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https://github.com/JorjBauer/aiie.git
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127 lines
3.2 KiB
C++
127 lines
3.2 KiB
C++
#include <string.h> // memset
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#include <TimeLib.h>
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#include "teensy-clock.h"
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#include "applemmu.h" // for FLOATING
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/*
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* http://apple2online.com/web_documents/prodos_technical_notes.pdf
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*
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* When ProDOS calls a clock card, the card deposits an ASCII string
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* in the GETLN input buffer in the form: 07,04,14,22,46,57. The
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* string translates as the following:
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*
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* 07 = the month, July
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* 04 = the day of the week (00 = Sun)
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* 14 = the date (00 to 31)
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* 22 = the hour (00 to 23)
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* 46 = the minute (00 to 59)
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* 57 = the second (00 to 59)
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*/
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static void timeToProDOS(uint16_t year, uint8_t month, uint8_t day, uint8_t hour, uint8_t minute,
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uint8_t proDOStimeOut[4])
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{
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proDOStimeOut[0] = ((year % 100) << 1) | (month >> 3);
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proDOStimeOut[1] = ((month & 0x0F) << 5) | (day & 0x1F);
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proDOStimeOut[2] = hour & 0x1F;
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proDOStimeOut[3] = minute & 0x3F;
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}
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TeensyClock::TeensyClock(AppleMMU *mmu)
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{
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this->mmu = mmu;
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}
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TeensyClock::~TeensyClock()
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{
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}
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void TeensyClock::Reset()
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{
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}
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uint8_t TeensyClock::readSwitches(uint8_t s)
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{
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// When any switch is read, we'll put the current time in the prodos time buffer
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tmElements_t tm;
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breakTime(now(), tm);
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// Put the date/time in the official ProDOS buffer
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uint8_t prodosOut[4];
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timeToProDOS(tm.Year, tm.Month, tm.Day, tm.Hour, tm.Minute, prodosOut);
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mmu->write(0xBF90, prodosOut[0]);
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mmu->write(0xBF91, prodosOut[1]);
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mmu->write(0xBF92, prodosOut[2]);
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mmu->write(0xBF93, prodosOut[3]);
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// and also generate a date/time that contains seconds, but not a
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// year, which it also consumes
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char ts[18];
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sprintf(ts, "%.2d,%.2d,%.2d,%.2d,%.2d,%.2d",
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tm.Month,
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tm.Wday - 1, // Sunday should be 0, not 1
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tm.Day,
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tm.Hour,
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tm.Minute,
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tm.Second);
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uint8_t i = 0;
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while (ts[i]) {
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mmu->write(0x200 + i, ts[i] | 0x80);
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i++;
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}
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return FLOATING;
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}
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void TeensyClock::writeSwitches(uint8_t s, uint8_t v)
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{
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// printf("unimplemented write to the clock - 0x%X\n", v);
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}
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// FIXME: this assumes slot #7
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void TeensyClock::loadROM(uint8_t *toWhere)
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{
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memset(toWhere, 0xEA, 256); // fill the page with NOPs
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// ProDOS only needs these 4 bytes to recognize that a clock is present
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toWhere[0x00] = 0x08; // PHP
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toWhere[0x02] = 0x28; // PLP
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toWhere[0x04] = 0x58; // CLI
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toWhere[0x06] = 0x70; // BVS
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// Pad out those bytes so they will return control well. The program
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// at c700 becomes
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//
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// C700: PHP ; push to stack
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// NOP ; filler (filled in by memory clear)
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// PLP ; pop from stack
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// RTS ; return
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// CLI ; required to detect driver, but not used
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// NOP ; filled in by memory clear
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// BVS ; required to detect driver, but not used
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toWhere[0x03] = 0x60; // RTS
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// And it needs a small routing here to read/write it:
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// 0x08: read
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toWhere[0x08] = 0x4C; // JMP $C710
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toWhere[0x09] = 0x10;
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toWhere[0x0A] = 0xC7;
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// 0x0b: write
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toWhere[0x0B] = 0x8D; // STA $C0F0 (slot 7's first switch)
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toWhere[0x0C] = 0xF0;
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toWhere[0x0D] = 0xC0;
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toWhere[0x0E] = 0x60; // RTS
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// simple read
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toWhere[0x10] = 0xAD; // LDA $C0F0 (slot 7's first switch)
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toWhere[0x11] = 0xF0;
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toWhere[0x12] = 0xC0;
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toWhere[0x13] = 0x60; // RTS
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}
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