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circuitpython/ports/nrf/common-hal/busio/SPI.c
Scott Shawcroft 9d91111b1b
Move atmel-samd to tinyusb and support nRF flash. 
This started while adding USB MIDI support (and descriptor support is
in this change.) When seeing that I'd have to implement the MIDI class
logic twice, once for atmel-samd and once for nrf, I decided to refactor
the USB stack so its shared across ports. This has led to a number of
changes that remove items from the ports folder and move them into
supervisor.

Furthermore, we had external SPI flash support for nrf pending so I
factored out the connection between the usb stack and the flash API as
well. This PR also includes the QSPI support for nRF.
2018-11-08 17:25:30 -08:00

330 lines
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/*
* SPI Master library for nRF5x.
* Copyright (c) 2015 Arduino LLC
* Copyright (c) 2016 Sandeep Mistry All right reserved.
* Copyright (c) 2017 hathach
* Copyright (c) 2018 Artur Pacholec
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include "shared-bindings/busio/SPI.h"
#include "py/mperrno.h"
#include "py/runtime.h"
#include "nrfx_spim.h"
#include "nrf_gpio.h"
STATIC spim_peripheral_t spim_peripherals[] = {
#if NRFX_CHECK(NRFX_SPIM3_ENABLED)
// SPIM3 exists only on nRF52840 and supports 32MHz max. All other SPIM's are only 8MHz max.
// Allocate SPIM3 first.
{ .spim = NRFX_SPIM_INSTANCE(3),
.max_frequency_MHz = 32,
.max_xfer_size = SPIM3_EASYDMA_MAXCNT_SIZE,
},
#endif
#if NRFX_CHECK(NRFX_SPIM2_ENABLED)
// SPIM2 is not shared with a TWIM, so allocate before the shared ones.
{ .spim = NRFX_SPIM_INSTANCE(2),
.max_frequency_MHz = 8,
.max_xfer_size = SPIM2_EASYDMA_MAXCNT_SIZE,
},
#endif
#if NRFX_CHECK(NRFX_SPIM1_ENABLED)
// SPIM1 and TWIM1 share an address.
{ .spim = NRFX_SPIM_INSTANCE(1),
.max_frequency_MHz = 8,
.max_xfer_size = SPIM1_EASYDMA_MAXCNT_SIZE,
},
#endif
#if NRFX_CHECK(NRFX_SPIM0_ENABLED)
// SPIM0 and TWIM0 share an address.
{ .spim = NRFX_SPIM_INSTANCE(0),
.max_frequency_MHz = 8,
.max_xfer_size = SPIM0_EASYDMA_MAXCNT_SIZE,
},
#endif
};
STATIC bool never_reset[4];
void spi_reset(void) {
for (size_t i = 0 ; i < MP_ARRAY_SIZE(spim_peripherals); i++) {
if (never_reset[i]) {
continue;
}
nrf_spim_disable(spim_peripherals[i].spim.p_reg);
}
}
void common_hal_busio_spi_never_reset(busio_spi_obj_t *self) {
for (size_t i = 0 ; i < MP_ARRAY_SIZE(spim_peripherals); i++) {
if (self->spim_peripheral == &spim_peripherals[i]) {
never_reset[i] = true;
never_reset_pin_number(self->clock_pin_number);
never_reset_pin_number(self->MOSI_pin_number);
never_reset_pin_number(self->MISO_pin_number);
break;
}
}
}
// Convert frequency to clock-speed-dependent value. Choose the next lower baudrate if in between
// available baudrates.
static nrf_spim_frequency_t baudrate_to_spim_frequency(const uint32_t baudrate) {
static const struct {
const uint32_t boundary;
nrf_spim_frequency_t spim_frequency;
} baudrate_map[] = {
#ifdef SPIM_FREQUENCY_FREQUENCY_M32
{ 32000000, NRF_SPIM_FREQ_32M },
#endif
#ifdef SPIM_FREQUENCY_FREQUENCY_M16
{ 16000000, NRF_SPIM_FREQ_16M },
#endif
{ 8000000, NRF_SPIM_FREQ_8M },
{ 4000000, NRF_SPIM_FREQ_4M },
{ 2000000, NRF_SPIM_FREQ_2M },
{ 1000000, NRF_SPIM_FREQ_1M },
{ 500000, NRF_SPIM_FREQ_500K },
{ 250000, NRF_SPIM_FREQ_250K },
{ 0, NRF_SPIM_FREQ_125K },
};
size_t i = 0;
uint32_t boundary;
do {
boundary = baudrate_map[i].boundary;
if (baudrate >= boundary) {
return baudrate_map[i].spim_frequency;
}
i++;
} while (boundary != 0);
// Should not get here.
return 0;
}
void common_hal_busio_spi_construct(busio_spi_obj_t *self, const mcu_pin_obj_t * clock, const mcu_pin_obj_t * mosi, const mcu_pin_obj_t * miso) {
// Find a free instance.
self->spim_peripheral = NULL;
for (size_t i = 0 ; i < MP_ARRAY_SIZE(spim_peripherals); i++) {
if ((spim_peripherals[i].spim.p_reg->ENABLE & SPIM_ENABLE_ENABLE_Msk) == 0) {
self->spim_peripheral = &spim_peripherals[i];
break;
}
}
if (self->spim_peripheral == NULL) {
mp_raise_ValueError(translate("All SPI peripherals are in use"));
}
nrfx_spim_config_t config = NRFX_SPIM_DEFAULT_CONFIG;
config.frequency = NRF_SPIM_FREQ_8M;
config.sck_pin = clock->number;
self->clock_pin_number = clock->number;
claim_pin(clock);
if (mosi != (mcu_pin_obj_t*)&mp_const_none_obj) {
config.mosi_pin = mosi->number;
self->MOSI_pin_number = mosi->number;
claim_pin(mosi);
} else {
self->MOSI_pin_number = NO_PIN;
}
if (miso != (mcu_pin_obj_t*)&mp_const_none_obj) {
config.miso_pin = miso->number;
self->MISO_pin_number = mosi->number;
claim_pin(miso);
} else {
self->MISO_pin_number = NO_PIN;
}
nrfx_err_t err = nrfx_spim_init(&self->spim_peripheral->spim, &config, NULL, NULL);
// A soft reset doesn't uninit the driver so we might end up with a invalid state
if (err == NRFX_ERROR_INVALID_STATE) {
nrfx_spim_uninit(&self->spim_peripheral->spim);
err = nrfx_spim_init(&self->spim_peripheral->spim, &config, NULL, NULL);
}
if (err != NRFX_SUCCESS) {
common_hal_busio_spi_deinit(self);
mp_raise_OSError(MP_EIO);
}
}
bool common_hal_busio_spi_deinited(busio_spi_obj_t *self) {
return self->clock_pin_number == NO_PIN;
}
void common_hal_busio_spi_deinit(busio_spi_obj_t *self) {
if (common_hal_busio_spi_deinited(self))
return;
nrfx_spim_uninit(&self->spim_peripheral->spim);
reset_pin_number(self->clock_pin_number);
reset_pin_number(self->MOSI_pin_number);
reset_pin_number(self->MISO_pin_number);
}
bool common_hal_busio_spi_configure(busio_spi_obj_t *self, uint32_t baudrate, uint8_t polarity, uint8_t phase, uint8_t bits) {
// nrf52 does not support 16 bit
if (bits != 8) {
return false;
}
// Set desired frequency, rounding down, and don't go above available frequency for this SPIM.
nrf_spim_frequency_set(self->spim_peripheral->spim.p_reg,
baudrate_to_spim_frequency(MIN(baudrate,
self->spim_peripheral->max_frequency_MHz * 1000000)));
nrf_spim_mode_t mode = NRF_SPIM_MODE_0;
if (polarity) {
mode = (phase) ? NRF_SPIM_MODE_3 : NRF_SPIM_MODE_2;
} else {
mode = (phase) ? NRF_SPIM_MODE_1 : NRF_SPIM_MODE_0;
}
nrf_spim_configure(self->spim_peripheral->spim.p_reg, mode, NRF_SPIM_BIT_ORDER_MSB_FIRST);
return true;
}
bool common_hal_busio_spi_try_lock(busio_spi_obj_t *self) {
bool grabbed_lock = false;
// NRFX_CRITICAL_SECTION_ENTER();
if (!self->has_lock) {
grabbed_lock = true;
self->has_lock = true;
}
// NRFX_CRITICAL_SECTION_EXIT();
return grabbed_lock;
}
bool common_hal_busio_spi_has_lock(busio_spi_obj_t *self) {
return self->has_lock;
}
void common_hal_busio_spi_unlock(busio_spi_obj_t *self) {
self->has_lock = false;
}
bool common_hal_busio_spi_write(busio_spi_obj_t *self, const uint8_t *data, size_t len) {
if (len == 0)
return true;
const uint32_t max_xfer_size = self->spim_peripheral->max_xfer_size;
const uint32_t parts = len / max_xfer_size;
const uint32_t remainder = len % max_xfer_size;
for (uint32_t i = 0; i < parts; ++i) {
const nrfx_spim_xfer_desc_t xfer = NRFX_SPIM_XFER_TX(data + i * max_xfer_size, max_xfer_size);
if (nrfx_spim_xfer(&self->spim_peripheral->spim, &xfer, 0) != NRFX_SUCCESS)
return false;
}
if (remainder > 0) {
const nrfx_spim_xfer_desc_t xfer = NRFX_SPIM_XFER_TX(data + parts * max_xfer_size, remainder);
if (nrfx_spim_xfer(&self->spim_peripheral->spim, &xfer, 0) != NRFX_SUCCESS)
return false;
}
return true;
}
bool common_hal_busio_spi_read(busio_spi_obj_t *self, uint8_t *data, size_t len, uint8_t write_value) {
if (len == 0)
return true;
const uint32_t max_xfer_size = self->spim_peripheral->max_xfer_size;
const uint32_t parts = len / max_xfer_size;
const uint32_t remainder = len % max_xfer_size;
for (uint32_t i = 0; i < parts; ++i) {
const nrfx_spim_xfer_desc_t xfer = NRFX_SPIM_XFER_RX(data + i * max_xfer_size, max_xfer_size);
if (nrfx_spim_xfer(&self->spim_peripheral->spim, &xfer, 0) != NRFX_SUCCESS)
return false;
}
if (remainder > 0) {
const nrfx_spim_xfer_desc_t xfer = NRFX_SPIM_XFER_RX(data + parts * max_xfer_size, remainder);
if (nrfx_spim_xfer(&self->spim_peripheral->spim, &xfer, 0) != NRFX_SUCCESS)
return false;
}
return true;
}
bool common_hal_busio_spi_transfer(busio_spi_obj_t *self, uint8_t *data_out, uint8_t *data_in, size_t len) {
if (len == 0)
return true;
const uint32_t max_xfer_size = self->spim_peripheral->max_xfer_size;
const uint32_t parts = len / max_xfer_size;
const uint32_t remainder = len % max_xfer_size;
for (uint32_t i = 0; i < parts; ++i) {
const nrfx_spim_xfer_desc_t xfer = NRFX_SPIM_SINGLE_XFER(data_out + i * max_xfer_size, max_xfer_size,
data_in + i * max_xfer_size, max_xfer_size);
if (nrfx_spim_xfer(&self->spim_peripheral->spim, &xfer, 0) != NRFX_SUCCESS)
return false;
}
if (remainder > 0) {
const nrfx_spim_xfer_desc_t xfer = NRFX_SPIM_SINGLE_XFER(data_out + parts * max_xfer_size, remainder,
data_in + parts * max_xfer_size, remainder);
if (nrfx_spim_xfer(&self->spim_peripheral->spim, &xfer, 0) != NRFX_SUCCESS)
return false;
}
return true;
}
uint32_t common_hal_busio_spi_get_frequency(busio_spi_obj_t* self) {
switch (self->spim_peripheral->spim.p_reg->FREQUENCY) {
case NRF_SPIM_FREQ_125K:
return 125000;
case NRF_SPIM_FREQ_250K:
return 250000;
case NRF_SPIM_FREQ_500K:
return 500000;
case NRF_SPIM_FREQ_1M:
return 1000000;
case NRF_SPIM_FREQ_2M:
return 2000000;
case NRF_SPIM_FREQ_4M:
return 4000000;
case NRF_SPIM_FREQ_8M:
return 8000000;
#ifdef SPIM_FREQUENCY_FREQUENCY_M16
case NRF_SPIM_FREQ_16M:
return 16000000;
#endif
#ifdef SPIM_FREQUENCY_FREQUENCY_M32
case NRF_SPIM_FREQ_32M:
return 32000000;
#endif
default:
return 0;
}
}
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