#include "apps.h"
#include "glitch.h"
+#define RESET 0x80 // not a real app -- causes firmware to reset
+#define DEBUGAPP 0xFF
//! Initialize registers and all that jazz.
-void init(){
- int i;
- WDTCTL = WDTPW + WDTHOLD; // Stop watchdog timer
-
- //LED out and on.
- PLEDDIR |= PLEDPIN;
- PLEDOUT &= ~PLEDPIN;
-
- //Setup clocks, unique to each '430.
- msp430_init_dco();
- msp430_init_uart();
-
- //DAC should be at full voltage if it exists.
+void init()
+{
+ WDTCTL = WDTPW + WDTHOLD; // Stop watchdog timer
+
+ //LED out and on.
+ PLEDDIR |= PLEDPIN;
+ PLEDOUT &= ~PLEDPIN;
+
+
+ /* P5.0 out and low; this is chosen for the PIC app (in which P5.0
+ is !MCLR) to ensure that an attached PIC chip, if present, is
+ immediately driven to reset state. A brief explanation of why this
+ is important follows.
+
+ At least dsPIC33F and PIC24H --and very likely other 16-bit PIC
+ families-- draw a large amount of current when running, especially
+ when using a fast clock: from 60 mA up to approx. 90 mA. If the
+ PIC target begins to run before the client can request a new ICSP
+ session, which requires much less current (e.g., less than 2 mA),
+ then the MSP430 chip on the GoodFET will fail to start and the FTDI
+ may have trouble communicating with the client. The latter likely
+ relates to the FTDI on-chip 3V3 regulator being specified up to
+ only 50 mA. */
+
+
+ //P5REN &= ~BIT0; //DO NOT UNCOMMENT. Breaks GF1x support.
+
+ //This will have to be cut soon. Use pulling resistors instead.
+ /*
+ P5DIR |= BIT0;
+ P5OUT &= ~BIT0;
+ */
+
+ //Setup clocks, unique to each '430.
+ msp430_init_dco();
+ msp430_init_uart();
+
+ //DAC should be at full voltage if it exists.
#ifdef DAC12IR
- //glitchvoltages(0xfff,0xfff);
- ADC12CTL0 = REF2_5V + REFON; // Internal 2.5V ref on
- for(i=0;i!=0xFFFF;i++) asm("nop");
- DAC12_0CTL = DAC12IR + DAC12AMP_5 + DAC12ENC; // Int ref gain 1
- DAC12_0DAT = 0xFFF; //Max voltage 0xfff
- DAC12_1CTL = DAC12IR + DAC12AMP_5 + DAC12ENC; // Int ref gain 1
- DAC12_1DAT = 0x000; //Min voltage 0x000
+ //glitchvoltages(0xfff,0xfff);
+ ADC12CTL0 = REF2_5V + REFON; // Internal 2.5V ref on
+ //for(i=0;i!=0xFFFF;i++) asm("nop"); //DO NOT UNCOMMENT, breaks GCC4
+ DAC12_0CTL = DAC12IR + DAC12AMP_5 + DAC12ENC; // Int ref gain 1
+ DAC12_0DAT = 0xFFF; //Max voltage 0xfff
+ DAC12_1CTL = DAC12IR + DAC12AMP_5 + DAC12ENC; // Int ref gain 1
+ DAC12_1DAT = 0x000; //Min voltage 0x000
+#endif
+
+ /** FIXME
+
+ This part is really ugly. GSEL (P5.7) must be high to select
+ normal voltage, but a lot of applications light to swing it low
+ to be a nuissance. To get around this, we assume that anyone
+ with a glitching FET will also have a DAC, then we set that DAC
+ to a high voltage.
+
+ At some point, each target must be sanitized to show that it
+ doesn't clear P5OUT or P5DIR.
+ */
+ P5DIR|=BIT7; P5OUT=BIT7; //Normal Supply
+ //P5DIR&=~BIT7; //Glitch Supply
+
+ //Enable Interrupts.
+ //eint();
+
+#ifdef INITPLATFORM
+ INITPLATFORM
#endif
-
- /** FIXME
-
- This part is really ugly. GSEL (P5.7) must be high to select
- normal voltage, but a lot of applications light to swing it low
- to be a nuissance. To get around this, we assume that anyone
- with a glitching FET will also have a DAC, then we set that DAC
- to a high voltage.
-
- At some point, each target must be sanitized to show that it
- doesn't clear P5OUT or P5DIR.
- */
- P5DIR|=BIT7; P5OUT=BIT7; //Normal Supply
- //P5DIR&=~BIT7; //Glitch Supply
-
- //Enable Interrupts.
- //eint();
}
//! Handle a command.
-void handle(unsigned char app,
- unsigned char verb,
- unsigned long len){
- //debugstr("GoodFET");
- P1OUT&=~1;
- switch(app){
- case GLITCH:
- glitchhandle(app,verb,len);
- break;
- case MONITOR:
- monitorhandle(app,verb,len);
- break;
- case SPI:
- spihandle(app,verb,len);
- break;
- case AVR:
- avrhandle(app,verb,len);
- break;
-#ifdef INSTALL_PIC_APP
- case PIC:
- pichandle(app,verb,len);
- break;
-#endif
- case I2CAPP:
- i2chandle(app,verb,len);
- break;
- case CHIPCON:
- cchandle(app,verb,len);
- break;
- case JTAG:
- jtaghandle(app,verb,len);
- break;
- case EJTAG:
- ejtaghandle(app,verb,len);
- break;
- case JTAG430: //Also JTAG430X, JTAG430X2
- jtag430x2handle(app,verb,len);
- break;
- case SMARTCARD:
- smartcardhandle(app,verb,len);
- break;
- case JTAGARM7TDMI:
- jtagarm7tdmihandle(app,verb,len);
- break;
- default:
- if(pluginhandle){
- pluginhandle(app,verb,len);
- }else{
- debugstr("Plugin missing.");
- debughex(app);
- txdata(app,NOK,0);
- }
- break;
- }
+void handle(uint8_t const app,
+ uint8_t const verb,
+ uint32_t const len)
+{
+ int i;
+
+ //debugstr("GoodFET");
+ PLEDOUT&=~PLEDPIN;
+
+ // find the app and call the handle fn
+ for(i = 0; i < num_apps; i++)
+ {
+ if(apps[i]->app == app)
+ {
+ // call the app's handle fn
+ (*(apps[i]->handle))(app, verb, len);
+
+ // exit early
+ return;
+ }
+ }
+
+ // if we get here, then the desired app is not copiled in
+ // this firmware
+ debugstr("App missing.");
+ debughex(app);
+ txdata(app, NOK, 0);
}
+
//! Main loop.
int main(void)
{
- volatile unsigned int i;
- unsigned char app, verb;
- unsigned long len;
- // MSP reboot count for reset input & reboot function located at 0xFFFE
- volatile unsigned int reset_count = 0;
- void (*reboot_function)(void) = (void *) 0xFFFE;
-
- init();
+ volatile unsigned int i;
+ unsigned char app, verb;
+ unsigned long len;
+ // MSP reboot count for reset input & reboot function located at 0xFFFE
+ volatile unsigned int reset_count = 0;
+ void (*reboot_function)(void) = (void *) 0xFFFE;
- txstring(MONITOR,OK,"http://goodfet.sf.net/");
+ init();
+ txstring(MONITOR,OK,"http://goodfet.sf.net/");
- //Command loop. There's no end!
- while(1){
- //Magic 3
- app=serial_rx();
-
- // If the app is the reset byte (0x80) increment and loop
- if (app == 0x80) {
- reset_count++;
-
- if (reset_count > 4) {
- // We could trigger the WDT with either:
- // WDTCTL = 0;
- // or
- // WDTCTL = WDTPW + WDTCNTCL + WDTSSEL + 0x00;
- // but instead we'll jump to our reboot function pointer
- (*reboot_function)();
+ //Command loop. There's no end!
+ while(1)
+ {
+ //Magic 3
+ app = serial_rx();
+
+ // If the app is the reset byte (0x80) increment and loop
+ if (app == RESET)
+ {
+ reset_count++;
+
+ if (reset_count > 4)
+ {
+ // We could trigger the WDT with either:
+ // WDTCTL = 0;
+ // or
+ // WDTCTL = WDTPW + WDTCNTCL + WDTSSEL + 0x00;
+ // but instead we'll jump to our reboot function pointer
+ (*reboot_function)();
+ }
+
+ continue;
+ }
+ else
+ {
+ reset_count = 0;
}
- continue;
- } else {
- reset_count = 0;
- }
+ verb = serial_rx();
+ //len=serial_rx();
+ len = rxword();
+
+ //Read data, looking for buffer overflow.y
+ if(len <= CMDDATALEN)
+ {
+ for(i = 0; i < len; i++)
+ {
+ cmddata[i] = serial_rx();
+ }
- verb=serial_rx();
- //len=serial_rx();
- len=rxword();
-
- //Read data, looking for buffer overflow.y
- if(len<=CMDDATALEN){
- for(i=0;i<len;i++){
- cmddata[i]=serial_rx();
- }
- handle(app,verb,len);
- }else{
- //Listen to the blaberring.
- for(i=0;i<len;i++)
- serial_rx();
- //Reply with an error.
- debugstr("Buffer length exceeded.");
- txdata(MONITOR,NOK,0);
- }
- }
+ handle(app,verb,len);
+ }
+ else
+ {
+ //Listen to the blaberring.
+ for(i = 0; i < len; i++)
+ serial_rx();
+
+ //Reply with an error.
+ debugstr("Buffer length exceeded.");
+ txdata(MONITOR,NOK,0);
+ }
+ }
}