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Код Задачи Слияния Проекты Выпуски Пакеты Вики Активность Действия

machine: merge stm32f405/407

Просмотр исходного кода 
They're no longer functionally different.
Этот коммит содержится в:
Elias Naur 2021-12-28 18:16:15 +01:00 коммит произвёл kenbell
родитель 81dbbc89d3
коммит 11ee0969b6
3 изменённых файлов: 188 добавлений и 401 удалений
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188
src/machine/machine_stm32f4.go
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@ -7,6 +7,7 @@ package machine
import (
"device/stm32"
"math/bits"
"runtime/interrupt"
"runtime/volatile"
"unsafe"
@ -592,3 +593,190 @@ func initRNG() {
stm32.RCC.AHB2ENR.SetBits(stm32.RCC_AHB2ENR_RNGEN)
stm32.RNG.CR.SetBits(stm32.RNG_CR_RNGEN)
}
func CPUFrequency() uint32 {
return 168000000
}
// Internal use: configured speed of the APB1 and APB2 timers, this should be kept
// in sync with any changes to runtime package which configures the oscillators
// and clock frequencies
const APB1_TIM_FREQ = 42000000 * 2
const APB2_TIM_FREQ = 84000000 * 2
// Alternative peripheral pin functions
const (
AF0_SYSTEM = 0
AF1_TIM1_2 = 1
AF2_TIM3_4_5 = 2
AF3_TIM8_9_10_11 = 3
AF4_I2C1_2_3 = 4
AF5_SPI1_SPI2 = 5
AF6_SPI3 = 6
AF7_USART1_2_3 = 7
AF8_USART4_5_6 = 8
AF9_CAN1_CAN2_TIM12_13_14 = 9
AF10_OTG_FS_OTG_HS = 10
AF11_ETH = 11
AF12_FSMC_SDIO_OTG_HS_1 = 12
AF13_DCMI = 13
AF14 = 14
AF15_EVENTOUT = 15
)
// -- UART ---------------------------------------------------------------------
func (uart *UART) configurePins(config UARTConfig) {
// enable the alternate functions on the TX and RX pins
config.TX.ConfigureAltFunc(PinConfig{Mode: PinModeUARTTX}, uart.TxAltFuncSelector)
config.RX.ConfigureAltFunc(PinConfig{Mode: PinModeUARTRX}, uart.RxAltFuncSelector)
}
func (uart *UART) getBaudRateDivisor(baudRate uint32) uint32 {
var clock uint32
switch uart.Bus {
case stm32.USART1, stm32.USART6:
clock = CPUFrequency() / 2 // APB2 Frequency
case stm32.USART2, stm32.USART3, stm32.UART4, stm32.UART5:
clock = CPUFrequency() / 4 // APB1 Frequency
}
return clock / baudRate
}
func (uart *UART) setRegisters() {
uart.rxReg = &uart.Bus.DR
uart.txReg = &uart.Bus.DR
uart.statusReg = &uart.Bus.SR
uart.txEmptyFlag = stm32.USART_SR_TXE
}
// -- SPI ----------------------------------------------------------------------
type SPI struct {
Bus *stm32.SPI_Type
AltFuncSelector uint8
}
func (spi SPI) config8Bits() {
// no-op on this series
}
func (spi SPI) configurePins(config SPIConfig) {
config.SCK.ConfigureAltFunc(PinConfig{Mode: PinModeSPICLK}, spi.AltFuncSelector)
config.SDO.ConfigureAltFunc(PinConfig{Mode: PinModeSPISDO}, spi.AltFuncSelector)
config.SDI.ConfigureAltFunc(PinConfig{Mode: PinModeSPISDI}, spi.AltFuncSelector)
}
func (spi SPI) getBaudRate(config SPIConfig) uint32 {
var clock uint32
switch spi.Bus {
case stm32.SPI1:
clock = CPUFrequency() / 2
case stm32.SPI2, stm32.SPI3:
clock = CPUFrequency() / 4
}
// limit requested frequency to bus frequency and min frequency (DIV256)
freq := config.Frequency
if min := clock / 256; freq < min {
freq = min
} else if freq > clock {
freq = clock
}
// calculate the exact clock divisor (freq=clock/div -> div=clock/freq).
// truncation is fine, since it produces a less-than-or-equal divisor, and
// thus a greater-than-or-equal frequency.
// divisors only come in consecutive powers of 2, so we can use log2 (or,
// equivalently, bits.Len - 1) to convert to respective enum value.
div := bits.Len32(clock/freq) - 1
// but DIV1 (2^0) is not permitted, as the least divisor is DIV2 (2^1), so
// subtract 1 from the log2 value, keeping a lower bound of 0
if div < 0 {
div = 0
} else if div > 0 {
div--
}
// finally, shift the enumerated value into position for SPI CR1
return uint32(div) << stm32.SPI_CR1_BR_Pos
}
// -- I2C ----------------------------------------------------------------------
type I2C struct {
Bus *stm32.I2C_Type
AltFuncSelector uint8
}
func (i2c *I2C) configurePins(config I2CConfig) {
config.SCL.ConfigureAltFunc(PinConfig{Mode: PinModeI2CSCL}, i2c.AltFuncSelector)
config.SDA.ConfigureAltFunc(PinConfig{Mode: PinModeI2CSDA}, i2c.AltFuncSelector)
}
func (i2c *I2C) getFreqRange(config I2CConfig) uint32 {
// all I2C interfaces are on APB1
clock := CPUFrequency() / 4
// convert to MHz
clock /= 1000000
// must be between 2 MHz (or 4 MHz for fast mode (Fm)) and 50 MHz, inclusive
var min, max uint32 = 2, 50
if config.Frequency > 100000 {
min = 4 // fast mode (Fm)
}
if clock < min {
clock = min
} else if clock > max {
clock = max
}
return clock << stm32.I2C_CR2_FREQ_Pos
}
func (i2c *I2C) getRiseTime(config I2CConfig) uint32 {
// These bits must be programmed with the maximum SCL rise time given in the
// I2C bus specification, incremented by 1.
// For instance: in Sm mode, the maximum allowed SCL rise time is 1000 ns.
// If, in the I2C_CR2 register, the value of FREQ[5:0] bits is equal to 0x08
// and PCLK1 = 125 ns, therefore the TRISE[5:0] bits must be programmed with
// 09h (1000 ns / 125 ns = 8 + 1)
freqRange := i2c.getFreqRange(config)
if config.Frequency > 100000 {
// fast mode (Fm) adjustment
freqRange *= 300
freqRange /= 1000
}
return (freqRange + 1) << stm32.I2C_TRISE_TRISE_Pos
}
func (i2c *I2C) getSpeed(config I2CConfig) uint32 {
ccr := func(pclk uint32, freq uint32, coeff uint32) uint32 {
return (((pclk - 1) / (freq * coeff)) + 1) & stm32.I2C_CCR_CCR_Msk
}
sm := func(pclk uint32, freq uint32) uint32 { // standard mode (Sm)
if s := ccr(pclk, freq, 2); s < 4 {
return 4
} else {
return s
}
}
fm := func(pclk uint32, freq uint32, duty uint8) uint32 { // fast mode (Fm)
if duty == DutyCycle2 {
return ccr(pclk, freq, 3)
} else {
return ccr(pclk, freq, 25) | stm32.I2C_CCR_DUTY
}
}
// all I2C interfaces are on APB1
clock := CPUFrequency() / 4
if config.Frequency <= 100000 {
return sm(clock, config.Frequency)
} else {
s := fm(clock, config.Frequency, config.DutyCycle)
if (s & stm32.I2C_CCR_CCR_Msk) == 0 {
return 1
} else {
return s | stm32.I2C_CCR_F_S
}
}
}

198
src/machine/machine_stm32f405.go
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@ -1,198 +0,0 @@
// +build stm32f405
package machine
// Peripheral abstraction layer for the stm32f405
import (
"device/stm32"
"math/bits"
)
func CPUFrequency() uint32 {
return 168000000
}
// Internal use: configured speed of the APB1 and APB2 timers, this should be kept
// in sync with any changes to runtime package which configures the oscillators
// and clock frequencies
const APB1_TIM_FREQ = 42000000 * 2
const APB2_TIM_FREQ = 84000000 * 2
// Alternative peripheral pin functions
const (
AF0_SYSTEM = 0
AF1_TIM1_2 = 1
AF2_TIM3_4_5 = 2
AF3_TIM8_9_10_11 = 3
AF4_I2C1_2_3 = 4
AF5_SPI1_SPI2 = 5
AF6_SPI3 = 6
AF7_USART1_2_3 = 7
AF8_USART4_5_6 = 8
AF9_CAN1_CAN2_TIM12_13_14 = 9
AF10_OTG_FS_OTG_HS = 10
AF11_ETH = 11
AF12_FSMC_SDIO_OTG_HS_1 = 12
AF13_DCMI = 13
AF14 = 14
AF15_EVENTOUT = 15
)
// -- UART ---------------------------------------------------------------------
func (uart *UART) configurePins(config UARTConfig) {
// enable the alternate functions on the TX and RX pins
config.TX.ConfigureAltFunc(PinConfig{Mode: PinModeUARTTX}, uart.TxAltFuncSelector)
config.RX.ConfigureAltFunc(PinConfig{Mode: PinModeUARTRX}, uart.RxAltFuncSelector)
}
func (uart *UART) getBaudRateDivisor(baudRate uint32) uint32 {
var clock uint32
switch uart.Bus {
case stm32.USART1, stm32.USART6:
clock = CPUFrequency() / 2 // APB2 Frequency
case stm32.USART2, stm32.USART3, stm32.UART4, stm32.UART5:
clock = CPUFrequency() / 4 // APB1 Frequency
}
return clock / baudRate
}
// Register names vary by ST processor, these are for STM F405
func (uart *UART) setRegisters() {
uart.rxReg = &uart.Bus.DR
uart.txReg = &uart.Bus.DR
uart.statusReg = &uart.Bus.SR
uart.txEmptyFlag = stm32.USART_SR_TXE
}
// -- SPI ----------------------------------------------------------------------
type SPI struct {
Bus *stm32.SPI_Type
AltFuncSelector uint8
}
func (spi SPI) config8Bits() {
// no-op on this series
}
func (spi SPI) configurePins(config SPIConfig) {
config.SCK.ConfigureAltFunc(PinConfig{Mode: PinModeSPICLK}, spi.AltFuncSelector)
config.SDO.ConfigureAltFunc(PinConfig{Mode: PinModeSPISDO}, spi.AltFuncSelector)
config.SDI.ConfigureAltFunc(PinConfig{Mode: PinModeSPISDI}, spi.AltFuncSelector)
}
func (spi SPI) getBaudRate(config SPIConfig) uint32 {
var clock uint32
switch spi.Bus {
case stm32.SPI1:
clock = CPUFrequency() / 2
case stm32.SPI2, stm32.SPI3:
clock = CPUFrequency() / 4
}
// limit requested frequency to bus frequency and min frequency (DIV256)
freq := config.Frequency
if min := clock / 256; freq < min {
freq = min
} else if freq > clock {
freq = clock
}
// calculate the exact clock divisor (freq=clock/div -> div=clock/freq).
// truncation is fine, since it produces a less-than-or-equal divisor, and
// thus a greater-than-or-equal frequency.
// divisors only come in consecutive powers of 2, so we can use log2 (or,
// equivalently, bits.Len - 1) to convert to respective enum value.
div := bits.Len32(clock/freq) - 1
// but DIV1 (2^0) is not permitted, as the least divisor is DIV2 (2^1), so
// subtract 1 from the log2 value, keeping a lower bound of 0
if div < 0 {
div = 0
} else if div > 0 {
div--
}
// finally, shift the enumerated value into position for SPI CR1
return uint32(div) << stm32.SPI_CR1_BR_Pos
}
// -- I2C ----------------------------------------------------------------------
type I2C struct {
Bus *stm32.I2C_Type
AltFuncSelector uint8
}
func (i2c *I2C) configurePins(config I2CConfig) {
config.SCL.ConfigureAltFunc(PinConfig{Mode: PinModeI2CSCL}, i2c.AltFuncSelector)
config.SDA.ConfigureAltFunc(PinConfig{Mode: PinModeI2CSDA}, i2c.AltFuncSelector)
}
func (i2c *I2C) getFreqRange(config I2CConfig) uint32 {
// all I2C interfaces are on APB1 (42 MHz)
clock := CPUFrequency() / 4
// convert to MHz
clock /= 1000000
// must be between 2 MHz (or 4 MHz for fast mode (Fm)) and 50 MHz, inclusive
var min, max uint32 = 2, 50
if config.Frequency > 10000 {
min = 4 // fast mode (Fm)
}
if clock < min {
clock = min
} else if clock > max {
clock = max
}
return clock << stm32.I2C_CR2_FREQ_Pos
}
func (i2c *I2C) getRiseTime(config I2CConfig) uint32 {
// These bits must be programmed with the maximum SCL rise time given in the
// I2C bus specification, incremented by 1.
// For instance: in Sm mode, the maximum allowed SCL rise time is 1000 ns.
// If, in the I2C_CR2 register, the value of FREQ[5:0] bits is equal to 0x08
// and PCLK1 = 125 ns, therefore the TRISE[5:0] bits must be programmed with
// 09h (1000 ns / 125 ns = 8 + 1)
freqRange := i2c.getFreqRange(config)
if config.Frequency > 100000 {
// fast mode (Fm) adjustment
freqRange *= 300
freqRange /= 1000
}
return (freqRange + 1) << stm32.I2C_TRISE_TRISE_Pos
}
func (i2c *I2C) getSpeed(config I2CConfig) uint32 {
ccr := func(pclk uint32, freq uint32, coeff uint32) uint32 {
return (((pclk - 1) / (freq * coeff)) + 1) & stm32.I2C_CCR_CCR_Msk
}
sm := func(pclk uint32, freq uint32) uint32 { // standard mode (Sm)
if s := ccr(pclk, freq, 2); s < 4 {
return 4
} else {
return s
}
}
fm := func(pclk uint32, freq uint32, duty uint8) uint32 { // fast mode (Fm)
if duty == DutyCycle2 {
return ccr(pclk, freq, 3)
} else {
return ccr(pclk, freq, 25) | stm32.I2C_CCR_DUTY
}
}
// all I2C interfaces are on APB1 (42 MHz)
clock := CPUFrequency() / 4
if config.Frequency <= 100000 {
return sm(clock, config.Frequency)
} else {
s := fm(clock, config.Frequency, config.DutyCycle)
if (s & stm32.I2C_CCR_CCR_Msk) == 0 {
return 1
} else {
return s | stm32.I2C_CCR_F_S
}
}
}

203
src/machine/machine_stm32f407.go
Просмотреть файл

@ -1,203 +0,0 @@
//go:build stm32f407
// +build stm32f407
package machine
// Peripheral abstraction layer for the stm32f407
import (
"device/stm32"
"math/bits"
)
func CPUFrequency() uint32 {
return 168000000
}
// Internal use: configured speed of the APB1 and APB2 timers, this should be kept
// in sync with any changes to runtime package which configures the oscillators
// and clock frequencies
const APB1_TIM_FREQ = 42000000 * 2
const APB2_TIM_FREQ = 84000000 * 2
// Alternative peripheral pin functions
const (
AF0_SYSTEM = 0
AF1_TIM1_2 = 1
AF2_TIM3_4_5 = 2
AF3_TIM8_9_10_11 = 3
AF4_I2C1_2_3 = 4
AF5_SPI1_SPI2 = 5
AF6_SPI3 = 6
AF7_USART1_2_3 = 7
AF8_USART4_5_6 = 8
AF9_CAN1_CAN2_TIM12_13_14 = 9
AF10_OTG_FS_OTG_HS = 10
AF11_ETH = 11
AF12_FSMC_SDIO_OTG_HS_1 = 12
AF13_DCMI = 13
AF14 = 14
AF15_EVENTOUT = 15
)
//---------- UART related code
// Configure the UART.
func (uart *UART) configurePins(config UARTConfig) {
// enable the alternate functions on the TX and RX pins
config.TX.ConfigureAltFunc(PinConfig{Mode: PinModeUARTTX}, uart.TxAltFuncSelector)
config.RX.ConfigureAltFunc(PinConfig{Mode: PinModeUARTRX}, uart.RxAltFuncSelector)
}
// UART baudrate calc based on the bus and clockspeed
// NOTE: keep this in sync with the runtime/runtime_stm32f407.go clock init code
func (uart *UART) getBaudRateDivisor(baudRate uint32) uint32 {
var clock uint32
switch uart.Bus {
case stm32.USART1, stm32.USART6:
clock = CPUFrequency() / 2 // APB2 Frequency
case stm32.USART2, stm32.USART3, stm32.UART4, stm32.UART5:
clock = CPUFrequency() / 4 // APB1 Frequency
}
return clock / baudRate
}
// Register names vary by ST processor, these are for STM F407
func (uart *UART) setRegisters() {
uart.rxReg = &uart.Bus.DR
uart.txReg = &uart.Bus.DR
uart.statusReg = &uart.Bus.SR
uart.txEmptyFlag = stm32.USART_SR_TXE
}
//---------- SPI related types and code
// SPI on the STM32Fxxx using MODER / alternate function pins
type SPI struct {
Bus *stm32.SPI_Type
AltFuncSelector uint8
}
func (spi SPI) config8Bits() {
// no-op on this series
}
func (spi SPI) configurePins(config SPIConfig) {
config.SCK.ConfigureAltFunc(PinConfig{Mode: PinModeSPICLK}, spi.AltFuncSelector)
config.SDO.ConfigureAltFunc(PinConfig{Mode: PinModeSPISDO}, spi.AltFuncSelector)
config.SDI.ConfigureAltFunc(PinConfig{Mode: PinModeSPISDI}, spi.AltFuncSelector)
}
func (spi SPI) getBaudRate(config SPIConfig) uint32 {
var clock uint32
switch spi.Bus {
case stm32.SPI1:
clock = CPUFrequency() / 2
case stm32.SPI2, stm32.SPI3:
clock = CPUFrequency() / 4
}
// limit requested frequency to bus frequency and min frequency (DIV256)
freq := config.Frequency
if min := clock / 256; freq < min {
freq = min
} else if freq > clock {
freq = clock
}
// calculate the exact clock divisor (freq=clock/div -> div=clock/freq).
// truncation is fine, since it produces a less-than-or-equal divisor, and
// thus a greater-than-or-equal frequency.
// divisors only come in consecutive powers of 2, so we can use log2 (or,
// equivalently, bits.Len - 1) to convert to respective enum value.
div := bits.Len32(clock/freq) - 1
// but DIV1 (2^0) is not permitted, as the least divisor is DIV2 (2^1), so
// subtract 1 from the log2 value, keeping a lower bound of 0
if div < 0 {
div = 0
} else if div > 0 {
div--
}
// finally, shift the enumerated value into position for SPI CR1
return uint32(div) << stm32.SPI_CR1_BR_Pos
}
// -- I2C ----------------------------------------------------------------------
type I2C struct {
Bus *stm32.I2C_Type
AltFuncSelector uint8
}
func (i2c *I2C) configurePins(config I2CConfig) {
config.SCL.ConfigureAltFunc(PinConfig{Mode: PinModeI2CSCL}, i2c.AltFuncSelector)
config.SDA.ConfigureAltFunc(PinConfig{Mode: PinModeI2CSDA}, i2c.AltFuncSelector)
}
func (i2c *I2C) getFreqRange(config I2CConfig) uint32 {
// all I2C interfaces are on APB1 (42 MHz)
clock := CPUFrequency() / 4
// convert to MHz
clock /= 1000000
// must be between 2 MHz (or 4 MHz for fast mode (Fm)) and 50 MHz, inclusive
var min, max uint32 = 2, 50
if config.Frequency > 100000 {
min = 4 // fast mode (Fm)
}
if clock < min {
clock = min
} else if clock > max {
clock = max
}
return clock << stm32.I2C_CR2_FREQ_Pos
}
func (i2c *I2C) getRiseTime(config I2CConfig) uint32 {
// These bits must be programmed with the maximum SCL rise time given in the
// I2C bus specification, incremented by 1.
// For instance: in Sm mode, the maximum allowed SCL rise time is 1000 ns.
// If, in the I2C_CR2 register, the value of FREQ[5:0] bits is equal to 0x08
// and PCLK1 = 125 ns, therefore the TRISE[5:0] bits must be programmed with
// 09h (1000 ns / 125 ns = 8 + 1)
freqRange := i2c.getFreqRange(config)
if config.Frequency > 100000 {
// fast mode (Fm) adjustment
freqRange *= 300
freqRange /= 1000
}
return (freqRange + 1) << stm32.I2C_TRISE_TRISE_Pos
}
func (i2c *I2C) getSpeed(config I2CConfig) uint32 {
ccr := func(pclk uint32, freq uint32, coeff uint32) uint32 {
return (((pclk - 1) / (freq * coeff)) + 1) & stm32.I2C_CCR_CCR_Msk
}
sm := func(pclk uint32, freq uint32) uint32 { // standard mode (Sm)
if s := ccr(pclk, freq, 2); s < 4 {
return 4
} else {
return s
}
}
fm := func(pclk uint32, freq uint32, duty uint8) uint32 { // fast mode (Fm)
if duty == DutyCycle2 {
return ccr(pclk, freq, 3)
} else {
return ccr(pclk, freq, 25) | stm32.I2C_CCR_DUTY
}
}
// all I2C interfaces are on APB1 (42 MHz)
clock := CPUFrequency() / 4
if config.Frequency <= 100000 {
return sm(clock, config.Frequency)
} else {
s := fm(clock, config.Frequency, config.DutyCycle)
if (s & stm32.I2C_CCR_CCR_Msk) == 0 {
return 1
} else {
return s | stm32.I2C_CCR_F_S
}
}
}