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Implement basic initialisation and data writing

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Wesley Moore 2018-11-14 15:26:09 +11:00
parent 92a277f65b
commit 2b24889e83
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GPG key ID: BF67766C0BC2D0EE
3 changed files with 108 additions and 16 deletions
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44
src/command.rs
View file

@ -42,9 +42,12 @@ pub enum RamOption {
#[derive(Clone, Copy)] #[derive(Clone, Copy)]
pub enum DeepSleepMode { pub enum DeepSleepMode {
Mode1, /// Not sleeping
Mode2,
Normal, Normal,
/// Deep sleep with RAM preserved
Mode1,
/// Deep sleep RAM not preserved
Mode2,
} }
pub enum Command { pub enum Command {
@ -204,13 +207,14 @@ macro_rules! pack {
} }
impl Command { impl Command {
fn execute<I: DisplayInterface>(self, interface: &mut I) -> Result<(), I::Error> { pub(crate) fn execute<I: DisplayInterface>(self, interface: &mut I) -> Result<(), I::Error> {
use self::Command::*; use self::Command::*;
let mut buf = [0u8; 4]; let mut buf = [0u8; 4];
let (command, data) = match self { let (command, data) = match self {
DriverOutputControl(gate_lines, scanning_seq_and_dir) => { DriverOutputControl(gate_lines, scanning_seq_and_dir) => {
pack!(buf, 0x01, [0xD3, 0x00, 0x00]) let [upper, lower] = u16_as_u8(gate_lines);
pack!(buf, 0x01, [lower, upper, scanning_seq_and_dir])
} }
GateDrivingVoltage(voltages) => { GateDrivingVoltage(voltages) => {
pack!(buf, 0x03, [voltages]) pack!(buf, 0x03, [voltages])
@ -271,8 +275,9 @@ impl Command {
// } // }
// VCOMSenseDuration(u8) => { // VCOMSenseDuration(u8) => {
// } // }
// WriteVCOM(u8) => { WriteVCOM(value) => {
// } pack!(buf, 0x2C, [value])
}
DummyLinePeriod(period) => { DummyLinePeriod(period) => {
debug_assert!(Contains::contains(&(0..=MAX_DUMMY_LINE_PERIOD), period)); debug_assert!(Contains::contains(&(0..=MAX_DUMMY_LINE_PERIOD), period));
pack!(buf, 0x3A, [period]) pack!(buf, 0x3A, [period])
@ -317,6 +322,33 @@ impl Command {
} }
} }
impl<'buf> BufCommand<'buf> {
pub(crate) fn execute<I: DisplayInterface>(self, interface: &mut I) -> Result<(), I::Error> {
use self::BufCommand::*;
let (command, data) = match self {
WriteBlackData(buffer) => {
// TODO: Handle rotation
(0x24, buffer)
}
WriteRedData(buffer) => {
// TODO: Handle rotation
(0x26, buffer)
}
WriteLUT(buffer) => {
(0x32, buffer)
}
};
interface.send_command(command)?;
if data.len() == 0 {
Ok(())
} else {
interface.send_data(data)
}
}
}
impl<C> Contains<C> for core::ops::Range<C> where C: Copy + PartialOrd { impl<C> Contains<C> for core::ops::Range<C> where C: Copy + PartialOrd {
fn contains(&self, item: C) -> bool { fn contains(&self, item: C) -> bool {
item >= self.start && item < self.end item >= self.start && item < self.end

69
src/display.rs
View file

@ -1,12 +1,21 @@
use hal; use hal;
use command::{BufCommand, Command, DataEntryMode, IncrementAxis};
use interface::DisplayInterface; use interface::DisplayInterface;
// Max display resolution is 160x296
const MAX_SOURCE_OUTPUTS: usize = 160;
const MAX_GATE_OUTPUTS: usize = 296;
// Magic numbers from the data sheet
const ANALOG_BLOCK_CONTROL_MAGIC: u8 = 0x54;
const DIGITAL_BLOCK_CONTROL_MAGIC: u8 = 0x3B;
struct Config {} struct Config {}
struct Dimensions { struct Dimensions {
rows: usize, rows: u16,
cols: usize, cols: u8,
} }
pub struct Display<I> where I: DisplayInterface { pub struct Display<I> where I: DisplayInterface {
@ -20,12 +29,62 @@ impl<I> Display<I> where I: DisplayInterface {
Self { interface, dimensions, rotation } Self { interface, dimensions, rotation }
} }
fn reset<D: hal::blocking::delay::DelayMs<u8>>(&mut self, delay: &mut D) { /// Perform a hardware reset followed by software reset
self.interface.reset(delay) fn reset<D: hal::blocking::delay::DelayMs<u8>>(&mut self, delay: &mut D) -> Result<(), I::Error> {
self.interface.reset(delay);
Command::SoftReset.execute(&mut self.interface)?;
self.interface.busy_wait();
Ok(())
} }
/// Initialise the controller according to Section 9: Typical Operating Sequence
/// from the data sheet
fn init(&mut self, config: Config) -> Result<(), I::Error> { fn init(&mut self, config: Config) -> Result<(), I::Error> {
Command::AnalogBlockControl(ANALOG_BLOCK_CONTROL_MAGIC).execute(&mut self.interface)?;
Command::DigitalBlockControl(DIGITAL_BLOCK_CONTROL_MAGIC).execute(&mut self.interface)?;
Command::DriverOutputControl(self.dimensions.rows, 0x00).execute(&mut self.interface)?;
Command::DummyLinePeriod(0x07).execute(&mut self.interface)?;
Command::GateLineWidth(0x04).execute(&mut self.interface)?;
Command::SourceDrivingVoltage(0x2D, 0xB2, 0x22).execute(&mut self.interface)?;
Command::WriteVCOM(0x3C).execute(&mut self.interface)?;
// POR is HiZ. Need pull from config
// Command::BorderWaveform(u8).execute(&mut self.interface)?;
// BufCommand::WriteLUT().execute(&mut self.interface)?;
Command::DataEntryMode(DataEntryMode::IncrementYIncrementX, IncrementAxis::Horizontal).execute(&mut self.interface)?;
let end = self.dimensions.cols / 8 - 1;
Command::StartEndXPosition(0, end).execute(&mut self.interface)?;
Command::StartEndYPosition(0, self.dimensions.rows).execute(&mut self.interface)?;
Ok(())
}
fn update<D: hal::blocking::delay::DelayMs<u8>>(&mut self, black: &[u8], red: &[u8], delay: &mut D) -> Result<(), I::Error> {
// Write the B/W RAM
Command::XAddress(0).execute(&mut self.interface)?;
Command::YAddress(0).execute(&mut self.interface)?;
BufCommand::WriteBlackData(&black).execute(&mut self.interface)?;
// Write the Red RAM
Command::XAddress(0).execute(&mut self.interface)?;
Command::YAddress(0).execute(&mut self.interface)?;
BufCommand::WriteRedData(&red).execute(&mut self.interface)?;
// Kick off the display update
Command::UpdateDisplayOption2(0xC7).execute(&mut self.interface)?;
Command::UpdateDisplay.execute(&mut self.interface)?;
delay.delay_ms(5); // Needed?
// TODO: We don't really need to wait here... the program can go off and do other things
// and only busy wait if it wants to talk to the display again. Could possibly treat
// the interface like a smart pointer in which "acquiring" it would wait until it's not
// busy.
self.interface.busy_wait();
Ok(()) Ok(())
} }
@ -35,5 +94,3 @@ impl<I> Display<I> where I: DisplayInterface {
unimplemented!() unimplemented!()
} }
} }

11
src/interface.rs
View file

@ -3,12 +3,15 @@ use hal;
// Section 15.2 of the HINK-E0213A07 data sheet says to hold for 10ms // Section 15.2 of the HINK-E0213A07 data sheet says to hold for 10ms
const RESET_DELAY_MS: u8 = 10; const RESET_DELAY_MS: u8 = 10;
const MAX_SPI_SPEED_HZ: u32 = 20_000_000;
pub trait DisplayInterface { pub trait DisplayInterface {
type Error; type Error;
fn send_command(&mut self, command: u8) -> Result<(), Self::Error>; fn send_command(&mut self, command: u8) -> Result<(), Self::Error>;
fn send_data(&mut self, data: &[u8]) -> Result<(), Self::Error>; fn send_data(&mut self, data: &[u8]) -> Result<(), Self::Error>;
fn reset<D: hal::blocking::delay::DelayMs<u8>>(&mut self, delay: &mut D); fn reset<D: hal::blocking::delay::DelayMs<u8>>(&mut self, delay: &mut D);
fn busy_wait(&self);
} }
pub struct Interface<SPI, CS, BUSY, DC, RESET> { pub struct Interface<SPI, CS, BUSY, DC, RESET> {
@ -62,10 +65,6 @@ where
Ok(()) Ok(())
} }
fn busy_wait(&self) {
while self.busy.is_high() {}
}
} }
impl<SPI, CS, BUSY, DC, RESET> DisplayInterface for Interface<SPI, CS, BUSY, DC, RESET> impl<SPI, CS, BUSY, DC, RESET> DisplayInterface for Interface<SPI, CS, BUSY, DC, RESET>
@ -97,4 +96,8 @@ where
self.dc.set_high(); self.dc.set_high();
self.write(data) self.write(data)
} }
fn busy_wait(&self) {
while self.busy.is_high() {}
}
} }