RCC_APB1ENR_BKPEN
 	// access to backup register
 	stm32.PWR.CR |= stm32.PWR_CR_DBP
 	// Enable LSE
 	stm32.RCC.BDCR |= stm32.RCC_BDCR_LSEON
 	// wait until LSE is ready
 	for stm32.RCC.BDCR&stm32.RCC_BDCR_LSERDY == 0 {
 	}
 	// Select LSE
 	stm32.RCC.BDCR |= stm32.RCC_RTCCLKSource_LSE
 	// set prescaler to "max" per datasheet
 	stm32.RTC.PRLH = stm32.RTC_PRLH_PRLH_Msk
 	stm32.RTC.PRLL = stm32.RTC_PRLL_PRLL_Msk
 	// set count to zero
 	stm32.RTC.CNTH = 0x0
 	stm32.RTC.CNTL = 0x0
 	// Enable RTC
 	stm32.RCC.BDCR |= stm32.RCC_BDCR_RTCEN
 	// Clear RSF
 	stm32.RTC.CRL &^= stm32.RTC_CRL_RSF
 	// Wait till flag is set
 	for stm32.RTC.CRL&stm32.RTC_CRL_RSF == 0 {
 	}
 }
-func ticks() timeUnit {
+// Enable the TIM3 clock.
-	return 0 // TODO
+func initTIM() {
 	stm32.RCC.APB1ENR |= stm32.RCC_APB1ENR_TIM3EN
 	arm.SetPriority(stm32.IRQ_TIM3, 0xc3)
 	arm.EnableIRQ(stm32.IRQ_TIM3)
 }
 // sleepTicks should sleep for specific number of microseconds.
 func sleepTicks(d timeUnit) {
 	for d != 0 {
 		ticks()            // update timestamp
 		ticks := uint32(d) // current scaling only supports 100 usec to 6553 msec
 		timerSleep(ticks)
 		d -= timeUnit(ticks)
 	}
 }
 // number of ticks (microseconds) since start.
 func ticks() timeUnit {
 	// convert RTC counter from seconds to microseconds
 	timerCounter := uint64(stm32.RTC.CNTH<<16|stm32.RTC.CNTL) * 1000 * 1000
 	// add the fractional part of current time using DIV registers
 	timerCounter += (uint64(stm32.RTC.DIVH<<16|stm32.RTC.DIVL) / 1024 * 32 * 32) * 1000 * 1000
 	// change since last measurement
 	offset := (timerCounter - timerLastCounter)
 	timerLastCounter = timerCounter
 	timestamp += timeUnit(offset)
 	return timestamp
 }
 // ticks are in microseconds
 func timerSleep(ticks uint32) {
 	timerWakeup = false
 	// STM32 timer update event period is calculated as follows:
 	//
 	// 			Update_event = TIM_CLK/((PSC + 1)*(ARR + 1)*(RCR + 1))
 	//
 	// Where:
 	//
 	//			TIM_CLK = timer clock input
 	// 			PSC = 16-bit prescaler register
 	// 			ARR = 16/32-bit Autoreload register
 	// 			RCR = 16-bit repetition counter
 	//
 	// Example:
 	//
 	//			TIM_CLK = 72 MHz
 	// 			Prescaler = 1
 	// 			Auto reload = 65535
 	// 			No repetition counter RCR = 0
 	// 			Update_event = 72*(10^6)/((1 + 1)*(65535 + 1)*(1))
 	// 			Update_event = 549.3 Hz
 	//
 	// Set the timer prescaler/autoreload timing registers.
 	// TODO: support smaller or larger scales (autoscaling) based
 	// on the length of sleep time requested.
 	// The current scaling only supports a range of 100 usec to 6553 msec.
 	// prescale counter down from 72mhz to 10khz aka 0.1 ms frequency.
 	stm32.TIM3.PSC = machine.CPU_FREQUENCY/10000 - 1 // 7199
 	// set duty aka duration
 	stm32.TIM3.ARR = stm32.RegValue(ticks/100) - 1 // convert from microseconds to 0.1 ms
 	// Enable the hardware interrupt.
 	stm32.TIM3.DIER |= stm32.TIM_DIER_UIE
 	// Enable the timer.
 	stm32.TIM3.CR1 |= stm32.TIM_CR1_CEN
 	// wait till timer wakes up
 	for !timerWakeup {
 		arm.Asm("wfi")
 	}
 }
 //go:export TIM3_IRQHandler
 func handleTIM3() {
 	if (stm32.TIM3.SR & stm32.TIM_SR_UIF) > 0 {
 		// Disable the timer.
 		stm32.TIM3.CR1 &^= stm32.TIM_CR1_CEN
 		// clear the update flag
 		stm32.TIM3.SR &^= stm32.TIM_SR_UIF
 		// timer was triggered
 		timerWakeup = true
 	}
 }