rockbox/apps/plugins/alpine_cdc.c

1205 lines
35 KiB
C

/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
*
* Copyright (C) 2003-2005 Jörg Hohensohn
*
* Alpine CD changer Project
* This is a feasibility study for Archos emulating an Alpine M-Bus CD changer.
*
* Currently it will do seeks and change tracks, but nothing like disks.
* The debug version shows a dump of the M-Bus communication on screen.
*
* Usage: Start plugin, it will stay in the background and do the emulation.
* You need to make an adapter with an 8-pin DIN plug for the radio at one end
* and a 4-ring 3.5 mm plug for the Archos headphone jack at the other.
* The Archos remote pin connects to the M-Bus, audio as usual.
*
* All files in this archive are subject to the GNU General Public License.
* See the file COPYING in the source tree root for full license agreement.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include "plugin.h"
/* Only build for (correct) target */
#if !defined(SIMULATOR) && CONFIG_CPU==SH7034 && !defined(HAVE_MMC)
PLUGIN_HEADER
#ifdef HAVE_LCD_CHARCELLS /* player model */
#define LINES 2
#define COLUMNS 11
#else /* recorder models */
#define LINES 8
#define COLUMNS 32 /* can't really tell for proportional font */
#endif
/****************** imports ******************/
#include "sh7034.h"
#include "system.h"
/****************** constants ******************/
/* measured bit time on the M-Bus is 3.075 ms = 325.2 Hz */
#define MBUS_BAUDRATE 3252 /* make it 10 * bittime */
#define MBUS_STEP_FREQ (MBUS_BAUDRATE/2) /* 5 steps per bit */
#define MBUS_BIT_FREQ (MBUS_BAUDRATE/10) /* the true bit frequency again */
#define MBUS_MAX_SIZE 16 /* maximum length of an M-Bus packet, incl. checksum */
#define MBUS_RCV_QUEUESIZE 4 /* how many packets can be queued by receiver */
#define ERI1 (*((volatile unsigned long*)0x090001A0)) /* RX error */
#define RXI1 (*((volatile unsigned long*)0x090001A4)) /* RX */
#define PB10 0x0400
/* receive status */
#define RX_BUSY 0 /* reception in progress */
#define RX_RECEIVED 1 /* valid data available */
#define RX_FRAMING 2 /* frame error */
#define RX_OVERRUN 3 /* receiver overrun */
#define RX_PARITY 4 /* parity error */
#define RX_SYMBOL 5 /* invalid bit timing */
#define RX_OVERFLOW 6 /* buffer full */
#define RX_OVERLAP 7 /* receive interrupt while transmitting */
/* timer operation mode */
#define TM_OFF 0 /* not in use */
#define TM_TRANSMIT 1 /* periodic timer to transmit */
#define TM_RX_TIMEOUT 2 /* single shot for receive timeout */
/* emulation play state */
#define EMU_IDLE 0
#define EMU_PREPARING 1
#define EMU_STOPPED 2
#define EMU_PAUSED 3
#define EMU_PLAYING 4
#define EMU_SPINUP 5
#define EMU_FF 6
#define EMU_FR 7
/****************** prototypes ******************/
void timer_init(unsigned hz, unsigned to); /* setup static timer registers and values */
void timer_set_mode(int mode); /* define for what the timer should be used right now */
void timer4_isr(void); /* IMIA4 ISR */
void transmit_isr(void); /* 2nd level ISR for M-Bus transmission */
void uart_init(unsigned baudrate); /* UART setup */
void uart_rx_isr(void) __attribute__((interrupt_handler)); /* RXI1 ISR */
void uart_err_isr(void) __attribute__((interrupt_handler)); /* ERI1 ISR */
void receive_timeout_isr(void); /* 2nd level ISR for receiver timeout */
void mbus_init(void); /* prepare the M-Bus layer */
int mbus_send(unsigned char* p_msg, int digits); /* packet send */
int mbus_receive(unsigned char* p_msg, unsigned bufsize, int timeout); /* packet receive */
unsigned char calc_checksum(unsigned char* p_msg, int digits); /* make M-Bus checksum */
bool bit_test(unsigned char* buf, unsigned bit); /* test one bit of M-Bus packet */
void bit_set(unsigned char* buf, unsigned bit, bool val); /* set/clear one bit of M-Bus packet */
void print_scroll(char* string); /* implements a scrolling screen */
void dump_packet(char* dest, int dst_size, char* src, int n); /* convert packet to ASCII */
void emu_init(void); /* init changer emulation */
void emu_process_packet(unsigned char* mbus_msg, int msg_size); /* feed a received radio packet */
void emu_tick(void); /* for regular actions of the emulator */
int get_playtime(void); /* return the current track time in seconds */
int get_tracklength(void); /* return the total length of the current track */
void set_track(int selected);
int get_track(void); /* return the track number */
void set_play(void); /* start or resume playback */
void set_pause(void); /* pause playback */
void set_stop(void); /* stop playback */
void set_position(int seconds); /* seek */
void get_playmsg(void); /* update the play message with Rockbox info */
void get_diskmsg(void); /* update the disk status message with Rockbox info */
void sound_neutral(void); /* set to everything flat and 0 dB volume */
void sound_normal(void); /* return to user settings */
void thread(void); /* the thread running it all */
int main(void* parameter); /* main loop */
enum plugin_status plugin_start(struct plugin_api* api, void* parameter); /* entry */
/****************** data types ******************/
/* one entry in the receive queue */
typedef struct
{
unsigned char buf[MBUS_MAX_SIZE]; /* message buffer */
unsigned size; /* length of data in the buffer */
unsigned error; /* error code from reception */
} t_rcv_queue_entry;
/****************** globals ******************/
/* information owned by the timer transmit ISR */
struct
{
unsigned char send_buf[MBUS_MAX_SIZE]; /* M-Bus message */
unsigned send_size; /* current length of data in the buffer */
unsigned index; /* index for which byte to send */
unsigned byte; /* which byte to send */
unsigned bitmask; /* which bit to send */
unsigned step; /* where in the pulse are we */
bool bit; /* currently sent bit */
bool collision; /* set if a collision happened */
bool busy; /* flag if in transmission */
} gSendIRQ;
/* information owned by the UART receive ISR */
struct
{
t_rcv_queue_entry queue[MBUS_RCV_QUEUESIZE]; /* M-Bus message queue */
unsigned buf_read; /* readout maintained by the user application */
unsigned buf_write; /* writing maintained by ISR */
bool overflow; /* indicate queue overflow */
unsigned byte; /* currently assembled byte */
unsigned bit; /* which bit to receive */
} gRcvIRQ;
/* information owned by the timer */
struct
{
unsigned mode; /* off, transmit, receive timout */
unsigned transmit; /* value for transmit */
unsigned timeout; /* value for receive timeout */
} gTimer;
/* information owned by the changer emulation */
struct
{
unsigned char playmsg[15]; /* current play state msg */
unsigned char changemsg[11]; /* changing message */
unsigned char diskmsg[12]; /* disk status message */
long poll_interval; /* call the emu each n ticks */
int time; /* seconds within the song */
int set_state; /* the desired state to change into */
} gEmu;
/* communication to the worker thread */
struct
{
bool foreground; /* set as long as we're owning the UI */
bool exiting; /* signal to the thread that we want to exit */
bool ended; /* response from the thread, that is has exited */
} gTread;
static struct plugin_api* rb; /* here is the global API struct pointer */
/****************** implementation ******************/
/* setup static timer registers and values */
void timer_init(unsigned hz, unsigned to)
{
rb->memset(&gTimer, 0, sizeof(gTimer));
gTimer.transmit = TIMER_FREQ / hz; /* time for bit transitions */
gTimer.timeout = TIMER_FREQ / to; /* time for receive timeout */
}
/* define for what the timer should be used right now */
void timer_set_mode(int mode)
{
TCNT4 = 0; /* start counting at 0 */
gTimer.mode = mode; /* store the mode */
if (mode == TM_RX_TIMEOUT)
{
rb->timer_register(1, NULL, gTimer.timeout, 11, timer4_isr);
}
else if (mode == TM_TRANSMIT)
{
rb->timer_register(1, NULL, gTimer.transmit, 14, timer4_isr);
}
else
{
rb->timer_unregister();
}
}
void timer4_isr(void) /* IMIA4 */
{
switch (gTimer.mode)
{ /* distribute the interrupt */
case TM_TRANSMIT:
transmit_isr();
break;
case TM_RX_TIMEOUT:
receive_timeout_isr();
rb->timer_unregister(); /* single shot */
break;
default:
timer_set_mode(TM_OFF); /* spurious interrupt */
} /* switch */
}
/* About Alpine M-Bus
* ------------------
*
* The protocol uses a single wire in half duplex mode.
* A bit like I2C, this wire is either pulled low or left floating high.
* Bit time is ~3 ms, a "zero" is coded as ~0.6 ms low, a "one" as ~1.8 ms low.
* Nice to view in a 0.6 ms grid:
*
* 0 0.6 1.2 1.8 2.4 3.0
* | | | | | |
* __ ___________________
* \____/ \ "zero" bit
* __ _________
* \______________/ \ "one" bit
*
* So I send out the data in a timer interrupt spawned to 0.6 ms.
* In phases where the line is floating high, I can check for collisions.
* (happens if the other side driving it low, too.)
*
* Data is transmitted in multiples of 4 bit, to ease BCD representation.
*/
/* 2nd level ISR for M-Bus transmission */
void transmit_isr(void)
{
bool exit = false;
TSR4 &= ~0x01; /* clear the interrupt */
switch(gSendIRQ.step++)
{
case 0:
and_b(~0x04, &PBDRH); /* low (read-modify-write access may have changed it while it was input) */
or_b(0x04, &PBIORH); /* drive low (output) */
break;
case 1: /* 0.6 ms */
if (!gSendIRQ.bit) /* sending "zero"? */
and_b(~0x04, &PBIORH); /* float (input) */
break;
case 2: /* 1.2 ms */
if (!gSendIRQ.bit && ((PBDR & PB10) == 0))
gSendIRQ.collision = true;
break;
case 3: /* 1.8 ms */
if (gSendIRQ.bit) /* sending "one"? */
and_b(~0x04, &PBIORH); /* float (input) */
else if ((PBDR & PB10) == 0)
gSendIRQ.collision = true;
break;
case 4: /* 2.4 ms */
if ((PBDR & PB10) == 0)
gSendIRQ.collision = true;
/* prepare next round */
gSendIRQ.step = 0;
gSendIRQ.bitmask >>= 1;
if (gSendIRQ.bitmask)
{ /* new bit */
gSendIRQ.bit = (gSendIRQ.byte & gSendIRQ.bitmask) != 0;
}
else
{ /* new byte */
if (++gSendIRQ.index < gSendIRQ.send_size)
{
gSendIRQ.bitmask = 0x08;
gSendIRQ.byte = gSendIRQ.send_buf[gSendIRQ.index];
gSendIRQ.bit = (gSendIRQ.byte & gSendIRQ.bitmask) != 0;
}
else
exit = true; /* done */
}
break;
}
if (exit || gSendIRQ.collision)
{ /* stop transmission */
or_b(0x20, PBCR1_ADDR+1); /* RxD1 again for PB10 */
timer_set_mode(TM_OFF); /* stop the timer */
gSendIRQ.busy = false; /* do this last, to avoid race conditions */
}
}
/* For receiving, I use the "normal" serial RX feature of the CPU,
* so we can receive within an interrupt, no line polling necessary.
* Luckily, the M-Bus bit always starts with a falling edge and ends with a high,
* this matches with the start bit and the stop bit of a serial transmission.
* The baudrate is set such that the M-Bus bit time (ca. 3ms) matches
* the serial reception time of one byte, so we receive one byte per
* M-Bus bit.
* Start bit, 8 data bits and stop bit (total=10) nicely fall into the 5
* phases like above:
*
* 0 0.6 1.2 1.8 2.4 3.0 ms
* | | | | | | time
* __ _______________________________
* \_______/ \ "zero" bit
* __ _______________
* \_______________________/ \ "one" bit
*
* | | | | | | | | | | | serial sampling interval
* Start 0 1 2 3 4 5 6 7 Stop bit (LSB first!)
*
* By looking at the bit pattern in the serial byte we can distinguish
* the short low from the longer low, tell "zero" and "one" apart.
* So we receive 0xFE for a "zero", 0xE0 for a "one".
* It may be necessary to treat the bits next to transitions as don't care,
* in case the timing is not so accurate.
* Bits are always sent "back-to-back", so I detect the packet end by timeout.
*/
void uart_init(unsigned baudrate)
{
RXI1 = (unsigned long)uart_rx_isr; /* install ISR */
ERI1 = (unsigned long)uart_err_isr; /* install ISR */
SCR1 = 0x00; /* disable everything; select async mode with SCK pin as I/O */
SMR1 = 0x00; /* async, 8N1, NoMultiProc, sysclock/1 */
BRR1 = ((FREQ/(32*baudrate))-1);
IPRE = (IPRE & ~0xf000) | 0xc000; /* interrupt on level 12 */
rb->sleep(1); /* hardware needs to settle for at least one bit interval */
and_b(~(SCI_RDRF | SCI_ORER | SCI_FER | SCI_PER), &SSR1); /* clear any receiver flag */
or_b(SCI_RE | SCI_RIE , &SCR1); /* enable the receiver with interrupt */
}
void uart_rx_isr(void) /* RXI1 */
{
unsigned char data;
t_rcv_queue_entry* p_entry = &gRcvIRQ.queue[gRcvIRQ.buf_write]; /* short cut */
data = RDR1; /* get data */
and_b(~SCI_RDRF, &SSR1); /* clear data received flag */
if (gTimer.mode == TM_TRANSMIT)
p_entry->error = RX_OVERLAP; /* oops, we're also transmitting, stop */
else
timer_set_mode(TM_RX_TIMEOUT); /* (re)spawn timeout */
if (p_entry->error != RX_BUSY)
return;
if ((data & ~0x00) == 0xFE) /* 01111111 in line order (reverse) */
{ /* "zero" received */
gRcvIRQ.byte <<= 1;
}
else if ((data & ~0x00) == 0xE0) /* 00000111 in line order (reverse) */
{ /* "one" received */
gRcvIRQ.byte = gRcvIRQ.byte << 1 | 0x01;
}
else
{ /* unrecognized pulse */
p_entry->error = RX_SYMBOL;
}
if (p_entry->error == RX_BUSY)
{
if (++gRcvIRQ.bit >= 4)
{ /* byte completed */
if (p_entry->size >= sizeof(p_entry->buf))
{
p_entry->error = RX_OVERFLOW; /* buffer full */
}
else
{
p_entry->buf[p_entry->size] = gRcvIRQ.byte;
gRcvIRQ.byte = 0;
gRcvIRQ.bit = 0;
p_entry->size++;
}
}
}
}
void uart_err_isr(void) /* ERI1 */
{
t_rcv_queue_entry* p_entry = &gRcvIRQ.queue[gRcvIRQ.buf_write]; /* short cut */
if (p_entry->error == RX_BUSY)
{ /* terminate reception in case of error */
if (SSR1 & SCI_FER)
p_entry->error = RX_FRAMING;
else if (SSR1 & SCI_ORER)
p_entry->error = RX_OVERRUN;
else if (SSR1 & SCI_PER)
p_entry->error = RX_PARITY;
}
/* clear any receiver flag */
and_b(~(SCI_RDRF | SCI_ORER | SCI_FER | SCI_PER), &SSR1);
}
/* 2nd level ISR for receiver timeout, this finalizes reception */
void receive_timeout_isr(void)
{
t_rcv_queue_entry* p_entry = &gRcvIRQ.queue[gRcvIRQ.buf_write]; /* short cut */
timer_set_mode(TM_OFF); /* single shot */
if (p_entry->error == RX_BUSY) /* everthing OK so far? */
p_entry->error = RX_RECEIVED; /* end with valid data */
/* move to next queue entry */
gRcvIRQ.buf_write++;
if (gRcvIRQ.buf_write >= MBUS_RCV_QUEUESIZE)
gRcvIRQ.buf_write = 0;
p_entry = &gRcvIRQ.queue[gRcvIRQ.buf_write];
if (gRcvIRQ.buf_write == gRcvIRQ.buf_read)
{ /* queue overflow */
gRcvIRQ.overflow = true;
/* what can I do? Continueing overwrites the oldest. */
}
gRcvIRQ.byte = 0;
gRcvIRQ.bit = 0;
p_entry->size = 0;
p_entry->error = RX_BUSY; /* enable receive on new entry */
}
/* generate the checksum */
unsigned char calc_checksum(unsigned char* p_msg, int digits)
{
int chk = 0;
int i;
for (i=0; i<digits; i++)
{
chk ^= p_msg[i];
}
chk = (chk+1) % 16;
return chk;
}
/****************** high-level M-Bus functions ******************/
void mbus_init(void)
{
/* init the send object */
rb->memset(&gSendIRQ, 0, sizeof(gSendIRQ));
timer_init(MBUS_STEP_FREQ, (MBUS_BIT_FREQ*10)/15); /* setup frequency and timeout (1.5 bit) */
/* init receiver */
rb->memset(&gRcvIRQ, 0, sizeof(gRcvIRQ));
uart_init(MBUS_BAUDRATE);
}
/* send out a number of BCD digits (one per byte) with M-Bus protocol */
int mbus_send(unsigned char* p_msg, int digits)
{
/* wait for previous transmit/receive to end */
while(gTimer.mode != TM_OFF) /* wait for "free line" */
rb->sleep(1);
/* fill in our part */
rb->memcpy(gSendIRQ.send_buf, p_msg, digits);
/* add checksum */
gSendIRQ.send_buf[digits] = calc_checksum(p_msg, digits);
digits++;
/* debug dump, to be removed */
if (gTread.foreground)
{
char buf[MBUS_MAX_SIZE+1];
dump_packet(buf, sizeof(buf), gSendIRQ.send_buf, digits);
/*print_scroll(buf); */
}
gSendIRQ.send_size = digits;
/* prepare everything so the ISR can start right away */
gSendIRQ.index = 0;
gSendIRQ.byte = gSendIRQ.send_buf[0];
gSendIRQ.bitmask = 0x08;
gSendIRQ.step = 0;
gSendIRQ.bit = (gSendIRQ.byte & gSendIRQ.bitmask) != 0;
gSendIRQ.collision = false;
gSendIRQ.busy = true;
/* last chance to wait for a new detected receive to end */
while(gTimer.mode != TM_OFF) /* wait for "free line" */
rb->sleep(1);
and_b(~0x30, PBCR1_ADDR+1); /* GPIO for PB10 */
timer_set_mode(TM_TRANSMIT); /* run */
/* make the call blocking until sent out */
rb->sleep(digits*4*HZ/MBUS_BIT_FREQ); /* should take this long */
while(gSendIRQ.busy) /* poll in case it lasts longer */
rb->sleep(1); /* (should not happen) */
/* debug output, to be removed */
if (gTread.foreground)
{
if (gSendIRQ.collision)
print_scroll("collision");
}
return gSendIRQ.collision;
}
/* returns the size of message copy, 0 if timed out, negative on error */
int mbus_receive(unsigned char* p_msg, unsigned bufsize, int timeout)
{
int retval = 0;
do
{
if (gRcvIRQ.buf_read != gRcvIRQ.buf_write)
{ /* something in the queue */
t_rcv_queue_entry* p_entry = &gRcvIRQ.queue[gRcvIRQ.buf_read]; /* short cut */
if (p_entry->error == RX_RECEIVED)
{ /* seems valid */
rb->memcpy(p_msg, p_entry->buf, MIN(p_entry->size, bufsize));
retval = p_entry->size; /* return message size */
}
else
{ /* an error occured */
retval = - p_entry->error; /* return negative number */
}
/* next queue readout position */
gRcvIRQ.buf_read++;
if (gRcvIRQ.buf_read >= MBUS_RCV_QUEUESIZE)
gRcvIRQ.buf_read = 0;
return retval; /* exit */
}
if (timeout != 0 || gTimer.mode != TM_OFF) /* also carry on if reception in progress */
{
if (timeout != -1 && timeout != 0) /* if not infinite or expired */
timeout--;
rb->sleep(1); /* wait a while */
}
} while (timeout != 0 || gTimer.mode != TM_OFF);
return 0; /* timeout */
}
/****************** MMI helper fuctions ******************/
void print_scroll(char* string)
{
static char screen[LINES][COLUMNS+1]; /* visible strings */
static unsigned pos = 0; /* next print position */
static unsigned screentop = 0; /* for scrolling */
if (!gTread.foreground)
return; /* just to protect careless callers */
if (pos >= LINES)
{ /* need to scroll first */
int i;
rb->lcd_clear_display();
screentop++;
for (i=0; i<LINES-1; i++)
rb->lcd_puts(0, i, screen[(i+screentop) % LINES]);
pos = LINES-1;
}
/* no strncpy avail. */
rb->snprintf(screen[(pos+screentop) % LINES], sizeof(screen[0]), "%s", string);
rb->lcd_puts(0, pos, screen[(pos+screentop) % LINES]);
#ifndef HAVE_LCD_CHARCELLS
rb->lcd_update();
#endif
pos++;
}
void dump_packet(char* dest, int dst_size, char* src, int n)
{
int i;
int len = MIN(dst_size-1, n);
for (i=0; i<len; i++)
{ /* convert to hex digits */
dest[i] = src[i] < 10 ? '0' + src[i] : 'A' + src[i] - 10;
}
dest[i] = '\0'; /* zero terminate string */
}
/****************** CD changer emulation ******************/
bool bit_test(unsigned char* buf, unsigned bit)
{
return (buf[bit/4] & (0x01 << bit%4)) != 0;
}
void bit_set(unsigned char* buf, unsigned bit, bool val)
{
if (val)
buf[bit/4] |= (0x01 << bit%4);
else
buf[bit/4] &= ~(0x01 << bit%4);
}
void emu_init(void)
{
rb->memset(&gEmu, 0, sizeof(gEmu));
gEmu.poll_interval = HZ;
/* init the play message to 990000000000000 */
gEmu.playmsg[0] = gEmu.playmsg[1] = 0x9;
/* init the changing message to 9B900000001 */
gEmu.changemsg[0] = gEmu.changemsg[2] = 0x9;
gEmu.changemsg[1] = 0xB;
gEmu.changemsg[10] = 0x1;
/* init the disk status message to 9C1019999990 */
rb->memset(&gEmu.diskmsg, 0x9, sizeof(gEmu.diskmsg));
gEmu.diskmsg[1] = 0xC;
gEmu.diskmsg[2] = gEmu.diskmsg[4] = 0x1;
gEmu.diskmsg[3] = gEmu.diskmsg[11] = 0x0;
}
/* feed a radio command into the emulator */
void emu_process_packet(unsigned char* mbus_msg, int msg_size)
{
bool playmsg_dirty = false;
bool diskmsg_dirty = false;
if (msg_size == 2 && mbus_msg[0] == 1 && mbus_msg[1] == 8)
{ /* 18: ping */
mbus_send("\x09\x08", 2); /* 98: ping OK */
}
else if (msg_size == 5 && mbus_msg[0] == 1 && mbus_msg[1] == 1 && mbus_msg[2] == 1)
{ /* set play state */
if (bit_test(mbus_msg, 16))
{
if (gEmu.set_state == EMU_FF || gEmu.set_state == EMU_FR) /* was seeking? */
{ /* seek to final position */
set_position(gEmu.time);
}
else if (gEmu.set_state != EMU_PLAYING || gEmu.set_state != EMU_PAUSED)
{ /* was not playing yet, better send disk message */
diskmsg_dirty = true;
}
set_play();
gEmu.set_state = EMU_PLAYING;
playmsg_dirty = true;
}
if (bit_test(mbus_msg, 17))
{
gEmu.set_state = EMU_PAUSED;
playmsg_dirty = true;
set_pause();
}
if (bit_test(mbus_msg, 14))
{
gEmu.set_state = EMU_STOPPED;
playmsg_dirty = true;
set_stop();
}
if (bit_test(mbus_msg, 18))
{
gEmu.set_state = EMU_FF;
playmsg_dirty = true;
set_pause();
}
if (bit_test(mbus_msg, 19))
{
gEmu.set_state = EMU_FR;
playmsg_dirty = true;
set_pause();
}
if (bit_test(mbus_msg, 12)) /* scan stop */
{
bit_set(gEmu.playmsg, 51, false);
playmsg_dirty = true;
}
if (gEmu.set_state == EMU_FF || gEmu.set_state == EMU_FR)
gEmu.poll_interval = HZ/4; /* faster refresh */
else
gEmu.poll_interval = HZ;
}
else if (msg_size == 8 && mbus_msg[0] == 1 && mbus_msg[1] == 1 && mbus_msg[2] == 4)
{ /* set program mode */
gEmu.playmsg[11] = mbus_msg[3]; /* copy repeat, random, intro */
gEmu.playmsg[12] = mbus_msg[4]; /* ToDo */
playmsg_dirty = true;
}
else if (msg_size ==8 && mbus_msg[0] == 1 && mbus_msg[1] == 1 && mbus_msg[2] == 3)
{ /* changing */
gEmu.time = 0; /* reset playtime */
playmsg_dirty = true;
if (mbus_msg[3] == 0)
{ /* changing track */
if (mbus_msg[4] == 0xA && mbus_msg[5] == 0x3)
{ /* next random */
gEmu.playmsg[3] = rb->rand() % 10; /* ToDo */
gEmu.playmsg[4] = rb->rand() % 10;
}
else if (mbus_msg[4] == 0xB && mbus_msg[5] == 0x3)
{ /* previous random */
gEmu.playmsg[3] = rb->rand() % 10; /* ToDo */
gEmu.playmsg[4] = rb->rand() % 10;
}
else
{ /* normal track select */
set_track(mbus_msg[4]*10 + mbus_msg[5]);
}
}
else
{ /* changing disk */
diskmsg_dirty = true;
gEmu.changemsg[3] = mbus_msg[3]; /* copy disk */
gEmu.diskmsg[2] = mbus_msg[3];
gEmu.changemsg[7] = gEmu.playmsg[11]; /* copy flags from status */
gEmu.changemsg[8] = gEmu.playmsg[12];
/*gEmu.playmsg[3] = 0; */ /* reset to track 1 */
/*gEmu.playmsg[4] = 1; */
mbus_send(gEmu.changemsg, sizeof(gEmu.changemsg));
}
}
else
{ /* if in doubt, send Ack */
mbus_send("\x09\x0F\x00\x00\x00\x00\x00", 7);
}
if (playmsg_dirty)
{
rb->yield(); /* give the audio thread a chance to process */
get_playmsg(); /* force update */
mbus_send(gEmu.playmsg, sizeof(gEmu.playmsg));
}
if (diskmsg_dirty)
{
get_diskmsg(); /* force update */
mbus_send(gEmu.diskmsg, sizeof(gEmu.diskmsg));
}
}
/* called each second in case the emulator has something to do */
void emu_tick(void)
{
get_playmsg(); /* force update */
if (bit_test(gEmu.playmsg, 56)) /* play bit */
{
unsigned remain; /* helper as we walk down the digits */
switch(gEmu.set_state)
{
case EMU_FF:
gEmu.time += 10;
case EMU_FR:
gEmu.time -= 5;
if (gEmu.time < 0)
gEmu.time = 0;
else if (gEmu.time > get_tracklength())
gEmu.time = get_tracklength();
/* convert value to MM:SS */
remain = (unsigned)gEmu.time;
gEmu.playmsg[7] = remain / (10*60);
remain -= gEmu.playmsg[7] * (10*60);
gEmu.playmsg[8] = remain / 60;
remain -= gEmu.playmsg[8] * 60;
gEmu.playmsg[9] = remain / 10;
remain -= gEmu.playmsg[9] * 10;
gEmu.playmsg[10] = remain;
}
mbus_send(gEmu.playmsg, sizeof(gEmu.playmsg));
}
}
/****************** communication with Rockbox playback ******************/
/* update the play message with Rockbox info */
void get_playmsg(void)
{
int track, time;
if (gEmu.set_state != EMU_FF && gEmu.set_state != EMU_FR)
{
switch(rb->audio_status())
{
case AUDIO_STATUS_PLAY:
print_scroll("AudioStat Play");
if (gEmu.set_state == EMU_FF || gEmu.set_state == EMU_FR)
gEmu.playmsg[2] = gEmu.set_state; /* set FF/FR */
else
gEmu.playmsg[2] = EMU_PLAYING; /* set normal play */
bit_set(gEmu.playmsg, 56, true); /* set play */
bit_set(gEmu.playmsg, 57, false); /* clear pause */
bit_set(gEmu.playmsg, 59, false); /* clear stop */
break;
case AUDIO_STATUS_PLAY | AUDIO_STATUS_PAUSE:
print_scroll("AudioStat Pause");
gEmu.playmsg[2] = EMU_PAUSED;
bit_set(gEmu.playmsg, 56, false); /* clear play */
bit_set(gEmu.playmsg, 57, true); /* set pause */
bit_set(gEmu.playmsg, 59, false); /* clear stop */
break;
default:
print_scroll("AudioStat 0");
gEmu.playmsg[2] = EMU_STOPPED;
bit_set(gEmu.playmsg, 56, false); /* clear play */
bit_set(gEmu.playmsg, 57, false); /* clear pause */
bit_set(gEmu.playmsg, 59, true); /* set stop */
break;
}
/* convert value to MM:SS */
time = get_playtime();
gEmu.time = time; /* copy it */
gEmu.playmsg[7] = time / (10*60);
time -= gEmu.playmsg[7] * (10*60);
gEmu.playmsg[8] = time / 60;
time -= gEmu.playmsg[8] * 60;
gEmu.playmsg[9] = time / 10;
time -= gEmu.playmsg[9] * 10;
gEmu.playmsg[10] = time;
}
else /* FF/FR */
{
gEmu.playmsg[2] = gEmu.set_state; /* in FF/FR, report that instead */
}
track = get_track();
gEmu.playmsg[3] = track / 10;
gEmu.playmsg[4] = track % 10;
}
/* update the disk status message with Rockbox info */
void get_diskmsg(void)
{
int tracks = rb->playlist_amount();
if (tracks > 99)
tracks = 99;
gEmu.diskmsg[5] = tracks / 10;
gEmu.diskmsg[6] = tracks % 10;
}
/* return the current track time in seconds */
int get_playtime(void)
{
struct mp3entry* p_mp3entry;
p_mp3entry = rb->audio_current_track();
if (p_mp3entry == NULL)
return 0;
return p_mp3entry->elapsed / 1000;
}
/* return the total length of the current track */
int get_tracklength(void)
{
struct mp3entry* p_mp3entry;
p_mp3entry = rb->audio_current_track();
if (p_mp3entry == NULL)
return 0;
return p_mp3entry->length / 1000;
}
/* change to a new track */
void set_track(int selected)
{
if (selected > get_track())
{
print_scroll("audio_next");
rb->audio_next();
}
else if (selected < get_track())
{
print_scroll("audio_prev");
rb->audio_prev();
}
}
/* return the track number */
int get_track(void)
{
struct mp3entry* p_mp3entry;
p_mp3entry = rb->audio_current_track();
if (p_mp3entry == NULL)
return 0;
return p_mp3entry->index + 1; /* track numbers start with 1 */
}
/* start or resume playback */
void set_play(void)
{
if (rb->audio_status() == AUDIO_STATUS_PLAY)
return;
if (rb->audio_status() == (AUDIO_STATUS_PLAY | AUDIO_STATUS_PAUSE))
{
print_scroll("audio_resume");
rb->audio_resume();
}
else
{
print_scroll("audio_play(0)");
rb->audio_play(0);
}
}
/* pause playback */
void set_pause(void)
{
if (rb->audio_status() == AUDIO_STATUS_PLAY)
{
print_scroll("audio_pause");
rb->audio_pause();
}
}
/* stop playback */
void set_stop(void)
{
if (rb->audio_status() & AUDIO_STATUS_PLAY)
{
print_scroll("audio_stop");
rb->audio_stop();
}
}
/* seek */
void set_position(int seconds)
{
if (rb->audio_status() & AUDIO_STATUS_PLAY)
{
print_scroll("audio_ff_rewind");
rb->audio_ff_rewind(seconds * 1000);
}
}
/****************** main thread + helper ******************/
/* set to everything flat and 0 dB volume */
void sound_neutral(void)
{ /* neutral sound settings */
rb->sound_set(SOUND_BASS, 0);
rb->sound_set(SOUND_TREBLE, 0);
rb->sound_set(SOUND_BALANCE, 0);
rb->sound_set(SOUND_VOLUME, 0);
#if (CONFIG_CODEC == MAS3587F) || (CONFIG_CODEC == MAS3539F)
rb->sound_set(SOUND_LOUDNESS, 0);
rb->sound_set(SOUND_SUPERBASS, 0);
rb->sound_set(SOUND_AVC, 0);
#endif
}
/* return to user settings */
void sound_normal(void)
{ /* restore sound settings */
rb->sound_set(SOUND_BASS, rb->global_settings->bass);
rb->sound_set(SOUND_TREBLE, rb->global_settings->treble);
rb->sound_set(SOUND_BALANCE, rb->global_settings->balance);
rb->sound_set(SOUND_VOLUME, rb->global_settings->volume);
#if (CONFIG_CODEC == MAS3587F) || (CONFIG_CODEC == MAS3539F)
rb->sound_set(SOUND_LOUDNESS, rb->global_settings->loudness);
rb->sound_set(SOUND_SUPERBASS, rb->global_settings->superbass);
rb->sound_set(SOUND_AVC, rb->global_settings->avc);
#endif
}
/* the thread running it all */
void thread(void)
{
int msg_size;
unsigned char mbus_msg[MBUS_MAX_SIZE];
char buf[32];
bool connected = false;
long last_tick = *rb->current_tick; /* for 1 sec tick */
do
{
msg_size = mbus_receive(mbus_msg, sizeof(mbus_msg), 1);
if (msg_size > 0)
{ /* received something */
if(gTread.foreground)
{
dump_packet(buf, sizeof(buf), mbus_msg, msg_size);
/*print_scroll(buf); */
}
if (msg_size > 2 && mbus_msg[0] == 1
&& mbus_msg[msg_size-1] == calc_checksum(mbus_msg, msg_size-1))
{ /* sanity and checksum OK */
if (!connected)
{ /* with the first received packet: */
sound_neutral(); /* set to flat and 0dB volume */
connected = true;
}
emu_process_packet(mbus_msg, msg_size-1); /* pass without chksum */
}
else if(gTread.foreground)
{ /* not OK */
print_scroll("bad packet");
}
}
else if (msg_size < 0 && gTread.foreground)
{ /* error */
rb->snprintf(buf, sizeof(buf), "rcv error %d", msg_size);
print_scroll(buf);
}
if (*rb->current_tick - last_tick >= gEmu.poll_interval)
{ /* call the emulation regulary */
emu_tick();
last_tick += gEmu.poll_interval;
}
} while (!gTread.exiting);
gTread.ended = true; /* acknowledge the exit */
rb->remove_thread(NULL); /* commit suicide */
}
/* callback to end the TSR plugin, called before a new one gets loaded */
bool exit_tsr(bool reenter)
{
if (reenter)
return false; /* dont let it start again */
gTread.exiting = true; /* tell the thread to end */
while (!gTread.ended) /* wait until it did */
rb->yield();
uart_init(BAUDRATE); /* return to standard baudrate */
IPRE = (IPRE & ~0xF000); /* UART interrupt off */
timer_set_mode(TM_OFF); /* timer interrupt off */
sound_normal(); /* restore sound settings */
return true;
}
/****************** main ******************/
int main(void* parameter)
{
(void)parameter;
#ifdef DEBUG
int button;
#endif
int stacksize;
void* stack;
mbus_init(); /* init the M-Bus layer */
emu_init(); /* init emulator */
rb->splash(HZ/5, true, "Alpine CDC"); /* be quick on autostart */
#ifdef DEBUG
print_scroll("Alpine M-Bus Test");
print_scroll("any key to TSR");
#endif
/* init the worker thread */
stack = rb->plugin_get_buffer(&stacksize); /* use the rest as stack */
stack = (void*)(((unsigned int)stack + 100) & ~3); /* a bit away, 32 bit align */
stacksize = (stacksize - 100) & ~3;
if (stacksize < DEFAULT_STACK_SIZE)
{
rb->splash(HZ*2, true, "Out of memory");
return -1;
}
rb->memset(&gTread, 0, sizeof(gTread));
gTread.foreground = true;
rb->create_thread(thread, stack, stacksize, "CDC"
IF_PRIO(, PRIORITY_BACKGROUND));
#ifdef DEBUG
do
{
button = rb->button_get(true);
} while (button & BUTTON_REL);
#endif
gTread.foreground = false; /* we're in the background now */
rb->plugin_tsr(exit_tsr); /* stay resident */
#ifdef DEBUG
return rb->default_event_handler(button);
#else
return 0;
#endif
}
/***************** Plugin Entry Point *****************/
enum plugin_status plugin_start(struct plugin_api* api, void* parameter)
{
rb = api; /* copy to global api pointer */
/* now go ahead and have fun! */
return (main(parameter)==0) ? PLUGIN_OK : PLUGIN_ERROR;
}
#endif /* #ifndef SIMULATOR, etc. */