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//*****************************************************************************
//
// lcd.c - Defines and Macros for the LCD Controller module.
//
// Copyright (c) 2012-2017 Texas Instruments Incorporated. All rights reserved.
// Software License Agreement
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//
// Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in the
// documentation and/or other materials provided with the
// distribution.
//
// Neither the name of Texas Instruments Incorporated nor the names of
// its contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// This is part of revision 2.1.4.178 of the Tiva Peripheral Driver Library.
//
//*****************************************************************************
//*****************************************************************************
//
//! \addtogroup lcd_api
//! @{
//
//*****************************************************************************
#include <stdint.h>
#include <stdbool.h>
#include <stdint.h>
#include "inc/hw_memmap.h"
#include "inc/hw_types.h"
#include "inc/hw_ints.h"
#include "inc/hw_lcd.h"
#include "driverlib/interrupt.h"
#include "driverlib/sysctl.h"
#include "driverlib/lcd.h"
#include "driverlib/debug.h"
//*****************************************************************************
//
// These are currently missing from hw_lcd.h and included here as a stopgap
// until the hardware header is updated.
//
//*****************************************************************************
#ifndef LCD_RASTRTIM0_MSBPPL_S
#define LCD_RASTRTIM0_MSBPPL_S 3
#endif
#ifndef LCD_RASTRTIM2_MSBLPP_S
#define LCD_RASTRTIM2_MSBLPP_S 26
#endif
//*****************************************************************************
//
//! Configures the basic operating mode and clock rate for the LCD controller.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui8Mode specifies the basic operating mode to be used.
//! \param ui32PixClk specifies the desired LCD controller pixel or master
//! clock rate in Hz.
//! \param ui32SysClk specifies the current system clock rate in Hz.
//!
//! This function sets the basic operating mode of the LCD controller and also
//! its master clock. The \e ui8Mode parameter may be set to either \b
//! LCD_MODE_LIDD or \b LCD_MODE_RASTER. \b LCD_MODE_LIDD is used to select
//! LCD Interface Display Driver mode for character panels connected via
//! an asynchronous interface (CS, WE, OE, ALE, data) and \b LCD_MODE_RASTER
//! is used to communicate with panels via a synchronous video interface using
//! data and sync signals. Additionally, \b LCD_MODE_AUTO_UFLOW_RESTART may
//! be ORed with either of these modes to indicate that the hardware should
//! restart automatically if a data underflow occurs.
//!
//! The \e ui32PixClk parameter specifies the desired master clock for the
//! the LCD controller. In LIDD mode, this value controls the MCLK used in
//! communication with the display and valid values are between \e ui32SysClk
//! and \e ui32SysClk/255. In raster mode, \e ui32PixClk specifies the pixel
//! clock rate for the raster interface and valid values are between \e
//! ui32SysClk/2 and \e ui32SysClk/255. The actual clock rate set may differ
//! slightly from the desired rate due to the fact that only integer dividers
//! are supported. The rate set will, however, be no higher than the requested
//! value.
//!
//! The \e ui32SysClk parameter provides the current system clock rate and is
//! used to allow the LCD controller clock rate divisor to be correctly set
//! to give the desired \e ui32PixClk rate.
//!
//! \return Returns the actual LCD controller pixel clock or MCLK rate set.
//
//*****************************************************************************
uint32_t
LCDModeSet(uint32_t ui32Base, uint8_t ui8Mode, uint32_t ui32PixClk,
uint32_t ui32SysClk)
{
uint32_t ui32Div;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui8Mode & ~(LCD_MODE_RASTER | LCD_MODE_LIDD |
LCD_MODE_AUTO_UFLOW_RESTART)) == 0);
//
// Enable clocks to the LCD controller submodules.
//
HWREG(ui32Base + LCD_O_CLKEN) = (LCD_CLKEN_DMA | LCD_CLKEN_CORE |
LCD_CLKEN_LIDD);
//
// Determine the clock divider to use to get as close as possible to the
// desired pixel clock. Note that we set the division up so that we
// round the divisor up and ensure that the clock used is never faster
// than the requested rate.
//
ui32Div = (ui32SysClk + (ui32PixClk - 1)) / ui32PixClk;
//
// Check that the calculated value is valid.
//
ASSERT(ui32Div);
ASSERT(ui32Div < 256);
ASSERT(!((ui8Mode & LCD_MODE_RASTER) && (ui32Div < 2)));
//
// Write the LCDCTL register to set the mode.
//
HWREG(ui32Base + LCD_O_CTL) = (uint32_t)ui8Mode |
(ui32Div << LCD_CTL_CLKDIV_S);
//
// Return the selected clock rate. Finding ui32Div set to 0 should not
// happen unless someone passed pathological arguments and builds without
// the ASSERTS, but we guard against it just in case.
//
return(ui32Div ? (ui32SysClk / ui32Div) : ui32SysClk);
}
//*****************************************************************************
//
//! Resets one or more of the LCD controller clock domains.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32Clocks defines the subset of clock domains to be reset.
//!
//! This function allows sub-modules of the LCD controller to be reset under
//! software control. The \e ui32Clocks parameter is the logical OR of the
//! following clocks:
//!
//! - \b LCD_CLOCK_MAIN causes the entire LCD controller module to be reset.
//! - \b LCD_CLOCK_DMA causes the DMA controller submodule to be reset.
//! - \b LCD_CLOCK_LIDD causes the LIDD submodule to be reset.
//! - \b LCD_CLOCK_CORE causes the core module, including the raster logic to
//! be reset.
//!
//! In all cases, LCD controller register values are preserved across these
//! resets.
//!
//! \return None.
//
//*****************************************************************************
void
LCDClockReset(uint32_t ui32Base, uint32_t ui32Clocks)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32Clocks & ~(LCD_CLOCK_MAIN | LCD_CLOCK_LIDD | LCD_CLOCK_DMA |
LCD_CLOCK_CORE)));
//
// Reset the required LCD controller sub-module(s).
//
HWREG(LCD0_BASE + 0x70) = ui32Clocks;
//
// Wait a while.
//
SysCtlDelay(10);
//
// Remove software reset.
//
HWREG(LCD0_BASE + 0x70) = 0x00000000;
//
// Wait a while.
//
SysCtlDelay(10);
}
//*****************************************************************************
//
//! Sets the LCD controller communication parameters when in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32Config defines the display interface configuration.
//!
//! This function is used when the LCD controller is configured in LIDD
//! mode and specifies the configuration of the interface between the
//! controller and the display panel. The \e ui32Config parameter is
//! comprised of one of the following modes:
//!
//! - \b LIDD_CONFIG_SYNC_MPU68 selects Sync MPU68 mode. LCDCP = EN, LCDLP =
//! DIR, LCDFP = ALE, LCDAC = CS0, LCDMCLK = MCLK.
//! - \b LIDD_CONFIG_ASYNC_MPU68 selects Async MPU68 mode. LCDCP = EN, LCDLP =
//! DIR, LCDFP = ALE, LCDAC = CS0, LCDMCLK = CS1.
//! - \b LIDD_CONFIG_SYNC_MPU80 selects Sync MPU80 mode. LCDCP = RS, LCDLP =
//! WS, LCDFP = ALE, LCDAC = CS0, LCDMCLK = MCLK.
//! - \b LIDD_CONFIG_ASYNC_MPU80 selects Async MPU80 mode. LCDCP = RS, LCDLP =
//! WS, LCDFP = ALE, LCDAC = CS0, LCDMCLK = CS1.
//! - \b LIDD_CONFIG_ASYNC_HITACHI selects Hitachi (async) mode. LCDCP = N/C,
//! LCDLP = DIR, LCDFP = ALE, LCDAC = E0, LCDMCLK = E1.
//!
//! Additional flags may be ORed into \e ui32Config to control the polarities
//! of various control signals:
//!
//! - \b LIDD_CONFIG_INVERT_ALE - Address Latch Enable (ALE) polarity control.
//! By default, ALE is active low. If this flag is set, it becomes active
//! high.
//! - \b LIDD_CONFIG_INVERT_RS_EN - Read Strobe/Enable polarity control. By
//! default, RS is active low and Enable is active high. If this flag is set,
//! RS becomes active high and Enable active low.
//! - \b LIDD_CONFIG_INVERT_WS_DIR - Write Strobe/Direction polarity control.
//! By default, WS is active low and Direction write low/read high. If this
//! flag is set, WS becomes active high and Direction becomes write high/read
//! low.
//! - \b LIDD_CONFIG_INVERT_CS0 - Chip Select 0/Enable 0 polarity control. By
//! default, CS0 and E0 are active high. If this flag is set, they become
//! active low.
//! - \b LIDD_CONFIG_INVERT_CS1 - Chip Select 1/Enable 1 polarity control. By
//! default, CS1 and E1 are active high. If this flag is set, they become
//! active low.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIDDConfigSet(uint32_t ui32Base, uint32_t ui32Config)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32Config & ~(LIDD_CONFIG_SYNC_MPU68 | LIDD_CONFIG_ASYNC_MPU68 |
LIDD_CONFIG_SYNC_MPU80 | LIDD_CONFIG_ASYNC_MPU80 |
LIDD_CONFIG_ASYNC_HITACHI |
LIDD_CONFIG_INVERT_ALE |
LIDD_CONFIG_INVERT_RS_EN |
LIDD_CONFIG_INVERT_WS_DIR |
LIDD_CONFIG_INVERT_CS0 | LIDD_CONFIG_INVERT_CS1)));
//
// Write the LIDD Control Register.
//
HWREG(ui32Base + LCD_O_LIDDCTL) = ui32Config;
}
//*****************************************************************************
//
//! Sets the LCD controller interface timing when in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select whose timings are to be set.
//! \param pTiming points to a structure containing the desired timing
//! parameters.
//!
//! This function is used in LIDD mode to set the setup, strobe and hold times
//! for the various interface control signals. Independent timings are stored
//! for each of the two supported chip selects offered by the LCD controller.
//!
//! For a definition of the timing parameters required, see the definition of
//! tLCDIDDTiming.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return None
//
//*****************************************************************************
void
LCDIDDTimingSet(uint32_t ui32Base, uint32_t ui32CS,
const tLCDIDDTiming *pTiming)
{
uint32_t ui32Val;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
ASSERT(pTiming);
ASSERT(pTiming->ui8WSSetup < 32);
ASSERT(pTiming->ui8WSDuration && (pTiming->ui8WSDuration < 64));
ASSERT(pTiming->ui8WSHold && (pTiming->ui8WSHold < 16));
ASSERT(pTiming->ui8RSSetup < 32);
ASSERT(pTiming->ui8RSDuration && (pTiming->ui8RSDuration < 64));
ASSERT(pTiming->ui8RSHold && (pTiming->ui8RSHold < 16));
ASSERT(pTiming->ui8DelayCycles && (pTiming->ui8DelayCycles < 5));
//
// Convert the timings provided into a value ready for the register.
//
ui32Val =
(((uint32_t)(pTiming->ui8WSSetup) << LCD_LIDDCS0CFG_WRSU_S) |
((uint32_t)(pTiming->ui8WSDuration) << LCD_LIDDCS0CFG_WRDUR_S) |
((uint32_t)(pTiming->ui8WSHold) << LCD_LIDDCS0CFG_WRHOLD_S) |
((uint32_t)(pTiming->ui8RSSetup) << LCD_LIDDCS0CFG_RDSU_S) |
((uint32_t)(pTiming->ui8RSDuration) << LCD_LIDDCS0CFG_RDDUR_S) |
((uint32_t)(pTiming->ui8RSHold) << LCD_LIDDCS0CFG_RDHOLD_S) |
((uint32_t)(pTiming->ui8DelayCycles - 1) << LCD_LIDDCS0CFG_GAP_S));
//
// Write the appropriate LCD LIDD CS configuration register.
//
if(!ui32CS)
{
HWREG(ui32Base + LCD_O_LIDDCS0CFG) = ui32Val;
}
else
{
HWREG(ui32Base + LCD_O_LIDDCS1CFG) = ui32Val;
}
}
//*****************************************************************************
//
//! Disables internal DMA operation when the LCD controller is in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//!
//! When the LCD controller is operating in LCD Interface Display Driver mode,
//! this function must be called after completion of a DMA transaction and
//! before calling LCDIDDCommandWrite(), LCDIDDDataWrite(), LCDIDDStatusRead(),
//! LCDIDDIndexedWrite(), LCDIDDIndexedRead() or LCDIDDDataRead() to disable
//! DMA mode and allow CPU-initiated transactions to the display.
//!
//! \note LIDD DMA mode is enabled automatically when LCDIDDDMAWrite() is
//! called.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIDDDMADisable(uint32_t ui32Base)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Disable DMA.
//
HWREG(ui32Base + LCD_O_LIDDCTL) &= ~LCD_LIDDCTL_DMAEN;
}
//*****************************************************************************
//
//! Writes a command to the display when the LCD controller is in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//! \param ui16Cmd is the 16-bit command word to write.
//!
//! This function writes a 16-bit command word to the display when the LCD
//! controller is in LIDD mode. A command write occurs with the ALE signal
//! active.
//!
//! This function must not be called if the LIDD interface is currently
//! configured to expect DMA transactions. If DMA was previously used to
//! write to the panel, LCDIDDDMADisable() must be called before this function
//! can be used.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIDDCommandWrite(uint32_t ui32Base, uint32_t ui32CS, uint16_t ui16Cmd)
{
uint32_t ui32Reg;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
//
// Determine the register to write based on the CS value supplied.
//
ui32Reg = ui32CS ? LCD_O_LIDDCS1ADDR : LCD_O_LIDDCS0ADDR;
//
// Write the command/address to the register.
//
HWREG(ui32Base + ui32Reg) = ui16Cmd;
}
//*****************************************************************************
//
//! Writes a data value to the display when the LCD controller is in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//! \param ui16Data is the 16-bit data word to write.
//!
//! This function writes a 16-bit data word to the display when the LCD
//! controller is in LIDD mode. A data write occurs with the ALE signal
//! inactive.
//!
//! This function must not be called if the LIDD interface is currently
//! configured to expect DMA transactions. If DMA was previously used to
//! write to the panel, LCDIDDDMADisable() must be called before this function
//! can be used.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIDDDataWrite(uint32_t ui32Base, uint32_t ui32CS, uint16_t ui16Data)
{
uint32_t ui32Reg;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
//
// Determine the register to write based on the CS value supplied.
//
ui32Reg = ui32CS ? LCD_O_LIDDCS1DATA : LCD_O_LIDDCS0DATA;
//
// Write the data value to the register.
//
HWREG(ui32Base + ui32Reg) = ui16Data;
}
//*****************************************************************************
//
//! Writes data to a given display register when the LCD controller is in LIDD
//! mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//! \param ui16Addr is the address of the display register to write.
//! \param ui16Data is the data to write.
//!
//! This function writes a 16-bit data word to a register in the display when
//! the LCD controller is in LIDD mode and configured to use either the
//! Motorola (\b LIDD_CONFIG_SYNC_MPU68 or \b LIDD_CONFIG_ASYNC_MPU68) or
//! Intel (\b LIDD_CONFIG_SYNC_MPU80 or \b LIDD_CONFIG_ASYNC_MPU80) modes
//! that employ an external address latch.
//!
//! When configured in Hitachi mode (\b LIDD_CONFIG_ASYNC_HITACHI), this
//! function should not be used. In this case the functions
//! LCDIDDCommandWrite() and LCDIDDDataWrite() may be used to transfer
//! command and data bytes to the panel.
//!
//! This function must not be called if the LIDD interface is currently
//! configured to expect DMA transactions. If DMA was previously used to
//! write to the panel, LCDIDDDMADisable() must be called before this function
//! can be used.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIDDIndexedWrite(uint32_t ui32Base, uint32_t ui32CS, uint16_t ui16Addr,
uint16_t ui16Data)
{
uint32_t ui32Addr;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
//
// Determine the address register to write.
//
ui32Addr = ui32CS ? LCD_O_LIDDCS1ADDR : LCD_O_LIDDCS0ADDR;
//
// Write the address.
//
HWREG(ui32Base + ui32Addr) = ui16Addr;
//
// Determine the data register to write.
//
ui32Addr = ui32CS ? LCD_O_LIDDCS1DATA : LCD_O_LIDDCS0DATA;
//
// Write the data.
//
HWREG(ui32Base + ui32Addr) = ui16Data;
}
//*****************************************************************************
//
//! Reads a status word from the display when the LCD controller is in LIDD
//! mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//!
//! This function reads the 16-bit status word from the display when the LCD
//! controller is in LIDD mode. A status read occurs with the ALE signal
//! active. If the interface is configured in Hitachi mode (\b
//! LIDD_CONFIG_ASYNC_HITACHI), this operation corresponds to a command mode
//! read.
//!
//! This function must not be called if the LIDD interface is currently
//! configured to expect DMA transactions. If DMA was previously used to
//! write to the panel, LCDIDDDMADisable() must be called before this function
//! can be used.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return Returns the status word read from the display panel.
//
//*****************************************************************************
uint16_t
LCDIDDStatusRead(uint32_t ui32Base, uint32_t ui32CS)
{
uint32_t ui32Reg;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
//
// Determine the register to read based on the CS value supplied.
//
ui32Reg = ui32CS ? LCD_O_LIDDCS1ADDR : LCD_O_LIDDCS0ADDR;
//
// Read the relevant status register.
//
return((uint16_t)HWREG(ui32Base + ui32Reg));
}
//*****************************************************************************
//
//! Reads a data word from the display when the LCD controller is in LIDD
//! mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//!
//! This function reads the 16-bit data word from the display when the LCD
//! controller is in LIDD mode. A data read occurs with the ALE signal
//! inactive.
//!
//! This function must not be called if the LIDD interface is currently
//! configured to expect DMA transactions. If DMA was previously used to
//! write to the panel, LCDIDDDMADisable() must be called before this function
//! can be used.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return Returns the status word read from the display panel.
//
//*****************************************************************************
uint16_t
LCDIDDDataRead(uint32_t ui32Base, uint32_t ui32CS)
{
uint32_t ui32Reg;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
//
// Determine the register to read based on the CS value supplied.
//
ui32Reg = ui32CS ? LCD_O_LIDDCS1DATA : LCD_O_LIDDCS0DATA;
//
// Read the relevant data register.
//
return((uint16_t)HWREG(ui32Base + ui32Reg));
}
//*****************************************************************************
//
//! Reads a given display register when the LCD controller is in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//! \param ui16Addr is the address of the display register to read.
//!
//! This function reads a 16-bit word from a register in the display when
//! the LCD controller is in LIDD mode and configured to use either the
//! Motorola (\b LIDD_CONFIG_SYNC_MPU68 or \b LIDD_CONFIG_ASYNC_MPU68) or
//! Intel (\b LIDD_CONFIG_SYNC_MPU80 or \b LIDD_CONFIG_ASYNC_MPU80) modes
//! that employ an external address latch.
//!
//! When configured in Hitachi mode (\b LIDD_CONFIG_ASYNC_HITACHI), this
//! function should not be used. In this case, the functions
//! LCDIDDStatusRead() and LCDIDDDataRead() may be used to read status
//! and data bytes from the panel.
//!
//! This function must not be called if the LIDD interface is currently
//! configured to expect DMA transactions. If DMA was previously used to
//! write to the panel, LCDIDDDMADisable() must be called before this function
//! can be used.
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return None.
//
//*****************************************************************************
uint16_t
LCDIDDIndexedRead(uint32_t ui32Base, uint32_t ui32CS, uint16_t ui16Addr)
{
uint32_t ui32Addr;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
//
// Determine the address register to write.
//
ui32Addr = ui32CS ? LCD_O_LIDDCS1ADDR : LCD_O_LIDDCS0ADDR;
//
// Write the address.
//
HWREG(ui32Base + ui32Addr) = ui16Addr;
//
// Determine the data register to read.
//
ui32Addr = ui32CS ? LCD_O_LIDDCS1DATA : LCD_O_LIDDCS0DATA;
//
// Return the data read.
//
return((uint16_t)HWREG(ui32Base + ui32Addr));
}
//*****************************************************************************
//
//! Writes a block of data to the display using DMA when the LCD controller is
//! in LIDD mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32CS specifies the chip select to use. Valid values are 0 and 1.
//! \param pui32Data is the address of the first 16-bit word to write. This
//! address must be aligned on a 32-bit word boundary.
//! \param ui32Count is the number of 16-bit words to write. This value must
//! be a multiple of 2.
//!
//! This function writes a block of 16-bit data words to the display using
//! DMA. It is only valid when the LCD controller is in LIDD mode.
//! Completion of the DMA transfer is signaled by the \b
//! LCD_INT_DMA_DONE interrupt.
//!
//! This function enables DMA mode prior to starting the transfer. The
//! caller is responsible for ensuring that any earlier DMA transfer has
//! completed before initiating another transfer.
//!
//! During the time that DMA is enabled, none of the other LCD LIDD data
//! transfer functions may be called. When the DMA transfer is complete and
//! the application wishes to use the CPU to communicate with the display,
//! LCDIDDDMADisable() must be called to disable DMA access prior to calling
//! LCDIDDCommandWrite(), LCDIDDDataWrite(), LCDIDDStatusRead(),
//! LCDIDDIndexedWrite(), LCDIDDIndexedRead() or LCDIDDDataRead().
//!
//! \note CS1 is not available when operating in Sync MPU68 or Sync MPU80
//! modes.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIDDDMAWrite(uint32_t ui32Base, uint32_t ui32CS, const uint32_t *pui32Data,
uint32_t ui32Count)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32CS == 0) || (ui32CS == 1));
ASSERT(!((uint32_t)pui32Data & 3));
ASSERT(!(ui32Count & 1));
//
// Make sure DMA is disabled so that enabling it triggers this new
// transfer.
//
HWREG(ui32Base + LCD_O_LIDDCTL) &= ~LCD_LIDDCTL_DMAEN;
//
// Set up the transfer. Note that the ceiling register must contain the
// address of the last word which contains data we want transfered and NOT
// the first location after the data we want written.
//
HWREG(ui32Base + LCD_O_DMABAFB0) = (uint32_t)pui32Data;
HWREG(ui32Base + LCD_O_DMACAFB0) = ((uint32_t)pui32Data +
(ui32Count * 2) - 4);
//
// Tell the controller which CS to use for the DMA transaction.
//
if(!ui32CS)
{
//
// Use CS0.
//
HWREG(ui32Base + LCD_O_LIDDCTL) &= ~LCD_LIDDCTL_DMACS;
}
else
{
//
// Use CS1.
//
HWREG(ui32Base + LCD_O_LIDDCTL) |= LCD_LIDDCTL_DMACS;
}
//
// Enable the DMA engine and start the transaction.
//
HWREG(ui32Base + LCD_O_LIDDCTL) |= LCD_LIDDCTL_DMAEN;
}
//*****************************************************************************
//
//! Sets the LCD controller interface timing when in raster mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param ui32Config specifies properties of the raster interface and the
//! attached display panel.
//! \param ui8PalLoadDelay specifies the number of system clocks to wait
//! between each 16 halfword (16-bit) burst when loading the palette from
//! SRAM into the internal palette RAM of the controller.
//!
//! This function configures the basic operating mode of the raster interface
//! and specifies the type of panel that the controller is to drive.
//!
//! The \e ui32Config parameter must be defined as one of the following to
//! select the required target panel type and output pixel format:
//!
//! - \b RASTER_FMT_ACTIVE_24BPP_PACKED selects an active matrix display
//! and uses a packed 24-bit per pixel packet frame buffer where 4 pixels
//! are described within 3 consecutive 32-bit words.
//! - \b RASTER_FMT_ACTIVE_24BPP_UNPACKED selects an active matrix display
//! and uses an unpacked 24-bit per pixel packet frame buffer where each
//! 32-bit word contains a single pixel and 8 bits of padding.
//! - \b RASTER_FMT_ACTIVE_16BPP selects an active matrix display
//! and uses a 16-bit per pixel frame buffer with 2 pixels in each 32-bit
//! word.
//! - \b RASTER_FMT_ACTIVE_PALETTIZED_12BIT selects an active matrix display
//! and uses a 1, 2, 4 or 8bpp frame buffer with palette lookup. Output color
//! data is described in 12-bit format using bits 11:0 of the data bus. The
//! frame buffer pixel format is defined by the value passed in the \e ui32Type
//! parameter to LCDRasterPaletteSet().
//! - \b RASTER_FMT_ACTIVE_PALETTIZED_16BIT selects an active matrix display
//! and uses a 1, 2, 4 or 8bpp frame buffer with palette lookup. Output color
//! data is described in 16-bit 5:6:5 format. The frame buffer pixel format is
//! defined by the value passed in the \e ui32Type parameter to
//! LCDRasterPaletteSet().
//! - \b RASTER_FMT_PASSIVE_MONO_4PIX selects a monochrome, passive matrix
//! display that outputs 4 pixels on each pixel clock.
//! - \b RASTER_FMT_PASSIVE_MONO_8PIX selects a monochrome, passive matrix
//! display that outputs 8 pixels on each pixel clock.
//! - \b RASTER_FMT_PASSIVE_COLOR_12BIT selects a passive matrix display
//! and uses a 12bpp frame buffer. The palette is bypassed and 12-bit pixel
//! data is sent to the grayscaler for the display.
//! - \b RASTER_FMT_PASSIVE_COLOR_16BIT selects a passive matrix display
//! and uses a 16bpp frame buffer with pixels in 5:6:5 format. Only the 4
//! most significant bits of each color component are sent to the grayscaler
//! for the display.
//!
//! Additionally, the following flags may be ORed into \e ui32Config:
//!
//! - \b RASTER_ACTVID_DURING_BLANK sets Actvid to toggle during vertical
//! blanking.
//! - \b RASTER_NIBBLE_MODE_ENABLED enables nibble mode. This parameter works
//! with \b RASTER_READ_ORDER_REVERSED to determine how 1, 2 and 4bpp pixels
//! are extracted from words read from the frame buffer. If specified, words
//! read from the frame buffer are byte swapped prior to individual pixels
//! being parsed from them.
//! - \b RASTER_LOAD_DATA_ONLY tells the controller to read only pixel data
//! from the frame buffer and to use the last palette read. No palette load
//! is performed.
//! - \b RASTER_LOAD_PALETTE_ONLY tells the controller to read only the palette
//! data from the frame buffer.
//! - \b RASTER_READ_ORDER_REVERSED when using 1, 2, 4 and 8bpp frame buffers,
//! this option reverses the order in which frame buffer words are parsed.
//! When this option is specified, the leftmost pixel in a word is taken from
//! the most significant bits. When absent, the leftmost pixel is parsed from
//! the least significant bits.
//!
//! If the LCD controller's raster engine is enabled when this function is
//! called, it is disabled as a result of the call.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterConfigSet(uint32_t ui32Base, uint32_t ui32Config,
uint8_t ui8PalLoadDelay)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32Config & ~(RASTER_FMT_ACTIVE_24BPP_PACKED |
RASTER_FMT_ACTIVE_24BPP_UNPACKED |
RASTER_FMT_ACTIVE_PALETTIZED_12BIT |
RASTER_FMT_ACTIVE_PALETTIZED_16BIT |
RASTER_FMT_PASSIVE_MONO_4PIX |
RASTER_FMT_PASSIVE_MONO_8PIX |
RASTER_FMT_PASSIVE_PALETTIZED |
RASTER_FMT_PASSIVE_COLOR_12BIT |
RASTER_FMT_PASSIVE_COLOR_16BIT |
RASTER_ACTVID_DURING_BLANK |
RASTER_NIBBLE_MODE_ENABLED |
RASTER_LOAD_DATA_ONLY |
RASTER_LOAD_PALETTE_ONLY |
RASTER_READ_ORDER_REVERSED)));
//
// Write the raster control register.
//
HWREG(ui32Base + LCD_O_RASTRCTL) = (ui32Config |
((uint32_t)ui8PalLoadDelay <<
LCD_RASTRCTL_REQDLY_S));
}
//*****************************************************************************
//
//! Sets the LCD controller interface timing when in raster mode.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param pTiming points to a structure containing the desired timing
//! parameters.
//!
//! This function is used in raster mode to set the panel size and sync timing
//! parameters.
//!
//! For a definition of the timing parameters required, see the definition of
//! tLCDRasterTiming.
//!
//! \return None
//
//*****************************************************************************
void
LCDRasterTimingSet(uint32_t ui32Base, const tLCDRasterTiming *pTiming)
{
uint32_t ui32T0, ui32T1, ui32T2;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(pTiming);
ASSERT(!(pTiming->ui32Flags & ~(RASTER_TIMING_SYNCS_OPPOSITE_PIXCLK |
RASTER_TIMING_SYNCS_ON_FALLING_PIXCLK |
RASTER_TIMING_SYNCS_ON_RISING_PIXCLK |
RASTER_TIMING_ACTIVE_LOW_OE |
RASTER_TIMING_ACTIVE_LOW_PIXCLK |
RASTER_TIMING_ACTIVE_LOW_HSYNC |
RASTER_TIMING_ACTIVE_LOW_VSYNC)));
ASSERT(pTiming->ui16PanelWidth && (pTiming->ui16PanelWidth <= 2048) &&
((pTiming->ui16PanelWidth % 16) == 0));
ASSERT(pTiming->ui16PanelHeight && (pTiming->ui16PanelHeight <= 2048));
ASSERT(pTiming->ui16HFrontPorch && (pTiming->ui16HFrontPorch <= 1024));
ASSERT(pTiming->ui16HBackPorch && (pTiming->ui16HBackPorch <= 1024));
ASSERT(pTiming->ui16HSyncWidth && (pTiming->ui16HSyncWidth <= 1024));
ASSERT(pTiming->ui8VSyncWidth && (pTiming->ui8VSyncWidth <= 64));
//
// Construct the values we need for the three raster timing registers.
//
ui32T0 = ((uint32_t)((pTiming->ui16HBackPorch - 1) & 0xFF) <<
LCD_RASTRTIM0_HBP_S) |
((uint32_t)((pTiming->ui16HFrontPorch - 1) & 0xFF) <<
LCD_RASTRTIM0_HFP_S) |
((uint32_t)((pTiming->ui16HSyncWidth - 1) & 0x3F) <<
LCD_RASTRTIM0_HSW_S) |
(((uint32_t)((pTiming->ui16PanelWidth - 1) & 0x3F0) >> 4) <<
LCD_RASTRTIM0_PPL_S) |
(((uint32_t)((pTiming->ui16PanelWidth - 1) & 0x400) >> 10) <<
LCD_RASTRTIM0_MSBPPL_S);
ui32T1 = ((uint32_t)pTiming->ui8VBackPorch << LCD_RASTRTIM1_VBP_S) |
((uint32_t)pTiming->ui8VFrontPorch << LCD_RASTRTIM1_VFP_S) |
((uint32_t)((pTiming->ui8VSyncWidth - 1) & 0x3F) <<
LCD_RASTRTIM1_VSW_S) |
((uint32_t)(pTiming->ui16PanelHeight - 1) & 0x3FF) <<
LCD_RASTRTIM1_LPP_S;
ui32T2 = pTiming->ui32Flags |
((((pTiming->ui16HSyncWidth - 1) & 0x3C0) >> 6) <<
LCD_RASTRTIM2_HSW_S) |
((((pTiming->ui16PanelHeight - 1) & 0x400) >> 10) <<
LCD_RASTRTIM2_MSBLPP_S) |
((((pTiming->ui16HBackPorch - 1) & 0x300) >> 8) <<
LCD_RASTRTIM2_MSBHBP_S) |
((((pTiming->ui16HFrontPorch - 1) & 0x300) >> 8) <<
LCD_RASTRTIM2_MSBHFP_S) |
(pTiming->ui8ACBiasLineCount << LCD_RASTRTIM2_ACBF_S);
//
// Write the timing registers, taking care to preserve any existing value
// in the AC Bias interrupt field of RASTRTIM2.
//
HWREG(ui32Base + LCD_O_RASTRTIM0) = ui32T0;
HWREG(ui32Base + LCD_O_RASTRTIM1) = ui32T1;
HWREG(ui32Base + LCD_O_RASTRTIM2) = (HWREG(ui32Base + LCD_O_RASTRTIM2) &
LCD_RASTRTIM2_ACBI_M) | ui32T2;
}
//*****************************************************************************
//
//! Sets the number of AC bias pin transitions per interrupt.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui8Count is the number of AC bias pin transitions to count before
//! the AC bias count interrupt is asserted. Valid values are from 0 to 15.
//!
//! This function is used to set the number of AC bias transitions between
//! each AC bias count interrupt (\b LCD_INT_AC_BIAS_CNT). If \e ui8Count is
//! 0, no AC bias count interrupt is generated.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterACBiasIntCountSet(uint32_t ui32Base, uint8_t ui8Count)
{
uint32_t ui32Val;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(ui8Count < 16);
//
// Get the existing raster timing 2 register value and mask in the new
// AC Bias interrupt count.
//
ui32Val = HWREG(ui32Base + LCD_O_RASTRTIM2);
ui32Val &= ~LCD_RASTRTIM2_ACBI_M;
ui32Val |= ((ui8Count << LCD_RASTRTIM2_ACBI_S) & LCD_RASTRTIM2_ACBI_M);
//
// Write the new value back to the register.
//
HWREG(ui32Base + LCD_O_RASTRTIM2) = ui32Val;
}
//*****************************************************************************
//
//! Enables the raster output.
//!
//! \param ui32Base is the base address of the controller.
//!
//! This function enables the LCD controller raster output and starts
//! displaying the content of the current frame buffer on the attached panel.
//! Prior to enabling the raster output, LCDModeSet(), LCDRasterConfigSet(),
//! LCDDMAConfigSet(), LCDRasterTimingSet(), LCDRasterPaletteSet() and
//! LCDRasterFrameBufferSet() must have been called.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterEnable(uint32_t ui32Base)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Reset the module prior to starting the raster. This is required to
// ensure correct operation of the raster engine.
//
LCDClockReset(ui32Base, LCD_CLOCK_MAIN);
//
// Enable the raster engine.
//
HWREG(ui32Base + LCD_O_RASTRCTL) |= LCD_RASTRCTL_LCDEN;
}
//*****************************************************************************
//
//! Determines whether or not the raster output is currently enabled.
//!
//! \param ui32Base is the base address of the controller.
//!
//! This function may be used to query whether or not the raster output is
//! currently enabled.
//!
//! \return Returns \b true if the raster is enabled or \b false if it is
//! disabled.
//
//*****************************************************************************
bool
LCDRasterEnabled(uint32_t ui32Base)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Return the current raster engine status.
//
return((HWREG(ui32Base + LCD_O_RASTRCTL) & LCD_RASTRCTL_LCDEN) ?
true : false);
}
//*****************************************************************************
//
//! Disables the raster output.
//!
//! \param ui32Base is the base address of the controller.
//!
//! This function disables the LCD controller raster output and stops driving
//! the attached display.
//!
//! \note Once disabled, the raster engine continues to scan data until the
//! end of the current frame. If the display is to be re-enabled, wait until
//! after the final \b LCD_INT_RASTER_FRAME_DONE has been received, indicating
//! that the raster engine has stopped.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterDisable(uint32_t ui32Base)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Disable the raster engine.
//
HWREG(ui32Base + LCD_O_RASTRCTL) &= ~LCD_RASTRCTL_LCDEN;
}
//*****************************************************************************
//
//! Sets the position and size of the subpanel on the raster display.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui32Flags may be either \b LCD_SUBPANEL_AT_TOP to show frame buffer
//! image data in the top portion of the display and default color in the
//! bottom portion, or \b LCD_SUBPANEL_AT_BOTTOM to show image data at the
//! bottom of the display and default color at the top.
//! \param ui32BottomLines defines the number of lines comprising the bottom
//! portion of the display. If \b LCD_SUBPANEL_AT_TOP is set in \e ui32Flags,
//! these lines contain the default pixel color when the subpanel is
//! enabled, otherwise they contain image data.
//! \param ui32DefaultPixel is the 24-bit RGB color to show in the portion of
//! the display not configured to show image data.
//!
//! The LCD controller provides a feature that allows a portion of the display
//! to be filled with a default color rather than image data from the frame
//! buffer. This feature reduces SRAM bandwidth requirements because no data
//! is fetched for lines containing the default color. This feature is only
//! available when the LCD controller is in raster mode and configured to drive
//! an active matrix display.
//!
//! The subpanel area containing image data from the frame buffer may be
//! positioned either at the top or bottom of the display as controlled by
//! the value of \e ui32Flags. The height of the bottom portion of the display
//! is defined by \e ui32BottomLines.
//!
//! When a subpanel is configured, the application must also reconfigure the
//! frame buffer to ensure that it contains the correct number of lines for
//! the subpanel size in use. This configuration can be achieved by calling
//! LCDRasterFrameBufferSet() with the \e ui32NumBytes parameter set
//! appropriately to describe the required number of active video lines in
//! the subpanel area.
//!
//! The subpanel display mode is not enabled using this function. To enable
//! the subpanel once it has been configured, call LCDRasterSubPanelEnable().
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterSubPanelConfigSet(uint32_t ui32Base, uint32_t ui32Flags,
uint32_t ui32BottomLines, uint32_t ui32DefaultPixel)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT((ui32Flags == LCD_SUBPANEL_AT_TOP) ||
(ui32Flags == LCD_SUBPANEL_AT_BOTTOM));
ASSERT(ui32BottomLines && (ui32BottomLines <= 2048));
//
// Adjust the line count into the 0-2047 range.
//
ui32BottomLines--;
//
// Set the first subpanel configuration register, taking care to leave the
// subpanel enabled if it already was.
//
HWREG(ui32Base + LCD_O_RASTRSUBP1) = (HWREG(ui32Base + LCD_O_RASTRSUBP1) &
LCD_RASTRSUBP1_SPEN) | ui32Flags |
((ui32DefaultPixel & 0xFFFF) <<
LCD_RASTRSUBP1_DPDLSB_S) |
((ui32BottomLines <<
LCD_RASTRSUBP1_LPPT_S) &
LCD_RASTRSUBP1_LPPT_M);
//
// Set the second subpanel configuration register.
//
HWREG(ui32Base + LCD_O_RASTRSUBP2) =
((ui32DefaultPixel >> 16) & LCD_RASTRSUBP2_DPDMSB_M) |
(((ui32BottomLines >> LCD_RASTRSUBP1_LPPT_S) & 1) << 8);
}
//*****************************************************************************
//
//! Enables subpanel display mode.
//!
//! \param ui32Base is the base address of the controller.
//!
//! This function enables subpanel display mode and displays a default color
//! rather than image data in the number of lines and at the position specified
//! by a previous call to LCDRasterSubPanelConfigSet(). Prior to calling
//! LCDRasterSubPanelEnable(), the frame buffer should have been reconfigured
//! to match the desired subpanel size using a call to
//! LCDRasterFrameBufferSet().
//!
//! Subpanel display is only possible when the LCD controller is in raster
//! mode and is configured to drive an active matrix display.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterSubPanelEnable(uint32_t ui32Base)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Enable the subpanel.
//
HWREG(ui32Base + LCD_O_RASTRSUBP1) |= LCD_RASTRSUBP1_SPEN;
}
//*****************************************************************************
//
//! Disables subpanel display mode.
//!
//! \param ui32Base is the base address of the controller.
//!
//! This function disables subpanel display mode and reverts to showing the
//! entire frame buffer image on the display. After the subpanel is disabled,
//! the frame buffer size must be reconfigured to match the full dimensions of
//! the display area by calling LCDRasterFrameBufferSet() with an appropriate
//! value for the \e ui32NumBytes parameter.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterSubPanelDisable(uint32_t ui32Base)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Disable the subpanel.
//
HWREG(ui32Base + LCD_O_RASTRSUBP1) &= ~LCD_RASTRSUBP1_SPEN;
}
//*****************************************************************************
//
//! Configures the LCD controller's internal DMA engine.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui32Config provides flags defining the desired DMA parameters.
//!
//! This function is used to configure the DMA engine within the LCD
//! controller. This engine is responsible for performing bulk data transfers
//! to the display when in LIDD mode or for transferring palette and pixel data
//! from SRAM to the display panel when in raster mode.
//!
//! The \e ui32Config parameter is a logical OR of various flags. It must
//! contain one value from each of the following groups.
//!
//! The first group of flags set the number of words that have to be in the
//! FIFO before it signals that it is ready:
//!
//! - \b LCD_DMA_FIFORDY_8_WORDS
//! - \b LCD_DMA_FIFORDY_16_WORDS
//! - \b LCD_DMA_FIFORDY_32_WORDS
//! - \b LCD_DMA_FIFORDY_64_WORDS
//! - \b LCD_DMA_FIFORDY_128_WORDS
//! - \b LCD_DMA_FIFORDY_256_WORDS
//! - \b LCD_DMA_FIFORDY_512_WORDS
//!
//! The second group of flags set the number of 32-bit words in each DMA burst
//! transfer:
//!
//! - \b LCD_DMA_BURST_1
//! - \b LCD_DMA_BURST_2
//! - \b LCD_DMA_BURST_4
//! - \b LCD_DMA_BURST_8
//! - \b LCD_DMA_BURST_16
//!
//! The final group of flags set internal byte lane controls and allow byte
//! swapping within the DMA engine. The label represents the output byte order
//! for an input 32-bit word ordered ``0123''.
//!
//! - \b LCD_DMA_BYTE_ORDER_0123
//! - \b LCD_DMA_BYTE_ORDER_1023
//! - \b LCD_DMA_BYTE_ORDER_3210
//! - \b LCD_DMA_BYTE_ORDER_2301
//!
//! Additionally, \b LCD_DMA_PING_PONG may be specified. This flag configures
//! the controller to operate in double-buffered mode. When data is scanned
//! out from the first frame buffer, the DMA engine immediately moves to
//! the second frame buffer and scans from there before moving back to the
//! first. If this flag is clear, the DMA engine uses a single frame buffer,
//! restarting the scan from the beginning of the buffer each time it completes
//! a frame.
//!
//! \note DMA burst size \b LCD_DMA_BURST_16 should be set when using frame
//! buffers in external, EPI-connected memory. Using a smaller burst size in
//! this case is likely to result in occasional FIFO underflows and associated
//! display glitches.
//!
//! \return None.
//
//*****************************************************************************
void
LCDDMAConfigSet(uint32_t ui32Base, uint32_t ui32Config)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32Config & ~(LCD_DMACTL_FIFORDY_M | LCD_DMACTL_BURSTSZ_M |
LCD_DMACTL_BYTESWAP | LCD_DMACTL_BIGDEND |
LCD_DMACTL_FMODE)));
//
// Write the DMA control register.
//
HWREG(ui32Base + LCD_O_DMACTL) = ui32Config;
}
//*****************************************************************************
//
//! Initializes the color palette in a frame buffer.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui32Type specifies the type of pixel data to be held in the frame
//! buffer and also the format of the source color values passed.
//! \param pui32Addr points to the start of the frame buffer into which the
//! palette information is to be written.
//! \param pui32SrcColors points to the first color value that is to be
//! written into the frame buffer palette.
//! \param ui32Start specifies the index of the first color in the palette
//! to update.
//! \param ui32Count specifies the number of source colors to be copied into
//! the frame buffer palette.
//!
//! This function is used to initialize the color palette stored at the
//! beginning of a frame buffer. It writes the relevant pixel type into the
//! first entry of the frame buffer and copies the requested number of colors
//! from a source buffer into the palette starting at the required index,
//! optionally converting them from 24-bit color format into the 12-bit format
//! used by the LCD controller.
//!
//! \e ui32Type must be set to one of the following values to indicate the
//! type of frame buffer for which the palette is being initialized:
//!
//! - \b LCD_PALETTE_TYPE_1BPP indicates a 1 bit per pixel
//! (monochrome) frame buffer. This format requires a 2 entry palette.
//! - \b LCD_PALETTE_TYPE_2BPP indicates a 2 bit per pixel frame
//! buffer. This format requires a 4 entry palette.
//! - \b LCD_PALETTE_TYPE_4BPP indicates a 4 bit per pixel frame
//! buffer. This format requires a 4 entry palette.
//! - \b LCD_PALETTE_TYPE_8BPP indicates an 8 bit per pixel frame
//! buffer. This format requires a 256 entry palette.
//! - \b LCD_PALETTE_TYPE_DIRECT indicates a direct color (12, 16 or
//! 24 bit per pixel). The color palette is not used in these modes, but the
//! frame buffer type must still be initialized to ensure that the hardware
//! uses the correct pixel type. When this value is used, the format of the
//! pixels in the frame buffer is defined by the \e ui32Config parameter
//! previously passed to LCDRasterConfigSet().
//!
//! Optionally, the \b LCD_PALETTE_SRC_24BIT flag may be ORed into \e ui32Type
//! to indicate that the supplied colors in the \e pui32SrcColors array are in
//! the 24-bit format as used by the TivaWare Graphics Library with one color
//! stored in each 32-bit word. In this case, the colors read from the source
//! array are converted to the 12-bit format used by the LCD controller before
//! being written into the frame buffer palette.
//!
//! If \b LCD_PALETTE_SRC_24BIT is not present, it is assumed that the
//! \e pui32SrcColors array contains 12-bit colors in the format required by
//! the LCD controller with 2 colors stored in each 32-bit word. In this case,
//! the values are copied directly into the frame buffer palette without any
//! reformatting.
//!
//! \return None.
//
//*****************************************************************************
void
LCDRasterPaletteSet(uint32_t ui32Base, uint32_t ui32Type, uint32_t *pui32Addr,
const uint32_t *pui32SrcColors, uint32_t ui32Start,
uint32_t ui32Count)
{
uint16_t *pui16Pal;
uint16_t *pui16Src;
uint32_t ui32Loop;
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(ui32Start < 256);
ASSERT((ui32Start + ui32Count) <= 256);
ASSERT(pui32Addr);
ASSERT((pui32SrcColors) || (ui32Count == 0));
ASSERT(!(ui32Type & ~(LCD_PALETTE_SRC_24BIT | LCD_PALETTE_TYPE_DIRECT |
LCD_PALETTE_TYPE_8BPP | LCD_PALETTE_TYPE_4BPP |
LCD_PALETTE_TYPE_2BPP | LCD_PALETTE_TYPE_1BPP)));
//
// Get a pointer to the start of the palette.
//
pui16Pal = (uint16_t *)pui32Addr;
//
// Are we converting the palette color format?
//
if(ui32Type & LCD_PALETTE_SRC_24BIT)
{
//
// Yes - loop through each of the supplied 24-bit colors converting
// and storing each.
//
ui32Loop = 0;
while(ui32Count)
{
pui16Pal[ui32Start + ui32Loop] =
PAL_FROM_RGB(pui32SrcColors[ui32Loop]);
ui32Loop++;
ui32Count--;
}
}
else
{
//
// No - loop through the supplied 12-bit colors storing each.
//
pui16Src = (uint16_t *)pui32SrcColors;
while(ui32Count)
{
pui16Pal[ui32Start] = pui16Src[ui32Start];
ui32Start++;
ui32Count--;
}
}
//
// Write the pixel type into the first palette entry.
//
pui16Pal[0] &= ~(LCD_PALETTE_TYPE_8BPP | LCD_PALETTE_TYPE_DIRECT);
pui16Pal[0] |= (ui32Type & ~LCD_PALETTE_SRC_24BIT);
}
//*****************************************************************************
//
//! Sets the LCD controller frame buffer start address and size in raster mode.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui8Buffer specifies which frame buffer to configure. Valid values
//! are 0 and 1.
//! \param pui32Addr points to the first byte of the frame buffer. This
//! pointer must be aligned on a 32-bit (word) boundary.
//! \param ui32NumBytes specifies the size of the frame buffer in bytes. This
//! value must be a multiple of 4.
//!
//! This function is used to configure the position and size of one of the
//! two supported frame buffers while in raster mode. The second frame buffer
//! (configured when ui8Buffer is set to 1) is only used if the controller
//! is set to operate in ping-pong mode (by specifying the \b LCD_DMA_PING_PONG
//! configuration flag on a call to LCDDMAConfigSet()).
//!
//! The format of the frame buffer depends on the image type in use and
//! the current raster configuration settings. If \b RASTER_LOAD_DATA_ONLY
//! was specified in a previous call to LCDRasterConfigSet(), the frame buffer
//! contains only packed pixel data in the required bit depth and format.
//! In other cases, the frame buffer comprises a palette of either 8 or 128
//! 32-bit words followed by the packed pixel data. The palette size is 8
//! words (16 16-bit entries) for all pixel formats other than 8bpp which
//! uses a palette of 128 words (256 16-bit entries). Note that the 8 word
//! palette is still present even for 12, 16 and 24-bit formats, which do not
//! use the lookup table.
//!
//! The frame buffer size, specified using the \e ui32NumBytes parameter, must
//! be the palette size (if any) plus the size of the image bitmap required
//! for the currently configured display resolution.
//!
//! \e ui32NumBytes = (Palette Size) + ((Width * Height) * BPP) / 8)
//!
//! If \b RASTER_LOAD_DATA_ONLY is not specified, frame buffers passed to this
//! function must be initialized using a call to LCDRasterPaletteSet() prior to
//! enabling the raster output. If this is not done, the pixel format
//! identifier and color table required by the hardware is not present
//! and the results are unpredictable.
//!
//! \return None.
//*****************************************************************************
void
LCDRasterFrameBufferSet(uint32_t ui32Base, uint8_t ui8Buffer,
uint32_t *pui32Addr, uint32_t ui32NumBytes)
{
//
// Sanity check parameters.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!((uint32_t)pui32Addr & 3));
ASSERT(!(ui32NumBytes & 3));
ASSERT(ui8Buffer < 2);
//
// Are we setting the values for frame buffer 0?
//
if(!ui8Buffer)
{
//
// Yes - set the registers for frame buffer 0.
//
HWREG(ui32Base + LCD_O_DMABAFB0) = (uint32_t)pui32Addr;
HWREG(ui32Base + LCD_O_DMACAFB0) = (uint32_t)pui32Addr +
ui32NumBytes - 4;
}
else
{
//
// No - set the registers for frame buffer 1.
//
HWREG(ui32Base + LCD_O_DMABAFB1) = (uint32_t)pui32Addr;
HWREG(ui32Base + LCD_O_DMACAFB1) = (uint32_t)pui32Addr +
ui32NumBytes - 4;
}
}
//*****************************************************************************
//
//! Enables individual LCD controller interrupt sources.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui32IntFlags is the bit mask of the interrupt sources to be enabled.
//!
//! This function enables the indicated LCD controller interrupt sources.
//! Only the sources that are enabled can be reflected to the processor
//! interrupt; disabled sources have no effect on the processor.
//!
//! The \e ui32IntFlags parameter is the logical OR of any of the following:
//!
//! - \b LCD_INT_DMA_DONE - indicates that a LIDD DMA transfer is complete.
//! - \b LCD_INT_RASTER_FRAME_DONE - indicates that a raster-mode frame is
//! complete.
//! - \b LCD_INT_SYNC_LOST - indicates that frame synchronization was lost.
//! - \b LCD_INT_AC_BIAS_CNT - indicates that that AC bias transition counter
//! has decremented to zero and is is valid for passive matrix panels only.
//! The counter, set by a call to LCDRasterACBiasIntCountSet(), is reloaded
//! but remains disabled until this interrupt is cleared.
//! - \b LCD_INT_UNDERFLOW - indicates that a data underflow occurred. The
//! internal FIFO was empty when the output logic attempted to read data to
//! send to the display.
//! - \b LCD_INT_PAL_LOAD - indicates that the color palette has been loaded.
//! - \b LCD_INT_EOF0 - indicates that the raw End-of-Frame 0 has been
//! signaled.
//! - \b LCD_INT_EOF2 - indicates that the raw End-of-Frame 1 has been
//! signaled.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIntEnable(uint32_t ui32Base, uint32_t ui32IntFlags)
{
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32IntFlags & ~(LCD_INT_DMA_DONE | LCD_INT_SYNC_LOST |
LCD_INT_AC_BIAS_CNT | LCD_INT_UNDERFLOW |
LCD_INT_PAL_LOAD | LCD_INT_EOF0 | LCD_INT_EOF1 |
LCD_INT_RASTER_FRAME_DONE)));
//
// Enable the interrupt sources by setting the appropriate bits in the
// mask register.
//
HWREG(ui32Base + LCD_O_IM) = ui32IntFlags;
}
//*****************************************************************************
//
//! Disables individual LCD controller interrupt sources.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui32IntFlags is the bit mask of the interrupt sources to be
//! disabled.
//!
//! This function disables the indicated LCD controller interrupt sources.
//! Only the sources that are enabled can be reflected to the processor
//! interrupt; disabled sources have no effect on the processor.
//!
//! The \e ui32IntFlags parameter is the logical OR of any of the following:
//!
//! - \b LCD_INT_DMA_DONE - indicates that a LIDD DMA transfer is complete.
//! - \b LCD_INT_RASTER_FRAME_DONE - indicates that a raster-mode frame is
//! complete.
//! - \b LCD_INT_SYNC_LOST - indicates that frame synchronization was lost.
//! - \b LCD_INT_AC_BIAS_CNT - indicates that that AC bias transition counter
//! has decremented to zero and is is valid for passive matrix panels only.
//! The counter, set by a call to LCDRasterACBiasIntCountSet(), is reloaded
//! but remains disabled until this interrupt is cleared.
//! - \b LCD_INT_UNDERFLOW - indicates that a data underflow occurred. The
//! internal FIFO was empty when the output logic attempted to read data to
//! send to the display.
//! - \b LCD_INT_PAL_LOAD - indicates that the color palette has been loaded.
//! - \b LCD_INT_EOF0 - indicates that the raw End-of-Frame 0 has been
//! signaled.
//! - \b LCD_INT_EOF2 - indicates that the raw End-of-Frame 1 has been
//! signaled.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIntDisable(uint32_t ui32Base, uint32_t ui32IntFlags)
{
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32IntFlags & ~(LCD_INT_DMA_DONE | LCD_INT_SYNC_LOST |
LCD_INT_AC_BIAS_CNT | LCD_INT_UNDERFLOW |
LCD_INT_PAL_LOAD | LCD_INT_EOF0 | LCD_INT_EOF1 |
LCD_INT_RASTER_FRAME_DONE)));
//
// Disable the interrupt sources by clearing the appropriate bits in the
// mask register.
//
HWREG(ui32Base + LCD_O_IENC) = ui32IntFlags;
}
//*****************************************************************************
//
//! Gets the current LCD controller interrupt status.
//!
//! \param ui32Base is the base address of the controller.
//! \param bMasked is false if the raw interrupt status is required and true
//! if the masked interrupt status is required.
//!
//! This function returns the interrupt status for the LCD controller.
//! Either the raw interrupt status or the status of interrupts that are
//! allowed to reflect to the processor can be returned.
//!
//! \return Returns the current interrupt status as the logical OR of any of
//! the following:
//!
//! - \b LCD_INT_DMA_DONE - indicates that a LIDD DMA transfer is complete.
//! - \b LCD_INT_RASTER_FRAME_DONE - indicates that a raster-mode frame is
//! complete.
//! - \b LCD_INT_SYNC_LOST - indicates that frame synchronization was lost.
//! - \b LCD_INT_AC_BIAS_CNT - indicates that that AC bias transition counter
//! has decremented to zero and is is valid for passive matrix panels only.
//! The counter, set by a call to LCDRasterACBiasIntCountSet(), is reloaded
//! but remains disabled until this interrupt is cleared.
//! - \b LCD_INT_UNDERFLOW - indicates that a data underflow occurred. The
//! internal FIFO was empty when the output logic attempted to read data to
//! send to the display.
//! - \b LCD_INT_PAL_LOAD - indicates that the color palette has been loaded.
//! - \b LCD_INT_EOF0 - indicates that the raw End-of-Frame 0 has been
//! signaled.
//! - \b LCD_INT_EOF2 - indicates that the raw End-of-Frame 1 has been
//! signaled.
//
//*****************************************************************************
uint32_t
LCDIntStatus(uint32_t ui32Base, bool bMasked)
{
ASSERT(ui32Base == LCD0_BASE);
//
// Were we asked for the masked or raw interrupt status?
//
if(bMasked)
{
//
// Return the masked interrupt status.
//
return(HWREG(ui32Base + LCD_O_MISCLR));
}
else
{
//
// Return the raw interrupts status.
//
return(HWREG(ui32Base + LCD_O_RISSET));
}
}
//*****************************************************************************
//
//! Clears LCD controller interrupt sources.
//!
//! \param ui32Base is the base address of the controller.
//! \param ui32IntFlags is a bit mask of the interrupt sources to be cleared.
//!
//! The specified LCD controller interrupt sources are cleared so that they no
//! longer assert. This function must be called in the interrupt handler to
//! keep the interrupt from being triggered again immediately upon exit.
//!
//! The \e ui32IntFlags parameter is the logical OR of any of the following:
//!
//! - \b LCD_INT_DMA_DONE - indicates that a LIDD DMA transfer is complete.
//! - \b LCD_INT_RASTER_FRAME_DONE - indicates that a raster-mode frame is
//! complete.
//! - \b LCD_INT_SYNC_LOST - indicates that frame synchronization was lost.
//! - \b LCD_INT_AC_BIAS_CNT - indicates that that AC bias transition counter
//! has decremented to zero and is is valid for passive matrix panels only.
//! The counter, set by a call to LCDRasterACBiasIntCountSet(), is reloaded
//! but remains disabled until this interrupt is cleared.
//! - \b LCD_INT_UNDERFLOW - indicates that a data underflow occurred. The
//! internal FIFO was empty when the output logic attempted to read data to
//! send to the display.
//! - \b LCD_INT_PAL_LOAD - indicates that the color palette has been loaded.
//! - \b LCD_INT_EOF0 - indicates that the raw End-of-Frame 0 has been
//! signaled.
//! - \b LCD_INT_EOF2 - indicates that the raw End-of-Frame 1 has been
//! signaled.
//!
//! \note Because there is a write buffer in the Cortex-M processor, it may
//! take several clock cycles before the interrupt source is actually cleared.
//! Therefore, it is recommended that the interrupt source be cleared early in
//! the interrupt handler (as opposed to the very last action) to avoid
//! returning from the interrupt handler before the interrupt source is
//! actually cleared. Failure to do so may result in the interrupt handler
//! being immediately reentered (because the interrupt controller still sees
//! the interrupt source asserted).
//!
//! \return None.
//
//*****************************************************************************
void
LCDIntClear(uint32_t ui32Base, uint32_t ui32IntFlags)
{
ASSERT(ui32Base == LCD0_BASE);
ASSERT(!(ui32IntFlags & ~(LCD_INT_DMA_DONE | LCD_INT_SYNC_LOST |
LCD_INT_AC_BIAS_CNT | LCD_INT_UNDERFLOW |
LCD_INT_PAL_LOAD | LCD_INT_EOF0 | LCD_INT_EOF1 |
LCD_INT_RASTER_FRAME_DONE)));
//
// Clear the requested interrupts.
//
HWREG(ui32Base + LCD_O_MISCLR) = ui32IntFlags;
}
//*****************************************************************************
//
//! Registers an interrupt handler for the LCD controller module.
//!
//! \param ui32Base specifies the LCD controller module base address.
//! \param pfnHandler is a pointer to the function to be called when the LCD
//! controller interrupt occurs.
//!
//! This function registers the handler to be called when the LCD controller
//! module interrupt occurs.
//!
//! \note This function need not be called if the appropriate interrupt vector
//! is statically linked into the vector table in the application startup code.
//!
//! \sa IntRegister() for important information about registering interrupt
//! handlers.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIntRegister(uint32_t ui32Base, void (*pfnHandler)(void))
{
//
// Check the arguments.
//
ASSERT(ui32Base == LCD0_BASE);
ASSERT(pfnHandler);
//
// Register the interrupt handler.
//
IntRegister(INT_LCD0_TM4C129, pfnHandler);
//
// Enable the interrupt in the interrupt controller.
//
IntEnable(INT_LCD0_TM4C129);
}
//*****************************************************************************
//
//! Unregisters the interrupt handler for the LCD controller module.
//!
//! \param ui32Base specifies the LCD controller module base address.
//!
//! This function unregisters the interrupt handler and disables the global LCD
//! controller interrupt in the interrupt controller.
//!
//! \note This function need not be called if the appropriate interrupt vector
//! is statically linked into the vector table in the application startup code.
//!
//! \sa IntRegister() for important information about registering interrupt
//! handlers.
//!
//! \return None.
//
//*****************************************************************************
void
LCDIntUnregister(uint32_t ui32Base)
{
//
// Check the arguments.
//
ASSERT(ui32Base == LCD0_BASE);
//
// Disable the interrupt in the interrupt controller.
//
IntDisable(INT_LCD0_TM4C129);
//
// Unregister the interrupt handler.
//
IntUnregister(INT_LCD0_TM4C129);
}
//*****************************************************************************
//
// Close the Doxygen group.
//! @}
//
//*****************************************************************************
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