Jake B. / Mbed 2 deprecated MakerBotServer

A web server for monitoring and controlling a MakerBot Replicator over the USB host and ethernet.

Dependencies:   IAP NTPClient RTC mbed-rtos mbed Socket lwip-sys lwip BurstSPI

Fork of LPC1768_Mini-DK by Frank Vannieuwkerke

Makerbot Server for LPC1768 Copyright (c) 2013, jake (at) allaboutjake (dot) com All rights reserved.

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.
  • The name of the author and/or copyright holder 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 HOLDER, AUTHOR, OR ANY 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.

Warnings:

This is not a commercial product or a hardened and secure network appliance. It is intended as a thought experiment or proof of concept and should not be relied upon in any way. Always operate your 3D printer in a safe and controlled manner.

Do not connect this directly to the exposed internet. It is intended to be behind a secure firewall (and NAT) such that it will only accept commands from the local network. Imagine how much fun a hacker could have instructing your 3D printer to continually print Standford bunnies. Well it could be much worse then that- a malicious user could send commands that could crash your machine (both in the software sense, as well as in the "smash your moving parts against the side of the machine repeatedly sense), overheat your extruders, cause your build plate to catch fire, and do severe damage to the machine, any surrounding building and propery. You have been warned.

Never print unattended and be ready to step in and stop the machine if something goes wrong. Keep in mind, a 3D printer has heaters that are operating at high temperatures, and if something starts to burn, it could cause damage to the machine, other property, and/or hurt yourself, pets, or others.

You should understand what you are doing. The source code here is not intended as a finished product or set of step by step instructions. You should engineer your own solution, which may wind up being better than mine.

Proceed at your own risk. You've been warned. (Several times) If you break your Makerbot, burn your house down, or injure yourself or others, I take no responsibility.

Introduction

I've been working on a side project to solve the "last mile" problem for people wanting to print from the network on their bots. I feel like the first half of the problem is solved with the FlashAir- getting the files to the card. The next step is a lightweight way of sending the "play back capture" command to the bot.

I looked around for a microcontroller platform that supports both networking and can function as a USB host. I happened to have an mbed (mbed) on hand that fit the bill. The mbed also has a working online toolchain (you need to own an mbed to gain access to the compiler). Some people don't like the online development environment, but I'm a fan of "working" and "Mac compatible." It was a good start, but cost wise, you would need an mbed LPC1768 module and some sort of carrier board that has both USB host and ethernet, or rig up your own connector solution. I happened to also have a Seedstudio mbed shield carrier board. This provides ethernet and USB connectors, but is another $25, putting the solution at around $75.

I also had an LPC1768 development board here called the "Mini-DK2". It has a USB host and a wired ethernet connector on board (search ebay if you're interested). It's a single-board solution that costs only $32 (and for $40 you can get one with a touchscreen) Its the cheapest development board I've seen with both USB host and an ethernet connector. I considered RasPi, but I'm not on that bandwagon. Since I had the Mini-DK2 on hand from another project that never went anywhere, I moved from the mbed module and carrier board to the DK2.

The mbed environment can compile binaries that work on the DK2 (again, you need to own at least one 1768 mbed already to get a license to use the compiler), and the mbed libraries provide some nice features. A USB Host library and and Ethernet library were readily available. The USBHost library didn't quite work out of the box. It took some time and more learning about the USB protocols than I would have liked, but I have the board communicating over the USB Host and the Makerbot.

Changes to stock mbed libraries

Many libraries are imported, but then converted to folders as to unlink them.

mbed provides a USHost library that includes a USBHostSerial object for connecting to CDC serial devices. Unfortunately, it did not work for me out of the box. I spent some time learning about USB protocols. One good reference is [Jan Axelson's Lakeview Research](http://www.lvr.com/usb_virtual_com_port.htm) discussion about CDC.

I found that the stock library was sending the control transfers to Interface 1. From what I understand, the control transfers needed to go to interface 0. I modified the USBHostSerial library to correct this, and the serial port interface came to life.

Next, I found that I wasn't able to get reliable communication. I traced it to what I think is an odd C++ inheritance and override problem. The USBHostSerial class implements the Stream interface, allowing printf/scanf operations. This is done by overriding the virtual _getc and _putc methods. Unfortunately, and for a reason I can't understand, these methods were not being called consistently. Sometimes they would work, but other times they would not. My solution was to implement transmit/receive methods with different names, and since the names were different, they seemed to get called consistently. I'd like to learn exactly what's going on here, but I don't feel like debugging it for academic purposes when it works just fine with the added methods.

Usage

Connect up your chosen dev board to power, ethernet and the USB host to the Makerbot's USB cable. The Mini-DK uses a USB-OTG adapter for the USB host. If you're using a Mini-DK board with an LCD, it will inform you of it's IP address on the display. This means it is now listening for a connection on port 7654.

If you are using an mbed dev board, or a Mini-DK without a display, the message will be directed to the serial console. Connect your computer to the appropriate port at a baud rate of 115200 to see the messages.

Use a telnet client to connect to the given IP address at port 7654. Telnet clients typically revert to "line mode" on ports other than 21. This means you get a local echo and the command isn't sent until you press enter.

Once connected, you can send the following commands:

A <username>:<password> : Set a username & password for the web interface and the telnet interface. Use the format shown with a colon separating the username from the password.

V : Print the version and Makerbot name, as well as the local firmware version (the Makerbot_Server firmware as discussed here).

B <filename.x3g> : Build from SD the given filename. According tot he protocol spec, this command is limited to 12 characters, so 8.3 filenames only.

P : Pause an active build

R : Resume active build

C : Cancel build- note that this immediately halts the build and does not clear the build area. You might want to pause the build first, and then cancel shortly after to make sure the nozzle isn't left hot and in contact with a printed part.

S : Print build status, tool and platform temps

Q : Quit and logout

The Mini-DK has two onboard buttons (besides the ISP and reset buttons). Currently one button will trigger a pause (if the Makerbot is printing) and the other will resume (if the Makerbot it paused)

Compiling

Edit "Target.h" to set whether you're building for an MBED module or the Mini-DK2

Installation

If you are using a mbed, then you can simply load the BIN file to the mbed using the mass storage bootloader. The mbed mounts as if it were a USB thumbdrive, and you copy the BIN file to the drive. After a reset, you're running the installed firmware.

The MiniDK has a serial bootloader. You connect to this bootloader from the "top" USB connector (not the USB host one). Hold down the ISP button and then tap the reset button and then release the ISP button to put it into programming mode. I use [lpc21isp](http://sourceforge.net/projects/lpc21isp/) to load the binary. The other option is FlashMagic, which uses HEX files, so you'll need to use some sort of bin2hex utility to convert the firmware file if you use this utility. I can't really say if/how this works, as I don't use this method. See this (http://mbed.org/users/frankvnk/notebook/lpc1768-mini-dk/) for more info.

Credits

Some credits, where credit is due.

EthernetInterface - modified to include PHY code for both the MiniDK2 and MBED based on selected #definitions

Mini-DK - Thanks for Frank and Erik for doing all the heavy lifting getting the MBED compiler and libraries and peripherals working on the Mini-DK2

NTP Client - Thanks to Donatien for this library to set the clock over the network

RTC - Thanks to Erik for the RTC library. I've got it in my project, but I don't think I'm using it for anything (yet).

SimpleSocket - Thanks to Yamaguchi-san. Modified slightly to take out references to EthernetInterface::init() and ::getIPAddress(). For some reason these don't like to be called in a thread.

JPEGCamera - Thanks again to Yamaguchi-san. Modified to output the JPEG binary over a socket rather than to a file descriptor.

USBHost - modified as noted above

IAP - Thanks to Okano-san. Pulled out of the Mini-DK folder so that I could link it back to the base repository at the root level.

Mini-DK/SPI_TFT/SPI_TFT.cpp@2:d0acbd263ec7, 2013-01-03 (annotated)

Committer:
frankvnk
Date:
Thu Jan 03 10:54:09 2013 +0000
Revision:
2:d0acbd263ec7
Child:
5:781a72d380a1
ONLY FOR TEST

Who changed what in which revision?

UserRevisionLine numberNew contents of line
frankvnk 2:d0acbd263ec7 1 /* mbed library for 240*320 pixel TFT with ILI9320 LCD Controller
frankvnk 2:d0acbd263ec7 2 * Rewrite from Peter Drescher code - http://mbed.org/cookbook/SPI-driven-QVGA-TFT
frankvnk 2:d0acbd263ec7 3 *
frankvnk 2:d0acbd263ec7 4 * TODO : BMP routine
frankvnk 2:d0acbd263ec7 5 */
frankvnk 2:d0acbd263ec7 6
frankvnk 2:d0acbd263ec7 7
frankvnk 2:d0acbd263ec7 8
frankvnk 2:d0acbd263ec7 9 #include "SPI_TFT.h"
frankvnk 2:d0acbd263ec7 10 #include "mbed.h"
frankvnk 2:d0acbd263ec7 11
frankvnk 2:d0acbd263ec7 12
frankvnk 2:d0acbd263ec7 13 #define BPP 16 // Bits per pixel
frankvnk 2:d0acbd263ec7 14
frankvnk 2:d0acbd263ec7 15
frankvnk 2:d0acbd263ec7 16 SPI_TFT::SPI_TFT(PinName mosi, PinName miso, PinName sclk, PinName cs, const char *name)
frankvnk 2:d0acbd263ec7 17 : _spi(mosi, miso, sclk), _cs(cs), GraphicsDisplay(name)
frankvnk 2:d0acbd263ec7 18 {
frankvnk 2:d0acbd263ec7 19 char_x = 0;
frankvnk 2:d0acbd263ec7 20 tft_reset();
frankvnk 2:d0acbd263ec7 21 set_orientation(0);
frankvnk 2:d0acbd263ec7 22 }
frankvnk 2:d0acbd263ec7 23
frankvnk 2:d0acbd263ec7 24 int SPI_TFT::width()
frankvnk 2:d0acbd263ec7 25 {
frankvnk 2:d0acbd263ec7 26 if (orientation == 0 || orientation == 2) return 240;
frankvnk 2:d0acbd263ec7 27 else return 320;
frankvnk 2:d0acbd263ec7 28 }
frankvnk 2:d0acbd263ec7 29
frankvnk 2:d0acbd263ec7 30 int SPI_TFT::height()
frankvnk 2:d0acbd263ec7 31 {
frankvnk 2:d0acbd263ec7 32 if (orientation == 0 || orientation == 2) return 320;
frankvnk 2:d0acbd263ec7 33 else return 240;
frankvnk 2:d0acbd263ec7 34 }
frankvnk 2:d0acbd263ec7 35
frankvnk 2:d0acbd263ec7 36 //
frankvnk 2:d0acbd263ec7 37 void SPI_TFT::set_orientation(unsigned int o)
frankvnk 2:d0acbd263ec7 38 {
frankvnk 2:d0acbd263ec7 39 orientation = o;
frankvnk 2:d0acbd263ec7 40 WindowMax();
frankvnk 2:d0acbd263ec7 41 }
frankvnk 2:d0acbd263ec7 42
frankvnk 2:d0acbd263ec7 43 // ILI9320
frankvnk 2:d0acbd263ec7 44 // Orientation is only set before a window command (registers 0x50..0x53)
frankvnk 2:d0acbd263ec7 45 // reg 03h (Entry Mode) : BGR = 1 - ORG = 1 - ID0, ID1 and AM are set according to the orientation variable.
frankvnk 2:d0acbd263ec7 46 // IMPORTANT : when ORG = 1, the GRAM writing direction follows the orientation (ID0, ID1, AM bits)
frankvnk 2:d0acbd263ec7 47 // AND we need to use the window command (reg 50h..53h) to write to an area on the display
frankvnk 2:d0acbd263ec7 48 // because we cannot change reg 20h and 21h to set the GRAM address (they both remain at 00h).
frankvnk 2:d0acbd263ec7 49 // This means that the pixel routine does not work when ORG = 1.
frankvnk 2:d0acbd263ec7 50 // Routines relying on the pixel routine first need to set reg 03h = 0x1030
frankvnk 2:d0acbd263ec7 51 // (cls, circle and line do so) AND need to write the data according to the orientation variable.
frankvnk 2:d0acbd263ec7 52
frankvnk 2:d0acbd263ec7 53 void SPI_TFT::mod_orientation(void)
frankvnk 2:d0acbd263ec7 54 {
frankvnk 2:d0acbd263ec7 55 switch (orientation)
frankvnk 2:d0acbd263ec7 56 {
frankvnk 2:d0acbd263ec7 57 case 0:
frankvnk 2:d0acbd263ec7 58 wr_reg(0x03, 0x10b0); // ID1 = 1, ID0 = 1, AM = 0 - Portrait
frankvnk 2:d0acbd263ec7 59 break;
frankvnk 2:d0acbd263ec7 60 case 1:
frankvnk 2:d0acbd263ec7 61 wr_reg(0x03, 0x10a8); // ID1 = 1, ID0 = 0, AM = 0 - Landscape
frankvnk 2:d0acbd263ec7 62 break;
frankvnk 2:d0acbd263ec7 63 case 2:
frankvnk 2:d0acbd263ec7 64 wr_reg(0x03, 0x1080); // ID1 = 0, ID0 = 0, AM = 1 - Portrait upside down
frankvnk 2:d0acbd263ec7 65 break;
frankvnk 2:d0acbd263ec7 66 case 3:
frankvnk 2:d0acbd263ec7 67 wr_reg(0x03, 0x1098); // ID1 = 0, ID0 = 1, AM = 1 - Landscape upside down
frankvnk 2:d0acbd263ec7 68 break;
frankvnk 2:d0acbd263ec7 69 }
frankvnk 2:d0acbd263ec7 70 }
frankvnk 2:d0acbd263ec7 71
frankvnk 2:d0acbd263ec7 72 void SPI_TFT::wr_cmd(unsigned char cmd)
frankvnk 2:d0acbd263ec7 73 {
frankvnk 2:d0acbd263ec7 74 _cs = 0;
frankvnk 2:d0acbd263ec7 75 _spi.write(0x70);
frankvnk 2:d0acbd263ec7 76 _spi.write(0x00);
frankvnk 2:d0acbd263ec7 77 _spi.write(cmd);
frankvnk 2:d0acbd263ec7 78 _cs = 1;
frankvnk 2:d0acbd263ec7 79 }
frankvnk 2:d0acbd263ec7 80
frankvnk 2:d0acbd263ec7 81 void SPI_TFT::wr_dat(unsigned short dat)
frankvnk 2:d0acbd263ec7 82 {
frankvnk 2:d0acbd263ec7 83 unsigned char u,l;
frankvnk 2:d0acbd263ec7 84 u = (dat >> 0x08);
frankvnk 2:d0acbd263ec7 85 l = (dat & 0xff);
frankvnk 2:d0acbd263ec7 86 _cs = 0;
frankvnk 2:d0acbd263ec7 87 _spi.write(0x72);
frankvnk 2:d0acbd263ec7 88 _spi.write(u);
frankvnk 2:d0acbd263ec7 89 _spi.write(l);
frankvnk 2:d0acbd263ec7 90 _cs = 1;
frankvnk 2:d0acbd263ec7 91 }
frankvnk 2:d0acbd263ec7 92
frankvnk 2:d0acbd263ec7 93 void SPI_TFT::wr_dat_start(void)
frankvnk 2:d0acbd263ec7 94 {
frankvnk 2:d0acbd263ec7 95 _spi.write(0x72);
frankvnk 2:d0acbd263ec7 96 }
frankvnk 2:d0acbd263ec7 97
frankvnk 2:d0acbd263ec7 98 unsigned short SPI_TFT::rd_dat(void) // SPI frequency needs to be lowered on read
frankvnk 2:d0acbd263ec7 99 {
frankvnk 2:d0acbd263ec7 100 unsigned short val = 0;
frankvnk 2:d0acbd263ec7 101 _cs = 0;
frankvnk 2:d0acbd263ec7 102 _spi.frequency(SPI_F_LO);
frankvnk 2:d0acbd263ec7 103 _spi.write(0x73);
frankvnk 2:d0acbd263ec7 104 _spi.write(0x00);
frankvnk 2:d0acbd263ec7 105 val = _spi.write(0); // Dummy read
frankvnk 2:d0acbd263ec7 106 val = _spi.write(0); // Read D8..D15
frankvnk 2:d0acbd263ec7 107 val <<= 8;
frankvnk 2:d0acbd263ec7 108 val |= _spi.write(0); // Read D0..D7
frankvnk 2:d0acbd263ec7 109 _cs = 1;
frankvnk 2:d0acbd263ec7 110 _spi.frequency(SPI_F_HI);
frankvnk 2:d0acbd263ec7 111 return (val);
frankvnk 2:d0acbd263ec7 112 }
frankvnk 2:d0acbd263ec7 113
frankvnk 2:d0acbd263ec7 114 void SPI_TFT::wr_reg(unsigned char reg, unsigned short val)
frankvnk 2:d0acbd263ec7 115 {
frankvnk 2:d0acbd263ec7 116 wr_cmd(reg);
frankvnk 2:d0acbd263ec7 117 wr_dat(val);
frankvnk 2:d0acbd263ec7 118 }
frankvnk 2:d0acbd263ec7 119
frankvnk 2:d0acbd263ec7 120 unsigned short SPI_TFT::rd_reg(unsigned char reg)
frankvnk 2:d0acbd263ec7 121 {
frankvnk 2:d0acbd263ec7 122 wr_cmd(reg);
frankvnk 2:d0acbd263ec7 123 return(rd_dat());
frankvnk 2:d0acbd263ec7 124 }
frankvnk 2:d0acbd263ec7 125
frankvnk 2:d0acbd263ec7 126 unsigned short SPI_TFT::Read_ID(void) // IMPORTANT : SPI frequency needs to be lowered when reading
frankvnk 2:d0acbd263ec7 127 {
frankvnk 2:d0acbd263ec7 128 unsigned short val = 0;
frankvnk 2:d0acbd263ec7 129 _cs = 0;
frankvnk 2:d0acbd263ec7 130 _spi.write(0x70);
frankvnk 2:d0acbd263ec7 131 _spi.write(0x00);
frankvnk 2:d0acbd263ec7 132 _spi.write(0X00);
frankvnk 2:d0acbd263ec7 133 _cs = 1;
frankvnk 2:d0acbd263ec7 134 _spi.frequency(SPI_F_LO);
frankvnk 2:d0acbd263ec7 135 _cs = 0;
frankvnk 2:d0acbd263ec7 136 _spi.write(0x73);
frankvnk 2:d0acbd263ec7 137 val = _spi.write(0x00); // Dummy read
frankvnk 2:d0acbd263ec7 138 val = _spi.write(0x00); // Read D8..D15
frankvnk 2:d0acbd263ec7 139 val <<= 8;
frankvnk 2:d0acbd263ec7 140 val |= _spi.write(0x00); // Read D0..D7
frankvnk 2:d0acbd263ec7 141 _cs = 1;
frankvnk 2:d0acbd263ec7 142 _spi.frequency(SPI_F_HI);
frankvnk 2:d0acbd263ec7 143 return (val);
frankvnk 2:d0acbd263ec7 144 }
frankvnk 2:d0acbd263ec7 145
frankvnk 2:d0acbd263ec7 146 void SPI_TFT::SetCursor( unsigned short Xpos, unsigned short Ypos )
frankvnk 2:d0acbd263ec7 147 {
frankvnk 2:d0acbd263ec7 148 wr_reg(0x20, Xpos );
frankvnk 2:d0acbd263ec7 149 wr_reg(0x21, Ypos );
frankvnk 2:d0acbd263ec7 150 }
frankvnk 2:d0acbd263ec7 151
frankvnk 2:d0acbd263ec7 152 void SPI_TFT::tft_reset()
frankvnk 2:d0acbd263ec7 153 {
frankvnk 2:d0acbd263ec7 154 _spi.format(8,3); // 8 bit spi mode 3
frankvnk 2:d0acbd263ec7 155 _spi.frequency(SPI_F_HI); // 48 Mhz SPI clock
frankvnk 2:d0acbd263ec7 156
frankvnk 2:d0acbd263ec7 157 wr_reg(0x00,0x0000);
frankvnk 2:d0acbd263ec7 158 wr_reg(0x01,0x0100); // Driver Output Control
frankvnk 2:d0acbd263ec7 159 wr_reg(0x02,0x0700); // LCD Driver Waveform Control
frankvnk 2:d0acbd263ec7 160 wr_reg(0x03,0x1030); // Set the scan mode
frankvnk 2:d0acbd263ec7 161 wr_reg(0x04,0x0000); // Scaling Control
frankvnk 2:d0acbd263ec7 162 wr_reg(0x08,0x0202); // Display Control 2
frankvnk 2:d0acbd263ec7 163 wr_reg(0x09,0x0000); // Display Control 3
frankvnk 2:d0acbd263ec7 164 wr_reg(0x0a,0x0000); // Frame Cycle Contal
frankvnk 2:d0acbd263ec7 165 wr_reg(0x0c,(1<<0)); // Extern Display Interface Control 1
frankvnk 2:d0acbd263ec7 166 wr_reg(0x0d,0x0000); // Frame Maker Position
frankvnk 2:d0acbd263ec7 167 wr_reg(0x0f,0x0000); // Extern Display Interface Control 2
frankvnk 2:d0acbd263ec7 168
frankvnk 2:d0acbd263ec7 169 wait_ms(50);
frankvnk 2:d0acbd263ec7 170
frankvnk 2:d0acbd263ec7 171 wr_reg(0x07,0x0101); // Display Control
frankvnk 2:d0acbd263ec7 172
frankvnk 2:d0acbd263ec7 173 wait_ms(50);
frankvnk 2:d0acbd263ec7 174
frankvnk 2:d0acbd263ec7 175 wr_reg(0x10,(1<<12)|(0<<8)|(1<<7)|(1<<6)|(0<<4)); // Power Control 1
frankvnk 2:d0acbd263ec7 176 wr_reg(0x11,0x0007); // Power Control 2
frankvnk 2:d0acbd263ec7 177 wr_reg(0x12,(1<<8)|(1<<4)|(0<<0)); // Power Control 3
frankvnk 2:d0acbd263ec7 178 wr_reg(0x13,0x0b00); // Power Control 4
frankvnk 2:d0acbd263ec7 179 wr_reg(0x29,0x0000); // Power Control 7
frankvnk 2:d0acbd263ec7 180 wr_reg(0x2b,(1<<14)|(1<<4));
frankvnk 2:d0acbd263ec7 181
frankvnk 2:d0acbd263ec7 182 wr_reg(0x50,0); // Set X Start
frankvnk 2:d0acbd263ec7 183 wr_reg(0x51,239); // Set X End
frankvnk 2:d0acbd263ec7 184 wr_reg(0x52,0); // Set Y Start
frankvnk 2:d0acbd263ec7 185 wr_reg(0x53,319); // Set Y End
frankvnk 2:d0acbd263ec7 186
frankvnk 2:d0acbd263ec7 187 wait_ms(50);
frankvnk 2:d0acbd263ec7 188
frankvnk 2:d0acbd263ec7 189 wr_reg(0x60,0x2700); // Driver Output Control
frankvnk 2:d0acbd263ec7 190 wr_reg(0x61,0x0001); // Driver Output Control
frankvnk 2:d0acbd263ec7 191 wr_reg(0x6a,0x0000); // Vertical Srcoll Control
frankvnk 2:d0acbd263ec7 192
frankvnk 2:d0acbd263ec7 193 wr_reg(0x80,0x0000); // Display Position Partial Display 1
frankvnk 2:d0acbd263ec7 194 wr_reg(0x81,0x0000); // RAM Address Start Partial Display 1
frankvnk 2:d0acbd263ec7 195 wr_reg(0x82,0x0000); // RAM Address End-Partial Display 1
frankvnk 2:d0acbd263ec7 196 wr_reg(0x83,0x0000); // Displsy Position Partial Display 2
frankvnk 2:d0acbd263ec7 197 wr_reg(0x84,0x0000); // RAM Address Start Partial Display 2
frankvnk 2:d0acbd263ec7 198 wr_reg(0x85,0x0000); // RAM Address End Partial Display 2
frankvnk 2:d0acbd263ec7 199
frankvnk 2:d0acbd263ec7 200 wr_reg(0x90,(0<<7)|(16<<0)); // Frame Cycle Control
frankvnk 2:d0acbd263ec7 201 wr_reg(0x92,0x0000); // Panel Interface Control 2
frankvnk 2:d0acbd263ec7 202 wr_reg(0x93,0x0001); // Panel Interface Control 3
frankvnk 2:d0acbd263ec7 203 wr_reg(0x95,0x0110); // Frame Cycle Control
frankvnk 2:d0acbd263ec7 204 wr_reg(0x97,(0<<8));
frankvnk 2:d0acbd263ec7 205 wr_reg(0x98,0x0000); // Frame Cycle Control
frankvnk 2:d0acbd263ec7 206 wr_reg(0x07,0x0133);
frankvnk 2:d0acbd263ec7 207
frankvnk 2:d0acbd263ec7 208 wait_ms(100);
frankvnk 2:d0acbd263ec7 209 WindowMax();
frankvnk 2:d0acbd263ec7 210 }
frankvnk 2:d0acbd263ec7 211
frankvnk 2:d0acbd263ec7 212
frankvnk 2:d0acbd263ec7 213 void SPI_TFT::pixel(int x, int y, int color)
frankvnk 2:d0acbd263ec7 214 {
frankvnk 2:d0acbd263ec7 215 switch (orientation)
frankvnk 2:d0acbd263ec7 216 {
frankvnk 2:d0acbd263ec7 217 case 0:
frankvnk 2:d0acbd263ec7 218 wr_reg(0x20, x);
frankvnk 2:d0acbd263ec7 219 wr_reg(0x21, y);
frankvnk 2:d0acbd263ec7 220 break;
frankvnk 2:d0acbd263ec7 221 case 1:
frankvnk 2:d0acbd263ec7 222 wr_reg(0x20, 239-y);
frankvnk 2:d0acbd263ec7 223 wr_reg(0x21, x);
frankvnk 2:d0acbd263ec7 224 break;
frankvnk 2:d0acbd263ec7 225 case 2:
frankvnk 2:d0acbd263ec7 226 wr_reg(0x20, 239-x);
frankvnk 2:d0acbd263ec7 227 wr_reg(0x21, 319-y);
frankvnk 2:d0acbd263ec7 228 break;
frankvnk 2:d0acbd263ec7 229 case 3:
frankvnk 2:d0acbd263ec7 230 wr_reg(0x20, y);
frankvnk 2:d0acbd263ec7 231 wr_reg(0x21, 319-x);
frankvnk 2:d0acbd263ec7 232 break;
frankvnk 2:d0acbd263ec7 233 }
frankvnk 2:d0acbd263ec7 234 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 235 wr_dat(color);
frankvnk 2:d0acbd263ec7 236 }
frankvnk 2:d0acbd263ec7 237
frankvnk 2:d0acbd263ec7 238
frankvnk 2:d0acbd263ec7 239 void SPI_TFT::window(unsigned int x, unsigned int y, unsigned int w, unsigned int h)
frankvnk 2:d0acbd263ec7 240 {
frankvnk 2:d0acbd263ec7 241 unsigned int xw1, yh1;
frankvnk 2:d0acbd263ec7 242 xw1 = x + w - 1;
frankvnk 2:d0acbd263ec7 243 yh1 = y + h - 1;
frankvnk 2:d0acbd263ec7 244 wr_reg(0x20, x);
frankvnk 2:d0acbd263ec7 245 wr_reg(0x21, y);
frankvnk 2:d0acbd263ec7 246 switch (orientation)
frankvnk 2:d0acbd263ec7 247 {
frankvnk 2:d0acbd263ec7 248 case 0:
frankvnk 2:d0acbd263ec7 249 wr_reg(0x50, x);
frankvnk 2:d0acbd263ec7 250 wr_reg(0x51, xw1);
frankvnk 2:d0acbd263ec7 251 wr_reg(0x52, y);
frankvnk 2:d0acbd263ec7 252 wr_reg(0x53, yh1);
frankvnk 2:d0acbd263ec7 253 break;
frankvnk 2:d0acbd263ec7 254 case 1:
frankvnk 2:d0acbd263ec7 255 wr_reg(0x50, 239 - yh1);
frankvnk 2:d0acbd263ec7 256 wr_reg(0x51, 239 - y);
frankvnk 2:d0acbd263ec7 257 wr_reg(0x52, x);
frankvnk 2:d0acbd263ec7 258 wr_reg(0x53, xw1);
frankvnk 2:d0acbd263ec7 259 break;
frankvnk 2:d0acbd263ec7 260 case 2:
frankvnk 2:d0acbd263ec7 261 wr_reg(0x50, 239 - xw1);
frankvnk 2:d0acbd263ec7 262 wr_reg(0x51, 239 - x);
frankvnk 2:d0acbd263ec7 263 wr_reg(0x52, 319 - yh1);
frankvnk 2:d0acbd263ec7 264 wr_reg(0x53, 319 - y);
frankvnk 2:d0acbd263ec7 265 break;
frankvnk 2:d0acbd263ec7 266 case 3:
frankvnk 2:d0acbd263ec7 267 wr_reg(0x50, y);
frankvnk 2:d0acbd263ec7 268 wr_reg(0x51, yh1);
frankvnk 2:d0acbd263ec7 269 wr_reg(0x52, 319 - xw1);
frankvnk 2:d0acbd263ec7 270 wr_reg(0x53, 319 - x);
frankvnk 2:d0acbd263ec7 271 break;
frankvnk 2:d0acbd263ec7 272 }
frankvnk 2:d0acbd263ec7 273 }
frankvnk 2:d0acbd263ec7 274
frankvnk 2:d0acbd263ec7 275
frankvnk 2:d0acbd263ec7 276 void SPI_TFT::WindowMax(void)
frankvnk 2:d0acbd263ec7 277 {
frankvnk 2:d0acbd263ec7 278 window(0, 0, width(), height());
frankvnk 2:d0acbd263ec7 279 }
frankvnk 2:d0acbd263ec7 280
frankvnk 2:d0acbd263ec7 281
frankvnk 2:d0acbd263ec7 282 void SPI_TFT::cls (void)
frankvnk 2:d0acbd263ec7 283 {
frankvnk 2:d0acbd263ec7 284 unsigned long int index=0;
frankvnk 2:d0acbd263ec7 285 // int color = _background;
frankvnk 2:d0acbd263ec7 286 wr_reg(0x03, 0x1030);
frankvnk 2:d0acbd263ec7 287 WindowMax();
frankvnk 2:d0acbd263ec7 288 SetCursor(0,0);
frankvnk 2:d0acbd263ec7 289 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 290 _cs = 0;
frankvnk 2:d0acbd263ec7 291 wr_dat_start();
frankvnk 2:d0acbd263ec7 292 _spi.format(16,3);
frankvnk 2:d0acbd263ec7 293 for( index = 0; index<width()*height(); index++ )
frankvnk 2:d0acbd263ec7 294 {
frankvnk 2:d0acbd263ec7 295 _spi.write(_background);
frankvnk 2:d0acbd263ec7 296 }
frankvnk 2:d0acbd263ec7 297 _spi.format(8,3);
frankvnk 2:d0acbd263ec7 298 _cs = 1;
frankvnk 2:d0acbd263ec7 299 }
frankvnk 2:d0acbd263ec7 300
frankvnk 2:d0acbd263ec7 301 void SPI_TFT::hline(int x0, int x1, int y, int color)
frankvnk 2:d0acbd263ec7 302 {
frankvnk 2:d0acbd263ec7 303 unsigned int index=0;
frankvnk 2:d0acbd263ec7 304 int w;
frankvnk 2:d0acbd263ec7 305 w = x1 - x0 + 1;
frankvnk 2:d0acbd263ec7 306 mod_orientation();
frankvnk 2:d0acbd263ec7 307 window(x0,y,w,1);
frankvnk 2:d0acbd263ec7 308 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 309 _cs = 0;
frankvnk 2:d0acbd263ec7 310 wr_dat_start();
frankvnk 2:d0acbd263ec7 311 _spi.format(16,3);
frankvnk 2:d0acbd263ec7 312 for( index = 0; index < (x1 - x0); index++ )
frankvnk 2:d0acbd263ec7 313 {
frankvnk 2:d0acbd263ec7 314 _spi.write(color);
frankvnk 2:d0acbd263ec7 315 }
frankvnk 2:d0acbd263ec7 316 _spi.format(8,3);
frankvnk 2:d0acbd263ec7 317 _cs = 1;
frankvnk 2:d0acbd263ec7 318 return;
frankvnk 2:d0acbd263ec7 319 }
frankvnk 2:d0acbd263ec7 320
frankvnk 2:d0acbd263ec7 321 void SPI_TFT::vline(int x, int y0, int y1, int color)
frankvnk 2:d0acbd263ec7 322 {
frankvnk 2:d0acbd263ec7 323 unsigned int index=0;
frankvnk 2:d0acbd263ec7 324 int h;
frankvnk 2:d0acbd263ec7 325 h = y1 - y0 + 1;
frankvnk 2:d0acbd263ec7 326 mod_orientation();
frankvnk 2:d0acbd263ec7 327 window(x,y0,1,h);
frankvnk 2:d0acbd263ec7 328 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 329 _cs = 0;
frankvnk 2:d0acbd263ec7 330 wr_dat_start();
frankvnk 2:d0acbd263ec7 331 _spi.format(16,3);
frankvnk 2:d0acbd263ec7 332 for( index = 0; index < (y1 - y0); index++ )
frankvnk 2:d0acbd263ec7 333 {
frankvnk 2:d0acbd263ec7 334 _spi.write(color);
frankvnk 2:d0acbd263ec7 335 }
frankvnk 2:d0acbd263ec7 336 _spi.format(8,3);
frankvnk 2:d0acbd263ec7 337 _cs = 1;
frankvnk 2:d0acbd263ec7 338 return;
frankvnk 2:d0acbd263ec7 339 }
frankvnk 2:d0acbd263ec7 340
frankvnk 2:d0acbd263ec7 341 void SPI_TFT::line(int x0, int y0, int x1, int y1, int color)
frankvnk 2:d0acbd263ec7 342 {
frankvnk 2:d0acbd263ec7 343 wr_reg(0x03, 0x1030);
frankvnk 2:d0acbd263ec7 344 WindowMax();
frankvnk 2:d0acbd263ec7 345 int dx = 0, dy = 0;
frankvnk 2:d0acbd263ec7 346 int dx_sym = 0, dy_sym = 0;
frankvnk 2:d0acbd263ec7 347 int dx_x2 = 0, dy_x2 = 0;
frankvnk 2:d0acbd263ec7 348 int di = 0;
frankvnk 2:d0acbd263ec7 349
frankvnk 2:d0acbd263ec7 350 dx = x1-x0;
frankvnk 2:d0acbd263ec7 351 dy = y1-y0;
frankvnk 2:d0acbd263ec7 352
frankvnk 2:d0acbd263ec7 353 if (dx == 0) { /* vertical line */
frankvnk 2:d0acbd263ec7 354 if (y1 > y0) vline(x0,y0,y1,color);
frankvnk 2:d0acbd263ec7 355 else vline(x0,y1,y0,color);
frankvnk 2:d0acbd263ec7 356 return;
frankvnk 2:d0acbd263ec7 357 }
frankvnk 2:d0acbd263ec7 358
frankvnk 2:d0acbd263ec7 359 if (dx > 0) {
frankvnk 2:d0acbd263ec7 360 dx_sym = 1;
frankvnk 2:d0acbd263ec7 361 } else {
frankvnk 2:d0acbd263ec7 362 dx_sym = -1;
frankvnk 2:d0acbd263ec7 363 }
frankvnk 2:d0acbd263ec7 364 if (dy == 0) { /* horizontal line */
frankvnk 2:d0acbd263ec7 365 if (x1 > x0) hline(x0,x1,y0,color);
frankvnk 2:d0acbd263ec7 366 else hline(x1,x0,y0,color);
frankvnk 2:d0acbd263ec7 367 return;
frankvnk 2:d0acbd263ec7 368 }
frankvnk 2:d0acbd263ec7 369
frankvnk 2:d0acbd263ec7 370 if (dy > 0) {
frankvnk 2:d0acbd263ec7 371 dy_sym = 1;
frankvnk 2:d0acbd263ec7 372 } else {
frankvnk 2:d0acbd263ec7 373 dy_sym = -1;
frankvnk 2:d0acbd263ec7 374 }
frankvnk 2:d0acbd263ec7 375
frankvnk 2:d0acbd263ec7 376 dx = dx_sym*dx;
frankvnk 2:d0acbd263ec7 377 dy = dy_sym*dy;
frankvnk 2:d0acbd263ec7 378
frankvnk 2:d0acbd263ec7 379 dx_x2 = dx*2;
frankvnk 2:d0acbd263ec7 380 dy_x2 = dy*2;
frankvnk 2:d0acbd263ec7 381
frankvnk 2:d0acbd263ec7 382 if (dx >= dy) {
frankvnk 2:d0acbd263ec7 383 di = dy_x2 - dx;
frankvnk 2:d0acbd263ec7 384 while (x0 != x1) {
frankvnk 2:d0acbd263ec7 385
frankvnk 2:d0acbd263ec7 386 pixel(x0, y0, color);
frankvnk 2:d0acbd263ec7 387 x0 += dx_sym;
frankvnk 2:d0acbd263ec7 388 if (di<0) {
frankvnk 2:d0acbd263ec7 389 di += dy_x2;
frankvnk 2:d0acbd263ec7 390 } else {
frankvnk 2:d0acbd263ec7 391 di += dy_x2 - dx_x2;
frankvnk 2:d0acbd263ec7 392 y0 += dy_sym;
frankvnk 2:d0acbd263ec7 393 }
frankvnk 2:d0acbd263ec7 394 }
frankvnk 2:d0acbd263ec7 395 pixel(x0, y0, color);
frankvnk 2:d0acbd263ec7 396 } else {
frankvnk 2:d0acbd263ec7 397 di = dx_x2 - dy;
frankvnk 2:d0acbd263ec7 398 while (y0 != y1) {
frankvnk 2:d0acbd263ec7 399 pixel(x0, y0, color);
frankvnk 2:d0acbd263ec7 400 y0 += dy_sym;
frankvnk 2:d0acbd263ec7 401 if (di < 0) {
frankvnk 2:d0acbd263ec7 402 di += dx_x2;
frankvnk 2:d0acbd263ec7 403 } else {
frankvnk 2:d0acbd263ec7 404 di += dx_x2 - dy_x2;
frankvnk 2:d0acbd263ec7 405 x0 += dx_sym;
frankvnk 2:d0acbd263ec7 406 }
frankvnk 2:d0acbd263ec7 407 }
frankvnk 2:d0acbd263ec7 408 pixel(x0, y0, color);
frankvnk 2:d0acbd263ec7 409 }
frankvnk 2:d0acbd263ec7 410 return;
frankvnk 2:d0acbd263ec7 411 }
frankvnk 2:d0acbd263ec7 412
frankvnk 2:d0acbd263ec7 413
frankvnk 2:d0acbd263ec7 414 void SPI_TFT::rect(int x0, int y0, int w, int h, int color)
frankvnk 2:d0acbd263ec7 415 {
frankvnk 2:d0acbd263ec7 416 hline(x0,x0+w,y0,color);
frankvnk 2:d0acbd263ec7 417 vline(x0,y0,y0+h,color);
frankvnk 2:d0acbd263ec7 418 hline(x0,x0+w,y0+h,color);
frankvnk 2:d0acbd263ec7 419 vline(x0+w,y0,y0+h,color);
frankvnk 2:d0acbd263ec7 420
frankvnk 2:d0acbd263ec7 421 return;
frankvnk 2:d0acbd263ec7 422 }
frankvnk 2:d0acbd263ec7 423
frankvnk 2:d0acbd263ec7 424 void SPI_TFT::fillrect(int x0, int y0, int w, int h, int color)
frankvnk 2:d0acbd263ec7 425 {
frankvnk 2:d0acbd263ec7 426 unsigned long int index=0;
frankvnk 2:d0acbd263ec7 427 if (w < 0)
frankvnk 2:d0acbd263ec7 428 {
frankvnk 2:d0acbd263ec7 429 x0 = x0 + w;
frankvnk 2:d0acbd263ec7 430 w = -w;
frankvnk 2:d0acbd263ec7 431 }
frankvnk 2:d0acbd263ec7 432 if (h < 0)
frankvnk 2:d0acbd263ec7 433 {
frankvnk 2:d0acbd263ec7 434 y0 = y0 + h;
frankvnk 2:d0acbd263ec7 435 h = -h;
frankvnk 2:d0acbd263ec7 436 }
frankvnk 2:d0acbd263ec7 437 mod_orientation();
frankvnk 2:d0acbd263ec7 438 window(x0,y0,w,h);
frankvnk 2:d0acbd263ec7 439 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 440 _cs = 0;
frankvnk 2:d0acbd263ec7 441 wr_dat_start();
frankvnk 2:d0acbd263ec7 442 _spi.format(16,3);
frankvnk 2:d0acbd263ec7 443 for( index = 0; index < h * w; index++ )
frankvnk 2:d0acbd263ec7 444 {
frankvnk 2:d0acbd263ec7 445 _spi.write(color);
frankvnk 2:d0acbd263ec7 446 }
frankvnk 2:d0acbd263ec7 447 _spi.format(8,3);
frankvnk 2:d0acbd263ec7 448 _cs = 1;
frankvnk 2:d0acbd263ec7 449 return;
frankvnk 2:d0acbd263ec7 450 }
frankvnk 2:d0acbd263ec7 451
frankvnk 2:d0acbd263ec7 452 void SPI_TFT::draw_ellipse(int xc, int yc, int a, int b, unsigned int color)
frankvnk 2:d0acbd263ec7 453 { /* e(x,y) = b^2*x^2 + a^2*y^2 - a^2*b^2 */
frankvnk 2:d0acbd263ec7 454 wr_reg(0x03, 0x1030);
frankvnk 2:d0acbd263ec7 455 WindowMax();
frankvnk 2:d0acbd263ec7 456 int x = 0, y = b;
frankvnk 2:d0acbd263ec7 457 long a2 = (long)a*a, b2 = (long)b*b;
frankvnk 2:d0acbd263ec7 458 long crit1 = -(a2/4 + a%2 + b2);
frankvnk 2:d0acbd263ec7 459 long crit2 = -(b2/4 + b%2 + a2);
frankvnk 2:d0acbd263ec7 460 long crit3 = -(b2/4 + b%2);
frankvnk 2:d0acbd263ec7 461 long t = -a2*y; /* e(x+1/2,y-1/2) - (a^2+b^2)/4 */
frankvnk 2:d0acbd263ec7 462 long dxt = 2*b2*x, dyt = -2*a2*y;
frankvnk 2:d0acbd263ec7 463 long d2xt = 2*b2, d2yt = 2*a2;
frankvnk 2:d0acbd263ec7 464
frankvnk 2:d0acbd263ec7 465 while (y>=0 && x<=a)
frankvnk 2:d0acbd263ec7 466 {
frankvnk 2:d0acbd263ec7 467 pixel(xc+x, yc+y, color);
frankvnk 2:d0acbd263ec7 468 if (x!=0 || y!=0)
frankvnk 2:d0acbd263ec7 469 pixel(xc-x, yc-y, color);
frankvnk 2:d0acbd263ec7 470 if (x!=0 && y!=0)
frankvnk 2:d0acbd263ec7 471 {
frankvnk 2:d0acbd263ec7 472 pixel(xc+x, yc-y, color);
frankvnk 2:d0acbd263ec7 473 pixel(xc-x, yc+y, color);
frankvnk 2:d0acbd263ec7 474 }
frankvnk 2:d0acbd263ec7 475 if (t + b2*x <= crit1 || /* e(x+1,y-1/2) <= 0 */
frankvnk 2:d0acbd263ec7 476 t + a2*y <= crit3) /* e(x+1/2,y) <= 0 */
frankvnk 2:d0acbd263ec7 477 incx();
frankvnk 2:d0acbd263ec7 478 else if (t - a2*y > crit2) /* e(x+1/2,y-1) > 0 */
frankvnk 2:d0acbd263ec7 479 incy();
frankvnk 2:d0acbd263ec7 480 else
frankvnk 2:d0acbd263ec7 481 {
frankvnk 2:d0acbd263ec7 482 incx();
frankvnk 2:d0acbd263ec7 483 incy();
frankvnk 2:d0acbd263ec7 484 }
frankvnk 2:d0acbd263ec7 485 }
frankvnk 2:d0acbd263ec7 486 }
frankvnk 2:d0acbd263ec7 487
frankvnk 2:d0acbd263ec7 488 void SPI_TFT::fill_ellipse(int xc, int yc, int a, int b, unsigned int color)
frankvnk 2:d0acbd263ec7 489 { /* e(x,y) = b^2*x^2 + a^2*y^2 - a^2*b^2 */
frankvnk 2:d0acbd263ec7 490 int x = 0, y = b;
frankvnk 2:d0acbd263ec7 491 int rx = x, ry = y;
frankvnk 2:d0acbd263ec7 492 unsigned int width = 1;
frankvnk 2:d0acbd263ec7 493 unsigned int height = 1;
frankvnk 2:d0acbd263ec7 494 long a2 = (long)a*a, b2 = (long)b*b;
frankvnk 2:d0acbd263ec7 495 long crit1 = -(a2/4 + a%2 + b2);
frankvnk 2:d0acbd263ec7 496 long crit2 = -(b2/4 + b%2 + a2);
frankvnk 2:d0acbd263ec7 497 long crit3 = -(b2/4 + b%2);
frankvnk 2:d0acbd263ec7 498 long t = -a2*y; /* e(x+1/2,y-1/2) - (a^2+b^2)/4 */
frankvnk 2:d0acbd263ec7 499 long dxt = 2*b2*x, dyt = -2*a2*y;
frankvnk 2:d0acbd263ec7 500 long d2xt = 2*b2, d2yt = 2*a2;
frankvnk 2:d0acbd263ec7 501
frankvnk 2:d0acbd263ec7 502 if (b == 0)
frankvnk 2:d0acbd263ec7 503 {
frankvnk 2:d0acbd263ec7 504 fillrect(xc-a, yc, 2*a+1, 1, color);
frankvnk 2:d0acbd263ec7 505 return;
frankvnk 2:d0acbd263ec7 506 }
frankvnk 2:d0acbd263ec7 507
frankvnk 2:d0acbd263ec7 508 while (y>=0 && x<=a)
frankvnk 2:d0acbd263ec7 509 {
frankvnk 2:d0acbd263ec7 510 if (t + b2*x <= crit1 || /* e(x+1,y-1/2) <= 0 */
frankvnk 2:d0acbd263ec7 511 t + a2*y <= crit3) /* e(x+1/2,y) <= 0 */
frankvnk 2:d0acbd263ec7 512 {
frankvnk 2:d0acbd263ec7 513 if (height == 1)
frankvnk 2:d0acbd263ec7 514 ; /* draw nothing */
frankvnk 2:d0acbd263ec7 515 else if (ry*2+1 > (height-1)*2)
frankvnk 2:d0acbd263ec7 516 {
frankvnk 2:d0acbd263ec7 517 fillrect(xc-rx, yc-ry, width, height-1, color);
frankvnk 2:d0acbd263ec7 518 fillrect(xc-rx, yc+ry+1, width, 1-height, color);
frankvnk 2:d0acbd263ec7 519 ry -= height-1;
frankvnk 2:d0acbd263ec7 520 height = 1;
frankvnk 2:d0acbd263ec7 521 }
frankvnk 2:d0acbd263ec7 522 else
frankvnk 2:d0acbd263ec7 523 {
frankvnk 2:d0acbd263ec7 524 fillrect(xc-rx, yc-ry, width, ry*2+1, color);
frankvnk 2:d0acbd263ec7 525 ry -= ry;
frankvnk 2:d0acbd263ec7 526 height = 1;
frankvnk 2:d0acbd263ec7 527 }
frankvnk 2:d0acbd263ec7 528 incx();
frankvnk 2:d0acbd263ec7 529 rx++;
frankvnk 2:d0acbd263ec7 530 width += 2;
frankvnk 2:d0acbd263ec7 531 }
frankvnk 2:d0acbd263ec7 532 else if (t - a2*y > crit2) /* e(x+1/2,y-1) > 0 */
frankvnk 2:d0acbd263ec7 533 {
frankvnk 2:d0acbd263ec7 534 incy();
frankvnk 2:d0acbd263ec7 535 height++;
frankvnk 2:d0acbd263ec7 536 }
frankvnk 2:d0acbd263ec7 537 else
frankvnk 2:d0acbd263ec7 538 {
frankvnk 2:d0acbd263ec7 539 if (ry*2+1 > height*2)
frankvnk 2:d0acbd263ec7 540 {
frankvnk 2:d0acbd263ec7 541 fillrect(xc-rx, yc-ry, width, height, color);
frankvnk 2:d0acbd263ec7 542 fillrect(xc-rx, yc+ry+1, width, -height, color);
frankvnk 2:d0acbd263ec7 543 }
frankvnk 2:d0acbd263ec7 544 else
frankvnk 2:d0acbd263ec7 545 {
frankvnk 2:d0acbd263ec7 546 fillrect(xc-rx, yc-ry, width, ry*2+1, color);
frankvnk 2:d0acbd263ec7 547 }
frankvnk 2:d0acbd263ec7 548 incx();
frankvnk 2:d0acbd263ec7 549 incy();
frankvnk 2:d0acbd263ec7 550 rx++;
frankvnk 2:d0acbd263ec7 551 width += 2;
frankvnk 2:d0acbd263ec7 552 ry -= height;
frankvnk 2:d0acbd263ec7 553 height = 1;
frankvnk 2:d0acbd263ec7 554 }
frankvnk 2:d0acbd263ec7 555 }
frankvnk 2:d0acbd263ec7 556
frankvnk 2:d0acbd263ec7 557 if (ry > height)
frankvnk 2:d0acbd263ec7 558 {
frankvnk 2:d0acbd263ec7 559 fillrect(xc-rx, yc-ry, width, height, color);
frankvnk 2:d0acbd263ec7 560 fillrect(xc-rx, yc+ry+1, width, -height, color);
frankvnk 2:d0acbd263ec7 561 }
frankvnk 2:d0acbd263ec7 562 else
frankvnk 2:d0acbd263ec7 563 {
frankvnk 2:d0acbd263ec7 564 fillrect(xc-rx, yc-ry, width, ry*2+1, color);
frankvnk 2:d0acbd263ec7 565 }
frankvnk 2:d0acbd263ec7 566 }
frankvnk 2:d0acbd263ec7 567
frankvnk 2:d0acbd263ec7 568
frankvnk 2:d0acbd263ec7 569 void SPI_TFT::locate(int x, int y)
frankvnk 2:d0acbd263ec7 570 {
frankvnk 2:d0acbd263ec7 571 char_x = x;
frankvnk 2:d0acbd263ec7 572 char_y = y;
frankvnk 2:d0acbd263ec7 573 }
frankvnk 2:d0acbd263ec7 574
frankvnk 2:d0acbd263ec7 575 int SPI_TFT::columns()
frankvnk 2:d0acbd263ec7 576 {
frankvnk 2:d0acbd263ec7 577 return width() / font[1];
frankvnk 2:d0acbd263ec7 578 }
frankvnk 2:d0acbd263ec7 579
frankvnk 2:d0acbd263ec7 580 int SPI_TFT::rows()
frankvnk 2:d0acbd263ec7 581 {
frankvnk 2:d0acbd263ec7 582 return height() / font[2];
frankvnk 2:d0acbd263ec7 583 }
frankvnk 2:d0acbd263ec7 584
frankvnk 2:d0acbd263ec7 585 int SPI_TFT::_putc(int value)
frankvnk 2:d0acbd263ec7 586 {
frankvnk 2:d0acbd263ec7 587 if (value == '\n') // new line
frankvnk 2:d0acbd263ec7 588 {
frankvnk 2:d0acbd263ec7 589 char_x = 0;
frankvnk 2:d0acbd263ec7 590 char_y = char_y + font[2];
frankvnk 2:d0acbd263ec7 591 if (char_y >= height() - font[2])
frankvnk 2:d0acbd263ec7 592 {
frankvnk 2:d0acbd263ec7 593 char_y = 0;
frankvnk 2:d0acbd263ec7 594 }
frankvnk 2:d0acbd263ec7 595 }
frankvnk 2:d0acbd263ec7 596 else
frankvnk 2:d0acbd263ec7 597 {
frankvnk 2:d0acbd263ec7 598 character(char_x, char_y, value);
frankvnk 2:d0acbd263ec7 599 }
frankvnk 2:d0acbd263ec7 600 return value;
frankvnk 2:d0acbd263ec7 601 }
frankvnk 2:d0acbd263ec7 602
frankvnk 2:d0acbd263ec7 603 void SPI_TFT::character(int x, int y, int c)
frankvnk 2:d0acbd263ec7 604 {
frankvnk 2:d0acbd263ec7 605 unsigned int hor,vert,offset,bpl,j,i,b;
frankvnk 2:d0acbd263ec7 606 unsigned char* bitmap_char;
frankvnk 2:d0acbd263ec7 607 unsigned char z,w;
frankvnk 2:d0acbd263ec7 608
frankvnk 2:d0acbd263ec7 609 if ((c < 31) || (c > 127)) return; // test char range
frankvnk 2:d0acbd263ec7 610
frankvnk 2:d0acbd263ec7 611 // read font parameter from start of array
frankvnk 2:d0acbd263ec7 612 offset = font[0]; // bytes / char
frankvnk 2:d0acbd263ec7 613 hor = font[1]; // get hor size of font
frankvnk 2:d0acbd263ec7 614 vert = font[2]; // get vert size of font
frankvnk 2:d0acbd263ec7 615 bpl = font[3]; // bytes per line
frankvnk 2:d0acbd263ec7 616
frankvnk 2:d0acbd263ec7 617 if (char_x + hor > width())
frankvnk 2:d0acbd263ec7 618 {
frankvnk 2:d0acbd263ec7 619 char_x = 0;
frankvnk 2:d0acbd263ec7 620 char_y = char_y + vert;
frankvnk 2:d0acbd263ec7 621 if (char_y >= height() - font[2])
frankvnk 2:d0acbd263ec7 622 {
frankvnk 2:d0acbd263ec7 623 char_y = 0;
frankvnk 2:d0acbd263ec7 624 }
frankvnk 2:d0acbd263ec7 625 }
frankvnk 2:d0acbd263ec7 626 mod_orientation();
frankvnk 2:d0acbd263ec7 627
frankvnk 2:d0acbd263ec7 628 bitmap_char = &font[((c -32) * offset) + 4]; // start of char bitmap
frankvnk 2:d0acbd263ec7 629 w = bitmap_char[0]; // width of actual char
frankvnk 2:d0acbd263ec7 630 window(char_x, char_y,w,vert); // char box
frankvnk 2:d0acbd263ec7 631 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 632 _cs = 0;
frankvnk 2:d0acbd263ec7 633 wr_dat_start();
frankvnk 2:d0acbd263ec7 634 _spi.format(16,3);
frankvnk 2:d0acbd263ec7 635 for (j=0; j<vert; j++) // vert line
frankvnk 2:d0acbd263ec7 636 {
frankvnk 2:d0acbd263ec7 637 for (i=0; i<w; i++) // horz line
frankvnk 2:d0acbd263ec7 638 {
frankvnk 2:d0acbd263ec7 639 z = bitmap_char[bpl * i + ((j & 0xF8) >> 3)+1];
frankvnk 2:d0acbd263ec7 640 b = 1 << (j & 0x07);
frankvnk 2:d0acbd263ec7 641 if (( z & b ) == 0x00)
frankvnk 2:d0acbd263ec7 642 {
frankvnk 2:d0acbd263ec7 643 _spi.write(_background);
frankvnk 2:d0acbd263ec7 644 }
frankvnk 2:d0acbd263ec7 645 else
frankvnk 2:d0acbd263ec7 646 {
frankvnk 2:d0acbd263ec7 647 _spi.write(_foreground);
frankvnk 2:d0acbd263ec7 648 }
frankvnk 2:d0acbd263ec7 649 }
frankvnk 2:d0acbd263ec7 650 }
frankvnk 2:d0acbd263ec7 651 _spi.format(8,3);
frankvnk 2:d0acbd263ec7 652 _cs = 1;
frankvnk 2:d0acbd263ec7 653 if ((w + 2) < hor) // x offset to next char
frankvnk 2:d0acbd263ec7 654 {
frankvnk 2:d0acbd263ec7 655 char_x += w + 2;
frankvnk 2:d0acbd263ec7 656 }
frankvnk 2:d0acbd263ec7 657 else char_x += hor;
frankvnk 2:d0acbd263ec7 658 }
frankvnk 2:d0acbd263ec7 659
frankvnk 2:d0acbd263ec7 660 void SPI_TFT::set_font(unsigned char* f)
frankvnk 2:d0acbd263ec7 661 {
frankvnk 2:d0acbd263ec7 662 font = f;
frankvnk 2:d0acbd263ec7 663 }
frankvnk 2:d0acbd263ec7 664
frankvnk 2:d0acbd263ec7 665
frankvnk 2:d0acbd263ec7 666 void SPI_TFT::Bitmap(unsigned int x, unsigned int y, unsigned int w, unsigned int h,unsigned char *bitmap)
frankvnk 2:d0acbd263ec7 667 {
frankvnk 2:d0acbd263ec7 668 unsigned int i,j;
frankvnk 2:d0acbd263ec7 669 unsigned short *bitmap_ptr = (unsigned short *)bitmap;
frankvnk 2:d0acbd263ec7 670 mod_orientation();
frankvnk 2:d0acbd263ec7 671 window(x, y, w, h);
frankvnk 2:d0acbd263ec7 672 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 673 _cs = 0;
frankvnk 2:d0acbd263ec7 674 wr_dat_start();
frankvnk 2:d0acbd263ec7 675 _spi.format(16,3);
frankvnk 2:d0acbd263ec7 676 bitmap_ptr += ((h - 1)*w);
frankvnk 2:d0acbd263ec7 677 for (j = 0; j < h; j++) //Lines
frankvnk 2:d0acbd263ec7 678 {
frankvnk 2:d0acbd263ec7 679 for (i = 0; i < w; i++) // copy pixel data to TFT
frankvnk 2:d0acbd263ec7 680 {
frankvnk 2:d0acbd263ec7 681 _spi.write(*bitmap_ptr); // one line
frankvnk 2:d0acbd263ec7 682 bitmap_ptr++;
frankvnk 2:d0acbd263ec7 683 }
frankvnk 2:d0acbd263ec7 684 bitmap_ptr -= 2*w;
frankvnk 2:d0acbd263ec7 685 }
frankvnk 2:d0acbd263ec7 686 _spi.format(8,3);
frankvnk 2:d0acbd263ec7 687 _cs = 1;
frankvnk 2:d0acbd263ec7 688 }
frankvnk 2:d0acbd263ec7 689
frankvnk 2:d0acbd263ec7 690 int SPI_TFT::BMP_16(unsigned int x, unsigned int y, const char *Name_BMP)
frankvnk 2:d0acbd263ec7 691 {
frankvnk 2:d0acbd263ec7 692 /* // Current code unusable : Rewrite without DMA is needed
frankvnk 2:d0acbd263ec7 693 #define OffsetPixelWidth 18
frankvnk 2:d0acbd263ec7 694 #define OffsetPixelHeigh 22
frankvnk 2:d0acbd263ec7 695 #define OffsetFileSize 34
frankvnk 2:d0acbd263ec7 696 #define OffsetPixData 10
frankvnk 2:d0acbd263ec7 697 #define OffsetBPP 28
frankvnk 2:d0acbd263ec7 698
frankvnk 2:d0acbd263ec7 699 char filename[50];
frankvnk 2:d0acbd263ec7 700 unsigned char BMP_Header[54];
frankvnk 2:d0acbd263ec7 701 unsigned short BPP_t;
frankvnk 2:d0acbd263ec7 702 unsigned int PixelWidth,PixelHeigh,start_data;
frankvnk 2:d0acbd263ec7 703 unsigned int i,off;
frankvnk 2:d0acbd263ec7 704 int padd,j;
frankvnk 2:d0acbd263ec7 705 unsigned short *line;
frankvnk 2:d0acbd263ec7 706
frankvnk 2:d0acbd263ec7 707 // get the filename
frankvnk 2:d0acbd263ec7 708 LocalFileSystem local("local");
frankvnk 2:d0acbd263ec7 709 sprintf(&filename[0],"/local/");
frankvnk 2:d0acbd263ec7 710 i=7;
frankvnk 2:d0acbd263ec7 711 while (*Name_BMP!='\0') {
frankvnk 2:d0acbd263ec7 712 filename[i++]=*Name_BMP++;
frankvnk 2:d0acbd263ec7 713 }
frankvnk 2:d0acbd263ec7 714
frankvnk 2:d0acbd263ec7 715 fprintf(stderr, "filename : %s \n\r",filename);
frankvnk 2:d0acbd263ec7 716
frankvnk 2:d0acbd263ec7 717 FILE *Image = fopen((const char *)&filename[0], "rb"); // open the bmp file
frankvnk 2:d0acbd263ec7 718 if (!Image) {
frankvnk 2:d0acbd263ec7 719 return(0); // error file not found !
frankvnk 2:d0acbd263ec7 720 }
frankvnk 2:d0acbd263ec7 721
frankvnk 2:d0acbd263ec7 722 fread(&BMP_Header[0],1,54,Image); // get the BMP Header
frankvnk 2:d0acbd263ec7 723
frankvnk 2:d0acbd263ec7 724 if (BMP_Header[0] != 0x42 || BMP_Header[1] != 0x4D) { // check magic byte
frankvnk 2:d0acbd263ec7 725 fclose(Image);
frankvnk 2:d0acbd263ec7 726 return(-1); // error no BMP file
frankvnk 2:d0acbd263ec7 727 }
frankvnk 2:d0acbd263ec7 728
frankvnk 2:d0acbd263ec7 729 BPP_t = BMP_Header[OffsetBPP] + (BMP_Header[OffsetBPP + 1] << 8);
frankvnk 2:d0acbd263ec7 730 if (BPP_t != 0x0010) {
frankvnk 2:d0acbd263ec7 731 fclose(Image);
frankvnk 2:d0acbd263ec7 732 return(-2); // error no 16 bit BMP
frankvnk 2:d0acbd263ec7 733 }
frankvnk 2:d0acbd263ec7 734
frankvnk 2:d0acbd263ec7 735 PixelHeigh = BMP_Header[OffsetPixelHeigh] + (BMP_Header[OffsetPixelHeigh + 1] << 8) + (BMP_Header[OffsetPixelHeigh + 2] << 16) + (BMP_Header[OffsetPixelHeigh + 3] << 24);
frankvnk 2:d0acbd263ec7 736 PixelWidth = BMP_Header[OffsetPixelWidth] + (BMP_Header[OffsetPixelWidth + 1] << 8) + (BMP_Header[OffsetPixelWidth + 2] << 16) + (BMP_Header[OffsetPixelWidth + 3] << 24);
frankvnk 2:d0acbd263ec7 737 if (PixelHeigh > height() + y || PixelWidth > width() + x) {
frankvnk 2:d0acbd263ec7 738 fclose(Image);
frankvnk 2:d0acbd263ec7 739 return(-3); // to big
frankvnk 2:d0acbd263ec7 740 }
frankvnk 2:d0acbd263ec7 741
frankvnk 2:d0acbd263ec7 742 start_data = BMP_Header[OffsetPixData] + (BMP_Header[OffsetPixData + 1] << 8) + (BMP_Header[OffsetPixData + 2] << 16) + (BMP_Header[OffsetPixData + 3] << 24);
frankvnk 2:d0acbd263ec7 743
frankvnk 2:d0acbd263ec7 744 line = (unsigned short *) malloc (2 * PixelWidth); // we need a buffer for a line
frankvnk 2:d0acbd263ec7 745 if (line == NULL) {
frankvnk 2:d0acbd263ec7 746 return(-4); // error no memory
frankvnk 2:d0acbd263ec7 747 }
frankvnk 2:d0acbd263ec7 748
frankvnk 2:d0acbd263ec7 749 // the bmp lines are padded to multiple of 4 bytes
frankvnk 2:d0acbd263ec7 750 padd = -1;
frankvnk 2:d0acbd263ec7 751 do {
frankvnk 2:d0acbd263ec7 752 padd ++;
frankvnk 2:d0acbd263ec7 753 } while ((PixelWidth * 2 + padd)%4 != 0);
frankvnk 2:d0acbd263ec7 754
frankvnk 2:d0acbd263ec7 755
frankvnk 2:d0acbd263ec7 756 //fseek(Image, 70 ,SEEK_SET);
frankvnk 2:d0acbd263ec7 757 window(x, y,PixelWidth ,PixelHeigh);
frankvnk 2:d0acbd263ec7 758 wr_cmd(0x22);
frankvnk 2:d0acbd263ec7 759 _cs = 0;
frankvnk 2:d0acbd263ec7 760
frankvnk 2:d0acbd263ec7 761 if (spi_port == 0) { // TFT on SSP0
frankvnk 2:d0acbd263ec7 762 LPC_GPDMACH0->DMACCDestAddr = (uint32_t)&LPC_SSP0->DR; // we send to SSP0
frankvnk 2:d0acbd263ec7 763 // LPC_SSP0->CR0 &= ~(0x08UL); // set to 8 bit
frankvnk 2:d0acbd263ec7 764 LPC_SSP0->DR = 0x72; // start Data
frankvnk 2:d0acbd263ec7 765 LPC_SSP0->CR0 |= 0x08UL; // set to 16 bit
frankvnk 2:d0acbd263ec7 766 // Enable SSP0 for DMA.
frankvnk 2:d0acbd263ec7 767 LPC_SSP0->DMACR = 0x2;
frankvnk 2:d0acbd263ec7 768
frankvnk 2:d0acbd263ec7 769 } else {
frankvnk 2:d0acbd263ec7 770 LPC_GPDMACH0->DMACCDestAddr = (uint32_t)&LPC_SSP1->DR; // we send to SSP1
frankvnk 2:d0acbd263ec7 771 // LPC_SSP1->CR0 &= ~(0x08UL); // set to 8 bit
frankvnk 2:d0acbd263ec7 772 LPC_SSP1->DR = 0x72; // start Data
frankvnk 2:d0acbd263ec7 773 LPC_SSP1->CR0 |= 0x08UL; // set to 16 bit
frankvnk 2:d0acbd263ec7 774 // Enable SSP1 for DMA.
frankvnk 2:d0acbd263ec7 775 LPC_SSP1->DMACR = 0x2;
frankvnk 2:d0acbd263ec7 776 }
frankvnk 2:d0acbd263ec7 777 for (j = PixelHeigh - 1; j >= 0; j--) { //Lines bottom up
frankvnk 2:d0acbd263ec7 778 off = j * (PixelWidth * 2 + padd) + start_data; // start of line
frankvnk 2:d0acbd263ec7 779 fseek(Image, off ,SEEK_SET);
frankvnk 2:d0acbd263ec7 780 fread(line,1,PixelWidth * 2,Image); // read a line - slow !
frankvnk 2:d0acbd263ec7 781
frankvnk 2:d0acbd263ec7 782 LPC_GPDMA->DMACIntTCClear = 0x1;
frankvnk 2:d0acbd263ec7 783 LPC_GPDMA->DMACIntErrClr = 0x1;
frankvnk 2:d0acbd263ec7 784 LPC_GPDMACH0->DMACCSrcAddr = (uint32_t)line;
frankvnk 2:d0acbd263ec7 785 LPC_GPDMACH0->DMACCControl = PixelWidth | (0UL << 18) | (0UL << 21) | (1UL << 31) | DMA_CHANNEL_SRC_INC ; // 8 bit transfer , address increment, interrupt
frankvnk 2:d0acbd263ec7 786 LPC_GPDMACH0->DMACCConfig = DMA_CHANNEL_ENABLE | DMA_TRANSFER_TYPE_M2P | (spi_port ? DMA_DEST_SSP1_TX : DMA_DEST_SSP0_TX);
frankvnk 2:d0acbd263ec7 787 LPC_GPDMA->DMACSoftSReq = 0x1;
frankvnk 2:d0acbd263ec7 788 do {
frankvnk 2:d0acbd263ec7 789 } while ((LPC_GPDMA->DMACRawIntTCStat & 0x01) == 0); // DMA is running
frankvnk 2:d0acbd263ec7 790
frankvnk 2:d0acbd263ec7 791 }
frankvnk 2:d0acbd263ec7 792
frankvnk 2:d0acbd263ec7 793 if (spi_port == 0) { // TFT on SSP0
frankvnk 2:d0acbd263ec7 794 do {
frankvnk 2:d0acbd263ec7 795 } while ((LPC_SSP0->SR & 0x10) == 0x10); // SPI FIFO not empty
frankvnk 2:d0acbd263ec7 796 LPC_SSP0->CR0 &= ~(0x08UL); // set to 8 bit
frankvnk 2:d0acbd263ec7 797 } else {
frankvnk 2:d0acbd263ec7 798 do {
frankvnk 2:d0acbd263ec7 799 } while ((LPC_SSP1->SR & 0x10) == 0x10); // SPI FIFO not empty
frankvnk 2:d0acbd263ec7 800 LPC_SSP1->CR0 |= 0x08UL; // set to 16 bit
frankvnk 2:d0acbd263ec7 801 }
frankvnk 2:d0acbd263ec7 802 _cs = 1;
frankvnk 2:d0acbd263ec7 803 free (line);
frankvnk 2:d0acbd263ec7 804 fclose(Image);
frankvnk 2:d0acbd263ec7 805 WindowMax();
frankvnk 2:d0acbd263ec7 806 */
frankvnk 2:d0acbd263ec7 807 return(1);
frankvnk 2:d0acbd263ec7 808 }