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//go:build rp2350
package machine
import (
"device/rp"
"runtime/volatile"
"unsafe"
)
const (
_NUMBANK0_GPIOS = 48
_NUMBANK0_IRQS = 6
rp2350ExtraReg = 1
_NUMIRQ = 51
notimpl = "rp2350: not implemented"
RESETS_RESET_Msk = 0x1fffffff
initUnreset = rp.RESETS_RESET_ADC |
rp.RESETS_RESET_SPI0 |
rp.RESETS_RESET_SPI1 |
rp.RESETS_RESET_UART0 |
rp.RESETS_RESET_UART1 |
rp.RESETS_RESET_USBCTRL
initDontReset = rp.RESETS_RESET_USBCTRL |
rp.RESETS_RESET_SYSCFG |
rp.RESETS_RESET_PLL_USB |
rp.RESETS_RESET_PLL_SYS |
rp.RESETS_RESET_PADS_QSPI |
rp.RESETS_RESET_IO_QSPI |
rp.RESETS_RESET_JTAG
padEnableMask = rp.PADS_BANK0_GPIO0_IE_Msk |
rp.PADS_BANK0_GPIO0_OD_Msk |
rp.PADS_BANK0_GPIO0_ISO_Msk
)
const (
PinOutput PinMode = iota
PinInput
PinInputPulldown
PinInputPullup
PinAnalog
PinUART
PinPWM
PinI2C
PinSPI
PinPIO0
PinPIO1
PinPIO2
)
const (
clkGPOUT0 clockIndex = iota // GPIO Muxing 0
clkGPOUT1 // GPIO Muxing 1
clkGPOUT2 // GPIO Muxing 2
clkGPOUT3 // GPIO Muxing 3
clkRef // Watchdog and timers reference clock
clkSys // Processors, bus fabric, memory, memory mapped registers
clkPeri // Peripheral clock for UART and SPI
ClkHSTX // High speed interface
clkUSB // USB clock
clkADC // ADC clock
numClocks
)
func calcClockDiv(srcFreq, freq uint32) uint32 {
// Div register is 4.16 int.frac divider so multiply by 2^16 (left shift by 16)
return uint32((uint64(srcFreq) << 16) / uint64(freq))
}
type clocksType struct {
clk [numClocks]clockType
dftclk_xosc_ctrl volatile.Register32
dftclk_rosc_ctrl volatile.Register32
dftclk_lposc_ctrl volatile.Register32
resus struct {
ctrl volatile.Register32
status volatile.Register32
}
fc0 fc
wakeEN0 volatile.Register32
wakeEN1 volatile.Register32
sleepEN0 volatile.Register32
sleepEN1 volatile.Register32
enabled0 volatile.Register32
enabled1 volatile.Register32
intR volatile.Register32
intE volatile.Register32
intF volatile.Register32
intS volatile.Register32
}
// GPIO function selectors
const (
// Connect the high-speed transmit peripheral (HSTX) to GPIO.
fnHSTX pinFunc = 0
fnSPI pinFunc = 1 // Connect one of the internal PL022 SPI peripherals to GPIO
fnUART pinFunc = 2
fnI2C pinFunc = 3
// Connect a PWM slice to GPIO. There are eight PWM slices,
// each with two outputchannels (A/B). The B pin can also be used as an input,
// for frequency and duty cyclemeasurement
fnPWM pinFunc = 4
// Software control of GPIO, from the single-cycle IO (SIO) block.
// The SIO function (F5)must be selected for the processors to drive a GPIO,
// but the input is always connected,so software can check the state of GPIOs at any time.
fnSIO pinFunc = 5
// Connect one of the programmable IO blocks (PIO) to GPIO. PIO can implement a widevariety of interfaces,
// and has its own internal pin mapping hardware, allowing flexibleplacement of digital interfaces on bank 0 GPIOs.
// The PIO function (F6, F7, F8) must beselected for PIO to drive a GPIO, but the input is always connected,
// so the PIOs canalways see the state of all pins.
fnPIO0, fnPIO1, fnPIO2 pinFunc = 6, 7, 8
// General purpose clock outputs. Can drive a number of internal clocks (including PLL
// outputs) onto GPIOs, with optional integer divide.
fnGPCK pinFunc = 9
// QSPI memory interface peripheral, used for execute-in-place from external QSPI flash or PSRAM memory devices.
fnQMI pinFunc = 9
// USB power control signals to/from the internal USB controller.
fnUSB pinFunc = 10
fnUARTAlt pinFunc = 11
fnNULL pinFunc = 0x1f
)
// Configure configures the gpio pin as per mode.
func (p Pin) Configure(config PinConfig) {
if p == NoPin {
return
}
p.init()
mask := uint32(1) << p
switch config.Mode {
case PinOutput:
p.setFunc(fnSIO)
rp.SIO.GPIO_OE_SET.Set(mask)
case PinInput:
p.setFunc(fnSIO)
p.pulloff()
case PinInputPulldown:
p.setFunc(fnSIO)
p.pulldown()
case PinInputPullup:
p.setFunc(fnSIO)
p.pullup()
case PinAnalog:
p.setFunc(fnNULL)
p.pulloff()
case PinUART:
p.setFunc(fnUART)
case PinPWM:
p.setFunc(fnPWM)
case PinI2C:
// IO config according to 4.3.1.3 of rp2040 datasheet.
p.setFunc(fnI2C)
p.pullup()
p.setSchmitt(true)
p.setSlew(false)
case PinSPI:
p.setFunc(fnSPI)
case PinPIO0:
p.setFunc(fnPIO0)
case PinPIO1:
p.setFunc(fnPIO1)
case PinPIO2:
p.setFunc(fnPIO2)
}
}
var (
timer = (*timerType)(unsafe.Pointer(rp.TIMER0))
)
// Enable or disable a specific interrupt on the executing core.
// num is the interrupt number which must be in [0,_NUMIRQ).
func irqSet(num uint32, enabled bool) {
if num >= _NUMIRQ {
return
}
register_index := num / 32
var mask uint32 = 1 << (num % 32)
if enabled {
// Clear pending before enable
//(if IRQ is actually asserted, it will immediately re-pend)
if register_index == 0 {
rp.PPB.NVIC_ICPR0.Set(mask)
rp.PPB.NVIC_ISER0.Set(mask)
} else {
rp.PPB.NVIC_ICPR1.Set(mask)
rp.PPB.NVIC_ISER1.Set(mask)
}
} else {
if register_index == 0 {
rp.PPB.NVIC_ICER0.Set(mask)
} else {
rp.PPB.NVIC_ICER1.Set(mask)
}
}
}
func (clks *clocksType) initRTC() {} // No RTC on RP2350.
func (clks *clocksType) initTicks() {
rp.TICKS.SetTIMER0_CTRL_ENABLE(0)
rp.TICKS.SetTIMER0_CYCLES(12)
rp.TICKS.SetTIMER0_CTRL_ENABLE(1)
}
func EnterBootloader() {
enterBootloader()
}
// startTick starts the watchdog tick.
// On RP2040, the watchdog contained a tick generator used to generate a 1μs tick for the watchdog. This was also
// distributed to the system timer. On RP2350, the watchdog instead takes a tick input from the system-level ticks block. See Section 8.5.
func (wd *watchdogImpl) startTick(cycles uint32) {
rp.TICKS.WATCHDOG_CTRL.SetBits(1)
}
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