mirror of
https://github.com/italicsjenga/rp-hal-boards.git
synced 2024-12-25 21:41:31 +11:00
439 lines
13 KiB
Rust
439 lines
13 KiB
Rust
//! # Pico Interpolator Example
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//!
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//! Example demonstrating the usage of the hardware interpolator.
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//!
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//! Runs several test programs, outputs the result on LEDs.
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//! Green led for successful test connects to GPIO3.
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//! Red led for unsuccessful test connects to GPIO4.
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//! In case of failure, the system LED blinks the number of the test.
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//! In case of success, the system LED stays lit.
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//!
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//! See the `Cargo.toml` file for Copyright and license details.
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#![no_std]
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#![no_main]
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// The macro for our start-up function
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use rp_pico::entry;
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// GPIO traits
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use embedded_hal::digital::v2::OutputPin;
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// Ensure we halt the program on panic (if we don't mention this crate it won't
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// be linked)
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use panic_halt as _;
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// A shorter alias for the Peripheral Access Crate, which provides low-level
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// register access
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use rp_pico::hal::pac;
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// A shorter alias for the Hardware Abstraction Layer, which provides
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// higher-level drivers.
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use rp_pico::hal;
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// Pull in any important traits
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use rp_pico::hal::prelude::*;
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use rp_pico::hal::sio::{Interp, Interp0, Interp1, Lane, LaneCtrl};
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/// Entry point to our bare-metal application.
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///
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/// The `#[entry]` macro ensures the Cortex-M start-up code calls this function
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/// as soon as all global variables are initialised.
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///
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/// The function configures the RP2040 peripherals, then just reads the button
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/// and sets the LED appropriately.
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#[entry]
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fn main() -> ! {
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// Grab our singleton objects
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let mut pac = pac::Peripherals::take().unwrap();
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let core = pac::CorePeripherals::take().unwrap();
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// Set up the watchdog driver - needed by the clock setup code
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let mut watchdog = hal::Watchdog::new(pac.WATCHDOG);
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// Configure the clocks
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//
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// The default is to generate a 125 MHz system clock
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let clocks = hal::clocks::init_clocks_and_plls(
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rp_pico::XOSC_CRYSTAL_FREQ,
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pac.XOSC,
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pac.CLOCKS,
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pac.PLL_SYS,
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pac.PLL_USB,
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&mut pac.RESETS,
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&mut watchdog,
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)
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.ok()
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.unwrap();
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// The delay object lets us wait for specified amounts of time (in
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// milliseconds)
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let mut delay = cortex_m::delay::Delay::new(core.SYST, clocks.system_clock.freq().to_Hz());
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// The single-cycle I/O block controls our GPIO pins
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let mut sio = hal::Sio::new(pac.SIO);
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// Set the pins up according to their function on this particular board
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let pins = rp_pico::Pins::new(
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pac.IO_BANK0,
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pac.PADS_BANK0,
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sio.gpio_bank0,
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&mut pac.RESETS,
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);
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// Our LED outputs
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let mut system_led_pin = pins.led.into_push_pull_output();
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let mut green_led_pin = pins.gpio3.into_push_pull_output();
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let mut red_led_pin = pins.gpio4.into_push_pull_output();
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system_led_pin.set_low().unwrap();
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green_led_pin.set_low().unwrap();
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red_led_pin.set_low().unwrap();
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let mut choose_led = |index: u32, result: bool| {
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if result {
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// blink the green led once to indicate success
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green_led_pin.set_high().unwrap();
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delay.delay_ms(500);
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green_led_pin.set_low().unwrap();
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delay.delay_ms(500);
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} else {
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// turn the red led on to indicate failure
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// and blink the on board led to indicate which test failed, looping forever
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red_led_pin.set_high().unwrap();
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loop {
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for _ in 0..index {
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system_led_pin.set_high().unwrap();
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delay.delay_ms(200);
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system_led_pin.set_low().unwrap();
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delay.delay_ms(200);
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}
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delay.delay_ms(1000);
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}
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}
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};
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// Run forever, setting the LED according to the button
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choose_led(1, multiplication_table(&mut sio.interp0));
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choose_led(2, moving_mask(&mut sio.interp0));
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choose_led(3, cross_lanes(&mut sio.interp0));
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choose_led(4, simple_blend1(&mut sio.interp0));
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choose_led(5, simple_blend2(&mut sio.interp0));
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choose_led(6, clamp(&mut sio.interp1));
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choose_led(7, texture_mapping(&mut sio.interp0));
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// turn the on board led on to indicate testing is done
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system_led_pin.set_high().unwrap();
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loop {
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delay.delay_ms(1000);
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}
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}
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fn multiplication_table(interp: &mut Interp0) -> bool {
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//get the default configuration that just keep adding base into accum
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let config = LaneCtrl::new();
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//write the configuration to the hardware.
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interp.get_lane0().set_ctrl(config.encode());
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//set the accumulator to 0 and the base to 9
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interp.get_lane0().set_accum(0);
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interp.get_lane0().set_base(9);
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//the expected output for comparison
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let expected = [9, 18, 27, 36, 45, 54, 63, 72, 81, 90];
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for i in expected {
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//returns the value of accum + base and sets accum to the same value
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let value = interp.get_lane0().pop();
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if value != i {
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return false; //inform that the interpolator did not return the expected value
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}
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}
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true
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}
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fn moving_mask(interp: &mut Interp0) -> bool {
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//get the default configuration that just keep adding base into accum
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let mut config = LaneCtrl::new();
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interp.get_lane0().set_accum(0x1234ABCD);
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let expected = [
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0x0000_000D,
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0x0000_00C0,
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0x0000_0B00,
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0x0000_A000,
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0x0004_0000,
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0x0030_0000,
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0x0200_0000,
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0x1000_0000,
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];
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for i in 0..8 {
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// LSB, then MSB. These are inclusive, so 0,31 means "the entire 32 bit register"
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config.mask_lsb = i * 4;
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config.mask_msb = i * 4 + 3;
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interp.get_lane0().set_ctrl(config.encode());
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// Reading read_raw() returns the lane data
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// after shifting, masking and sign extending, without adding base
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if interp.get_lane0().read_raw() != expected[i as usize] {
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return false;
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}
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}
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let signed_expected = [
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0xFFFF_FFFD,
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0xFFFF_FFC0,
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0xFFFF_FB00,
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0xFFFF_A000,
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0x0004_0000,
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0x0030_0000,
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0x0200_0000,
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0x1000_0000,
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];
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config.signed = true;
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for i in 0..8 {
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config.mask_lsb = i * 4;
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config.mask_msb = i * 4 + 3;
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interp.get_lane0().set_ctrl(config.encode());
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if interp.get_lane0().read_raw() != signed_expected[i as usize] {
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return false;
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}
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}
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true
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}
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fn cross_lanes(interp: &mut Interp0) -> bool {
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// this configuration will at the time of pop()
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// when applied to lane0 : set lane0 accumulator to the result from lane1
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// when applied to lane1 : set lane1 accumulator to the result from lane0
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let config = LaneCtrl {
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cross_result: true,
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..LaneCtrl::new()
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};
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let encoded_config = config.encode();
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// each lane is used through an accessor,
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// as lanes mutate each other, they can not be borrowed at the same time
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interp.get_lane0().set_ctrl(encoded_config);
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interp.get_lane1().set_ctrl(encoded_config);
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interp.get_lane0().set_accum(123);
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interp.get_lane1().set_accum(456);
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// lane0 will add 1 to its result, lane1 will add nothing
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interp.get_lane0().set_base(1);
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interp.get_lane1().set_base(0);
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let expected = [
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(124, 456),
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(457, 124),
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(125, 457),
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(458, 125),
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(126, 458),
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(459, 126),
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(127, 459),
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(460, 127),
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(128, 460),
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(461, 128),
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];
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for i in expected {
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if i != (interp.get_lane0().peek(), interp.get_lane1().pop()) {
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return false;
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}
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}
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true
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}
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fn simple_blend1(interp: &mut Interp0) -> bool {
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let config = LaneCtrl {
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blend: true,
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..LaneCtrl::new()
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};
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//enable blend mode
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interp.get_lane0().set_ctrl(config.encode());
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//make sure the default configuration is in lane1 as the value may be shifted and masked.
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interp.get_lane1().set_ctrl(LaneCtrl::new().encode());
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//set the minimum value for interp.get_lane0().set_accum(0) 0/256
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interp.get_lane0().set_base(500);
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//set the maximum value which is inaccessible
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// as the blend is done between 0/256 and 255/256
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interp.get_lane1().set_base(1000);
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let expected = [500, 582, 666, 748, 832, 914, 998];
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for i in 0..=6 {
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interp.get_lane1().set_accum(255 * i / 6);
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if expected[i as usize] != interp.get_lane1().peek() {
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return false;
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}
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}
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true
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}
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fn simple_blend2(interp: &mut Interp0) -> bool {
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let config = LaneCtrl {
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blend: true,
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..LaneCtrl::new()
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};
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//enable blend mode
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interp.get_lane0().set_ctrl(config.encode());
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interp.get_lane0().set_base((-1000i32) as u32);
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interp.get_lane1().set_base(1000);
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let mut config1 = LaneCtrl {
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signed: true,
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..LaneCtrl::new()
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};
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interp.get_lane1().set_ctrl(config1.encode());
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let expected_signed = [-1000, -672, -336, -8, 328, 656, 992];
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for i in 0..=6 {
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// write a value between 0 and 256 (exclusive)
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interp.get_lane1().set_accum(255 * i / 6);
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// reads it as a value between -1000 and 1000 (exclusive)
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if interp.get_lane1().peek() as i32 != expected_signed[i as usize] {
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return false;
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}
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}
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config1.signed = false;
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interp.get_lane1().set_ctrl(config1.encode());
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let expected_unsigned = [
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0xfffffc18, 0xd5fffd60, 0xaafffeb0, 0x80fffff8, 0x56000148, 0x2c000290, 0x010003e0,
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];
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for i in 0..=6 {
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interp.get_lane1().set_accum(255 * i / 6);
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// reads a value between 4294966296 and 1000
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if interp.get_lane1().peek() != expected_unsigned[i as usize] {
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return false;
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}
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}
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true
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}
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///Divides by 4 and clamp the value between 0 and 255 inclusive
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fn clamp(interp: &mut Interp1) -> bool {
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// Enables Clamp ONLY AVAILABLE ON Interp1
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// shift two bits to the right and mask the two most significant bits
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// because sign extension is made after the mask
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let config = LaneCtrl {
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clamp: true,
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shift: 2,
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mask_lsb: 0,
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mask_msb: 29,
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signed: true,
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..LaneCtrl::new()
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};
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interp.get_lane0().set_ctrl(config.encode());
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//set minimum value of result
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interp.get_lane0().set_base(0);
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//set maximum value of result
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interp.get_lane1().set_base(255);
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let values: [(i32, i32); 9] = [
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(-1024, 0),
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(-768, 0),
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(-512, 0),
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(-256, 0),
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(0, 0),
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(256, 64),
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(512, 128),
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(768, 192),
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(1024, 255),
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];
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for (arg, result) in values {
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interp.get_lane0().set_accum(arg as u32);
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if result != interp.get_lane0().peek() as i32 {
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return false;
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}
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}
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true
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}
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fn texture_mapping(interp: &mut Interp0) -> bool {
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#[rustfmt::skip]
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let texture: [u8;16] = [
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0x00, 0x01, 0x02, 0x03,
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0x10, 0x11, 0x12, 0x13,
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0x20, 0x21, 0x22, 0x23,
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0x30, 0x31, 0x32, 0x33,
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];
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// the position will be given in fixed point with 16 bits
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// fractional part
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let uv_fractional_bits = 16;
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let texture_width_bits = 2;
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let texture_height_bits = 2;
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// bits
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// 3322222222221111 1111110000000000
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// 1098765432109876 5432109876543210
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// accum0 u axis coordinate xx xxxxxxxxxxxxxxxx 18 bits
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// after shift and mask xx
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// accum1 v axis xx xxxxxxxxxxxxxxxx 18 bits
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// after shift and mask xx
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// add_raw make the interpolator increment the accumulator
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// with the base value without masking or shifting
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let config0 = LaneCtrl {
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add_raw: true,
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shift: uv_fractional_bits,
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mask_lsb: 0,
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mask_msb: texture_width_bits - 1,
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..LaneCtrl::new()
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};
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interp.get_lane0().set_ctrl(config0.encode());
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let config1 = LaneCtrl {
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add_raw: true,
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shift: uv_fractional_bits - texture_width_bits,
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mask_lsb: texture_width_bits,
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mask_msb: texture_width_bits + texture_height_bits - 1,
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..LaneCtrl::new()
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};
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interp.get_lane1().set_ctrl(config1.encode());
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interp.set_base(0);
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// set starting position to 0x0
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// will move 1/2 a pixel horizontally
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// and 1/3 a pixel vertically per call to pop()
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interp.get_lane0().set_accum(0);
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interp.get_lane0().set_base(65536 / 2);
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interp.get_lane1().set_accum(0);
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interp.get_lane1().set_base(65536 / 3);
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let expected = [
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0x00, 0x00, 0x01, 0x01, 0x12, 0x12, 0x13, 0x23, 0x20, 0x20, 0x31, 0x31,
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];
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for i in expected {
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if i != texture[interp.pop() as usize] {
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return false;
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}
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}
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// reset the starting position
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interp.get_lane0().set_accum(0);
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interp.get_lane1().set_accum(0);
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interp.set_base(texture.as_ptr() as u32);
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for i in expected {
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// This is unsafe and should be done extremely carefully
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// remember to follow memory alignment,
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// reading or writing an unaligned address will crash
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if i != unsafe { *(interp.pop() as *const u8) } {
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return false;
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}
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}
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true
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}
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// End of file
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