2020-01-02 14:48:01 +11:00
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#include <string.h>
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#include "t6a04.h"
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void t6a04_init(T6A04 *lcd)
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{
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memset(lcd->ram, 0, T6A04_RAMSIZE);
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lcd->enabled = false;
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lcd->incmode = T6A04_XINC;
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lcd->offset = 0;
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lcd->currow = 0;
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lcd->curcol = 0;
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lcd->just_moved = true;
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2020-05-08 23:07:44 +10:00
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lcd->has8bitmode = false;
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2020-01-02 14:48:01 +11:00
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}
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uint8_t t6a04_cmd_rd(T6A04 *lcd)
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{
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return 0; // we are always ready for a new cmd
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}
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/*
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* 0x00/0x01: 6/8 bit mode
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* 0x02/0x03: enable/disable
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* 0x04-0x07: incmodes
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* 0x20-0x34: set col
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* 0x40-0x7f: set Z offset
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* 0x80-0xbf: set row
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* 0xc0-0xff: set contrast
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*/
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void t6a04_cmd_wr(T6A04 *lcd, uint8_t val)
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{
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if ((val & 0xc0) == 0xc0) {
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// contrast, ignoring
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} else if (val & 0x80) {
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lcd->currow = val & 0x3f;
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lcd->just_moved = true;
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} else if (val & 0x40) {
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lcd->offset = val & 0x3f;
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} else if (val & 0x20) {
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lcd->curcol = val & 0x1f;
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lcd->just_moved = true;
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} else if (val & 0x18) {
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// stuff we don't emulate
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} else if (val & 0x04) {
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lcd->incmode = val & 0x03;
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} else if (val & 0x02) {
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lcd->enabled = val & 0x01;
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} else {
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lcd->has8bitmode = val;
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}
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}
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// Advance current position according to current incmode
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static void _advance(T6A04 *lcd)
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{
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uint8_t maxY = lcd->has8bitmode ? 14 : 19;
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switch (lcd->incmode) {
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case T6A04_XDEC:
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lcd->currow = (lcd->currow-1) & 0x3f;
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break;
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case T6A04_XINC:
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lcd->currow = (lcd->currow+1) & 0x3f;
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break;
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case T6A04_YDEC:
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if (lcd->curcol == 0) {
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lcd->curcol = maxY;
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} else {
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lcd->curcol--;
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}
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break;
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case T6A04_YINC:
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if (lcd->curcol < maxY) {
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lcd->curcol++;
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} else {
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lcd->curcol = 0;
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}
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break;
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}
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}
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uint8_t t6a04_data_rd(T6A04 *lcd)
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{
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uint8_t res;
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if (lcd->just_moved) {
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// After a move command, the first read op is a noop.
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lcd->just_moved = false;
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return 0;
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}
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if (lcd->has8bitmode) {
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int pos = lcd->currow * T6A04_ROWSIZE + lcd->curcol;
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res = lcd->ram[pos];
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} else {
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// 6bit mode is a bit more complicated because the 6-bit number often
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// spans two bytes. We manage this by loading two bytes into a uint16_t
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// and then shift it right properly.
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// bitpos represents the leftmost bit of our 6bit number.
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int bitpos = lcd->curcol * 6;
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// offset represents the shift right we need to perform from the two
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// bytes following bitpos/8 so that we can have our number with a 6-bit
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// mask.
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// Example, col 3 has a bitpos of 18, which means that it loads bytes 2
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// and 3. Its bits would be in bit pos 14:8, which means it has an
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// offset of 8. There is always an offset and its always in the 3-10
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// range
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int offset = 10 - (bitpos % 8); // 10 is for 16bit - 6bit
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int pos = (lcd->currow * T6A04_ROWSIZE) + (bitpos / 8);
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uint16_t word = lcd->ram[pos] << 8;
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word |= lcd->ram[pos+1];
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res = (word >> offset) & 0x3f;
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}
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_advance(lcd);
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return res;
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}
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void t6a04_data_wr(T6A04 *lcd, uint8_t val)
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{
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lcd->just_moved = false;
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if (lcd->has8bitmode) {
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int pos = lcd->currow * T6A04_ROWSIZE + lcd->curcol;
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lcd->ram[pos] = val;
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} else {
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// See comments in t6a04_data_rd().
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int bitpos = lcd->curcol * 6;
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int offset = 10 - (bitpos % 8);
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int pos = (lcd->currow * T6A04_ROWSIZE) + (bitpos / 8);
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uint16_t word = lcd->ram[pos] << 8;
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word |= lcd->ram[pos+1];
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// word contains our current ram value. Let's fit val in this.
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word &= ~(0x003f << offset);
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word |= val << offset;
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lcd->ram[pos] = word >> 8;
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lcd->ram[pos+1] = word & 0xff;
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}
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_advance(lcd);
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}
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bool t6a04_pixel(T6A04 *lcd, uint8_t y, uint8_t x)
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{
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x = (x + lcd->offset) & 0x3f;
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uint8_t val = lcd->ram[x * T6A04_ROWSIZE + (y / 8)];
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return (val >> (7 - (y % 8))) & 1;
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}
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