Mercurial > hp34970-firmware / file revision
lib/unigraphic/SPI8.cpp@f1c85c2500f2
lib/unigraphic/SPI8.cpp
Tue, 20 Sep 2016 23:50:45 +0200
- author
- David Douard <david.douard@logilab.fr>
- date
- Tue, 20 Sep 2016 23:50:45 +0200
- changeset 5
- f1c85c2500f2
- permissions
- -rw-r--r--
several improvements
- add (used parts of) unigraphics in repo
- extract hp communication protocol listener in a dedicated file
/* mbed UniGraphic library - SPI8 protocol class * Copyright (c) 2015 Giuliano Dianda * Released under the MIT License: http://mbed.org/license/mit * * Derived work of: * * mbed library for 240*320 pixel display TFT based on ILI9341 LCD Controller * Copyright (c) 2013 Peter Drescher - DC2PD * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "SPI8.h" SPI8::SPI8(int Hz, PinName mosi, PinName miso, PinName sclk, PinName CS, PinName reset, PinName DC) : _CS(CS), _spi(mosi, miso, sclk), _reset(reset), _DC(DC) { _reset = 1; _DC=1; _CS=1; _spi.format(8,0); // 8 bit spi mode 0 _spi.frequency(Hz); hw_reset(); } void SPI8::wr_cmd8(unsigned char cmd) { _DC.write(0); // 0=cmd _spi.write(cmd); // write 8bit _DC.write(1); // 1=data next } void SPI8::wr_data8(unsigned char data) { _spi.write(data); // write 8bit } void SPI8::wr_cmd16(unsigned short cmd) { _DC.write(0); // 0=cmd _spi.write(cmd>>8); // write 8bit _spi.write(cmd&0xFF); // write 8bit _DC.write(1); // 1=data next } void SPI8::wr_data16(unsigned short data) { _spi.write(data>>8); // write 8bit _spi.write(data&0xFF); // write 8bit } void SPI8::wr_gram(unsigned short data) { _spi.write(data>>8); // write 8bit _spi.write(data&0xFF); // write 8bit } void SPI8::wr_gram(unsigned short data, unsigned int count) { if((data>>8)==(data&0xFF)) { count<<=1; while(count) { _spi.write(data); // write 8bit count--; } } else { while(count) { _spi.write(data>>8); // write 8bit _spi.write(data&0xFF); // write 8bit count--; } } } void SPI8::wr_grambuf(unsigned short* data, unsigned int lenght) { while(lenght) { _spi.write((*data)>>8); // write 8bit _spi.write((*data)&0xFF); // write 8bit data++; lenght--; } } unsigned short SPI8::rd_gram(bool convert) { unsigned int r=0; _spi.write(0); // whole first byte is dummy r |= _spi.write(0); r <<= 8; r |= _spi.write(0); if(convert) { r <<= 8; r |= _spi.write(0); // gram is 18bit/pixel, if you set 16bit/pixel (cmd 3A), during writing the 16bits are expanded to 18bit // during reading, you read the raw 18bit gram r = RGB24to16((r&0xFF0000)>>16, (r&0xFF00)>>8, r&0xFF);// 18bit pixel padded to 24bits, rrrrrr00_gggggg00_bbbbbb00, converted to 16bit } _CS = 1; // force CS HIG to interupt the "read state" _CS = 0; return (unsigned short)r; } unsigned int SPI8::rd_reg_data32(unsigned char reg) { wr_cmd8(reg); unsigned int r=0; r |= _spi.write(0); // we get only 7bit valid, first bit was the dummy cycle r <<= 8; r |= _spi.write(0); r <<= 8; r |= _spi.write(0); r <<= 8; r |= _spi.write(0); r <<= 1; // 32bits are aligned, now collecting bit_0 r |= (_spi.write(0) >> 7); // we clocked 7 more bit so ILI waiting for 8th, we need to reset spi bus _CS = 1; // force CS HIG to interupt the cmd _CS = 0; return r; } unsigned int SPI8::rd_extcreg_data32(unsigned char reg, unsigned char SPIreadenablecmd) { unsigned int r=0; for(int regparam=1; regparam<4; regparam++) // when reading EXTC regs, first parameter is always dummy, so start with 1 { wr_cmd8(SPIreadenablecmd); // spi-in enable cmd, 0xD9 (ili9341) or 0xFB (ili9488) or don't know wr_data8(0xF0|regparam); // in low nibble specify which reg parameter we want wr_cmd8(reg); // now send cmd (select register we want to read) r <<= 8; r |= _spi.write(0); // r = _spi.write(0) >> 8; for 16bit } _CS = 1; // force CS HIG to interupt the cmd _CS = 0; return r; } // ILI932x specific void SPI8::dummyread() { _spi.write(0); // dummy read } // ILI932x specific void SPI8::reg_select(unsigned char reg, bool forread) { _CS = 1; //fixme: really needed? _CS = 0; //fixme: really needed? _spi.write(0x70); _spi.write(0); // write MSB _spi.write(reg); // write LSB _CS = 1; //fixme: really needed? _CS = 0; //fixme: really needed? if(forread) _spi.write(0x73); else _spi.write(0x72); } // ILI932x specific void SPI8::reg_write(unsigned char reg, unsigned short data) { _CS = 1; //fixme: really needed? _CS = 0; //fixme: really needed? _spi.write(0x70); _spi.write(0); // write MSB _spi.write(reg); // write LSB _CS = 1; //fixme: really needed? _CS = 0; //fixme: really needed? _spi.write(0x72); _spi.write(data>>8); _spi.write(data&0xFF); } // ILI932x specific unsigned short SPI8::reg_read(unsigned char reg) { unsigned short r=0; _CS = 1; //fixme: really needed? _CS = 0; //fixme: really needed? _spi.write(0x70); _spi.write(0); // write MSB _spi.write(reg); // write LSB _CS = 1; //fixme: really needed? _CS = 0; //fixme: really needed? _spi.write(0x73); _spi.write(0); // dummy read r = _spi.write(0); // read 8bit r <<= 8; r |= _spi.write(0); // read 8bit return r; } void SPI8::hw_reset() { wait_ms(15); _DC = 1; _CS = 1; _reset = 0; // display reset wait_ms(2); _reset = 1; // end reset wait_ms(100); } void SPI8::BusEnable(bool enable) { _CS = enable ? 0:1; }
