/* rp2040_hwspi.c - `struct spi` implementation for the RP2040's ARM Primecell SSP (PL022) */ #include #include /* pico-sdk:hardware_spi */ #include /* pico-sdk:hardware_gpio5 */ #include "hw/rp2040_hwspi.h" static void rp2040_hwspi_readwritev(struct spi *_self, const struct bidi_iovec *iov, int iovcnt); struct spi_vtable rp2040_hwspi_vtable = { .readwritev = rp2040_hwspi_readwritev, }; void _rp2040_hwspi_init(struct rp2040_hwspi *self, enum rp2040_hwspi_instance inst_num, enum spi_mode mode, uint baudrate_hz, uint pin_miso, uint pin_mosi, uint pin_clk, uint pin_cs) { /* Be not weary: This is but 12 lines of actual code; and many * lines of comments and assert()s. */ spi_inst_t *inst; assert(self); assert(baudrate_hz); assert(pin_miso != pin_mosi); assert(pin_miso != pin_clk); assert(pin_miso != pin_cs); assert(pin_mosi != pin_clk); assert(pin_mosi != pin_cs); assert(pin_clk != pin_cs); /* I know we called this "hwspi", but we're actually going to * disconnect the CS pin from the PL022 SSP and manually drive * it from software. This is because the PL022 has a maximum * of 16-bit frames, while we need to be able to do *at least* * 32-bit frames (and ideally, much larger). By managing it * ourselves, we can just keep CS pulled low extra-long, * making the frame extra-long. */ /* Regarding the constraints on pin assignments: see the * RP2040 datasheet, table 2, in §1.4.3 "GPIO Functions". */ switch (inst_num) { case RP2040_HWSPI_0: inst = spi0; assert(pin_miso == 0 || pin_miso == 4 || pin_miso == 16 || pin_miso == 20); /*assert(pin_cs == 1 || pin_cs == 5 || pin_cs == 17 || pin_cs == 21);*/ assert(pin_clk == 2 || pin_clk == 6 || pin_clk == 18 || pin_clk == 22); assert(pin_mosi == 3 || pin_mosi == 7 || pin_mosi == 19 || pin_mosi == 23); break; case RP2040_HWSPI_1: inst = spi1; assert(pin_miso == 8 || pin_miso == 12 || pin_miso == 24 || pin_miso == 28); /*assert(pin_cs == 9 || pin_cs == 13 || pin_cs == 25 || pin_cs == 29);*/ assert(pin_clk == 10 || pin_clk == 14 || pin_clk == 26); assert(pin_mosi == 11 || pin_mosi == 15 || pin_mosi == 27); break; default: assert(false); } spi_init(inst, baudrate_hz); spi_set_format(inst, 8, (mode & 0b10) ? SPI_CPOL_1 : SPI_CPOL_0, (mode & 0b01) ? SPI_CPHA_1 : SPI_CPHA_0, SPI_MSB_FIRST); /* Connect the pins to the PL022; set them each to "function * 1" (again, see the RP2040 datasheet, table 2, in §1.4.3 * "GPIO Functions"). * * ("GPIO_FUNC_SPI" is how the pico-sdk spells "function 1", * since on the RP2040 all of the "function 1" functions are * some part of SPI.) */ gpio_set_function(pin_clk, GPIO_FUNC_SPI); gpio_set_function(pin_mosi, GPIO_FUNC_SPI); gpio_set_function(pin_miso, GPIO_FUNC_SPI); /* Initialize the CS pin for software control. */ gpio_init(pin_cs); gpio_set_dir(pin_cs, GPIO_OUT); gpio_put(pin_cs, 1); /* Return. */ self->vtable = &rp2040_hwspi_vtable; self->inst = inst; self->pin_cs = pin_cs; } static void rp2040_hwspi_readwritev(struct spi *_self, const struct bidi_iovec *iov, int iovcnt) { struct rp2040_hwspi *self = (struct rp2040_hwspi *)_self; assert(self); spi_inst_t *inst = self->inst; assert(inst); assert(iov); assert(iovcnt); gpio_put(self->pin_cs, 0); /* TODO: Replace blocking reads+writes with DMA. */ for (int i = 0; i < iovcnt; i++) { if (iov[i].iov_write_src && iov[i].iov_read_dst) spi_write_read_blocking(inst, iov[i].iov_write_src, iov[i].iov_read_dst, iov[i].iov_len); else if (iov[i].iov_write_src) spi_write_blocking(inst, iov[i].iov_write_src, iov[i].iov_len); else if (iov[i].iov_read_dst) spi_read_blocking(inst, 0, iov[i].iov_read_dst, iov[i].iov_len); else assert(false); } gpio_put(self->pin_cs, 1); }