/* * GraphLCD driver library * * avrctl.c - AVR controlled LCD driver class * * This file is released under the GNU General Public License. Refer * to the COPYING file distributed with this package. * * (c) 2005-2010 Andreas Regel * (c) 2011 Wolfgang Astleitner */ #include #include #include #include "common.h" #include "config.h" #include "port.h" #include "avrctl.h" namespace GLCD { /* command header: ** 8 bits sync byte (0xAA for sent commands, 0x55 for received commands) ** 8 bits command id ** 16 bits command length (excluding header) */ const unsigned char CMD_HDR_SYNC = 0; const unsigned char CMD_HDR_COMMAND = 1; const unsigned char CMD_HDR_LENGTH = 2; const unsigned char CMD_DATA_START = 4; const unsigned char CMD_SYNC_SEND = 0xAA; const unsigned char CMD_SYNC_RECV = 0x55; const unsigned char CMD_SYS_SYNC = 0x00; const unsigned char CMD_SYS_ACK = 0x01; const unsigned char CMD_DISP_CLEAR_SCREEN = 0x10; const unsigned char CMD_DISP_SWITCH_SCREEN = 0x11; const unsigned char CMD_DISP_SET_BRIGHTNESS = 0x12; const unsigned char CMD_DISP_SET_COL_DATA = 0x13; const unsigned char CMD_DISP_SET_ROW_DATA = 0x14; const unsigned char CMD_DISP_UPDATE = 0x15; const int kBufferWidth = 256; const int kBufferHeight = 128; cDriverAvrCtl::cDriverAvrCtl(cDriverConfig * config) : config(config) { oldConfig = new cDriverConfig(*config); port = new cSerialPort(); //width = config->width; //height = config->height; refreshCounter = 0; } cDriverAvrCtl::~cDriverAvrCtl() { delete port; delete oldConfig; } int cDriverAvrCtl::Init() { int x; width = config->width; if (width <= 0) width = 256; height = config->height; if (height <= 0) height = 128; for (unsigned int i = 0; i < config->options.size(); i++) { if (config->options[i].name == "") { } } // setup lcd array (wanted state) newLCD = new unsigned char*[kBufferWidth]; if (newLCD) { for (x = 0; x < kBufferWidth; x++) { newLCD[x] = new unsigned char[(kBufferHeight + 7) / 8]; memset(newLCD[x], 0, (kBufferHeight + 7) / 8); } } // setup lcd array (current state) oldLCD = new unsigned char*[kBufferWidth]; if (oldLCD) { for (x = 0; x < kBufferWidth; x++) { oldLCD[x] = new unsigned char[(kBufferHeight + 7) / 8]; memset(oldLCD[x], 0, (kBufferHeight + 7) / 8); } } if (config->device == "") { return -1; } if (port->Open(config->device.c_str()) != 0) return -1; *oldConfig = *config; // clear display Clear(); syslog(LOG_INFO, "%s: AvrCtl initialized.\n", config->name.c_str()); return 0; } int cDriverAvrCtl::DeInit() { int x; // free lcd array (wanted state) if (newLCD) { for (x = 0; x < kBufferWidth; x++) { delete[] newLCD[x]; } delete[] newLCD; } // free lcd array (current state) if (oldLCD) { for (x = 0; x < kBufferWidth; x++) { delete[] oldLCD[x]; } delete[] oldLCD; } if (port->Close() != 0) return -1; return 0; } int cDriverAvrCtl::CheckSetup() { if (config->device != oldConfig->device || config->width != oldConfig->width || config->height != oldConfig->height) { DeInit(); Init(); return 0; } if (config->upsideDown != oldConfig->upsideDown || config->invert != oldConfig->invert) { oldConfig->upsideDown = config->upsideDown; oldConfig->invert = config->invert; return 1; } return 0; } void cDriverAvrCtl::Clear() { for (int x = 0; x < kBufferWidth; x++) memset(newLCD[x], 0, (kBufferHeight + 7) / 8); } void cDriverAvrCtl::SetPixel(int x, int y, uint32_t data) { if (x >= width || y >= height) return; if (config->upsideDown) { x = width - 1 - x; y = height - 1 - y; } int offset = 7 - (y % 8); if (data == GLCD::cColor::White) newLCD[x][y / 8] |= (1 << offset); else newLCD[x][y / 8] &= ( 0xFF ^ (1 << offset) ); } #if 0 void cDriverAvrCtl::Set8Pixels(int x, int y, unsigned char data) { if (x >= width || y >= height) return; if (!config->upsideDown) { int offset = 7 - (y % 8); for (int i = 0; i < 8; i++) { newLCD[x + i][y / 8] |= ((data >> (7 - i)) << offset) & (1 << offset); } } else { x = width - 1 - x; y = height - 1 - y; int offset = 7 - (y % 8); for (int i = 0; i < 8; i++) { newLCD[x - i][y / 8] |= ((data >> (7 - i)) << offset) & (1 << offset); } } } #endif void cDriverAvrCtl::Refresh(bool refreshAll) { int x; int y; int i; int num = kBufferWidth / 2; unsigned char data[16*num]; if (CheckSetup() == 1) refreshAll = true; if (config->refreshDisplay > 0) { refreshCounter = (refreshCounter + 1) % config->refreshDisplay; if (!refreshAll && !refreshCounter) refreshAll = true; } refreshAll = true; if (refreshAll) { for (x = 0; x < kBufferWidth; x += num) { for (i = 0; i < num; i++) { for (y = 0; y < (kBufferHeight + 7) / 8; y++) { data[i * ((kBufferHeight + 7) / 8) + y] = (newLCD[x + i][y]) ^ (config->invert ? 0xff : 0x00); } memcpy(oldLCD[x + i], newLCD[x + i], (kBufferHeight + 7) / 8); } CmdDispSetColData(x, 0, 16 * num, data); } CmdDispUpdate(); CmdDispSwitchScreen(); // and reset RefreshCounter refreshCounter = 0; } else { // draw only the changed bytes } } void cDriverAvrCtl::SetBrightness(unsigned int percent) { CmdDispSetBrightness(percent); } int cDriverAvrCtl::WaitForAck(void) { uint8_t cmd[4]; int len; int timeout = 10000; len = 0; while (len < 4 && timeout > 0) { len += port->ReadData(&cmd[len]); timeout--; } if (timeout == 0) return 0; return 1; } void cDriverAvrCtl::CmdSysSync(void) { uint8_t cmd[4]; cmd[CMD_HDR_SYNC] = CMD_SYNC_SEND; cmd[CMD_HDR_COMMAND] = CMD_SYS_SYNC; cmd[CMD_HDR_LENGTH] = 0; cmd[CMD_HDR_LENGTH+1] = 0; port->WriteData(cmd, 4); WaitForAck(); } void cDriverAvrCtl::CmdDispClearScreen(void) { uint8_t cmd[4]; cmd[CMD_HDR_SYNC] = CMD_SYNC_SEND; cmd[CMD_HDR_COMMAND] = CMD_DISP_CLEAR_SCREEN; cmd[CMD_HDR_LENGTH] = 0; cmd[CMD_HDR_LENGTH+1] = 0; port->WriteData(cmd, 4); WaitForAck(); } void cDriverAvrCtl::CmdDispSwitchScreen(void) { uint8_t cmd[4]; cmd[CMD_HDR_SYNC] = CMD_SYNC_SEND; cmd[CMD_HDR_COMMAND] = CMD_DISP_SWITCH_SCREEN; cmd[CMD_HDR_LENGTH] = 0; cmd[CMD_HDR_LENGTH+1] = 0; port->WriteData(cmd, 4); WaitForAck(); } void cDriverAvrCtl::CmdDispSetBrightness(uint8_t percent) { uint8_t cmd[5]; cmd[CMD_HDR_SYNC] = CMD_SYNC_SEND; cmd[CMD_HDR_COMMAND] = CMD_DISP_SET_BRIGHTNESS; cmd[CMD_HDR_LENGTH] = 0; cmd[CMD_HDR_LENGTH+1] = 1; cmd[CMD_DATA_START] = percent; port->WriteData(cmd, 5); WaitForAck(); } void cDriverAvrCtl::CmdDispSetColData(uint16_t column, uint16_t offset, uint16_t length, uint8_t * data) { uint8_t cmd[2560]; cmd[CMD_HDR_SYNC] = CMD_SYNC_SEND; cmd[CMD_HDR_COMMAND] = CMD_DISP_SET_COL_DATA; cmd[CMD_HDR_LENGTH] = (length + 6) >> 8; cmd[CMD_HDR_LENGTH+1] = (length + 6); cmd[CMD_DATA_START] = column >> 8; cmd[CMD_DATA_START+1] = column; cmd[CMD_DATA_START+2] = offset >> 8; cmd[CMD_DATA_START+3] = offset; cmd[CMD_DATA_START+4] = length >> 8; cmd[CMD_DATA_START+5] = length; memcpy(&cmd[CMD_DATA_START+6], data, length); port->WriteData(cmd, length+10); WaitForAck(); } void cDriverAvrCtl::CmdDispUpdate(void) { uint8_t cmd[4]; cmd[CMD_HDR_SYNC] = CMD_SYNC_SEND; cmd[CMD_HDR_COMMAND] = CMD_DISP_UPDATE; cmd[CMD_HDR_LENGTH] = 0; cmd[CMD_HDR_LENGTH+1] = 0; port->WriteData(cmd, 4); WaitForAck(); } }