void QK_onIdle(void) {
#ifdef Q_SPY                     /* use the idle cycles for QS transmission */

    if ((AT91C_BASE_DBGU->DBGU_CSR & AT91C_US_TXBUFE) != 0) {  /* not busy? */
        uint16_t nBytes = 0xFFFF;
        uint8_t const *block;

        QF_INT_DISABLE();
        if ((block = QS_getBlock(&nBytes)) != (uint8_t *)0) { /* new block? */
            AT91C_BASE_DBGU->DBGU_TPR = (uint32_t)block;
            AT91C_BASE_DBGU->DBGU_TCR = (uint32_t)nBytes;
            nBytes = 0xFFFF;
            if ((block = QS_getBlock(&nBytes)) != (uint8_t *)0) {/*another? */
                AT91C_BASE_DBGU->DBGU_TNPR = (uint32_t)block;
                AT91C_BASE_DBGU->DBGU_TNCR = (uint32_t)nBytes;
            }
        }
        QF_INT_ENABLE();
    }

#elif defined NDEBUG /* only if not debugging (idle mode hinders debugging) */
    AT91C_BASE_PMC->PMC_SCDR = 1;/* Power-Management: disable the CPU clock */
    /* NOTE: an interrupt starts the CPU clock again */
#endif
}
Esempio n. 2
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/*..........................................................................*/
__ramfunc
void QK_onIdle(void) {

    /* toggle first LED on and off, see NOTE01 */
    QF_INT_DISABLE();
    LED_ON(3);  /* turn LED on  */
    LED_OFF(3); /* turn LED off */
    QF_INT_ENABLE();

#ifdef Q_SPY
    /* use the idle cycles for QS transmission... */

    if ((AT91C_BASE_DBGU->DBGU_CSR & AT91C_US_TXBUFE) != 0) { /* not busy? */
        uint16_t nBytes = 0xFFFFU; /* get all available bytes */
        uint8_t const *block;

        QF_INT_DISABLE();
        if ((block = QS_getBlock(&nBytes)) != (uint8_t *)0) { /* new block? */
            AT91C_BASE_DBGU->DBGU_TPR = (uint32_t)block;
            AT91C_BASE_DBGU->DBGU_TCR = (uint32_t)nBytes;
            nBytes = 0xFFFFU; /* get all available bytes */
            if ((block = QS_getBlock(&nBytes)) != (uint8_t *)0) {/*another? */
                AT91C_BASE_DBGU->DBGU_TNPR = (uint32_t)block;
                AT91C_BASE_DBGU->DBGU_TNCR = (uint32_t)nBytes;
            }
        }
        QF_INT_ENABLE();
    }
#elif defined NDEBUG /* only if not debugging (idle mode hinders debugging) */
    AT91C_BASE_PMC->PMC_SCDR = 1;/* Power-Management: disable the CPU clock */
    /* NOTE: an interrupt starts the CPU clock again */
#endif
}
Esempio n. 3
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/*..........................................................................*/
void QK_onIdle(void) {

    /* toggle the User LED on and then off, see NOTE02 */
    QF_INT_LOCK(dummy);
    GPIOC->DATA_Bits[USER_LED] = USER_LED;         /* turn the User LED on  */
    GPIOC->DATA_Bits[USER_LED] = 0;                /* turn the User LED off */
    QF_INT_UNLOCK(dummy);

#ifdef Q_SPY
    if ((UART0->FR & UART_FR_TXFE) != 0) {                      /* TX done? */
        uint16_t fifo = UART_TXFIFO_DEPTH;       /* max bytes we can accept */
        uint8_t const *block;
        QF_INT_LOCK(dummy);
        block = QS_getBlock(&fifo);    /* try to get next block to transmit */
        QF_INT_UNLOCK(dummy);
        while (fifo-- != 0) {                    /* any bytes in the block? */
            UART0->DR = *block++;                      /* put into the FIFO */
        }
    }
#elif defined NDEBUG
    /* Put the CPU and peripherals to the low-power mode.
    * you might need to customize the clock management for your application,
    * see the datasheet for your particular Cortex-M3 MCU.
    */
    __WFI();                                          /* Wait-For-Interrupt */
#endif
}
Esempio n. 4
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/*..........................................................................*/
void QK_onIdle(void) {
    float volatile x;

    /* toggle the User LED on and then off, see NOTE01 */
    QF_INT_DISABLE();
    GPIOF->DATA_Bits[LED_GREEN] = LED_GREEN;      /* turn the Green LED on  */
    GPIOF->DATA_Bits[LED_GREEN] = 0;              /* turn the Green LED off */
    QF_INT_ENABLE();

    x = 3.1415926F;
    x = x + 2.7182818F;

#ifdef Q_SPY
    if ((UART0->FR & UART_FR_TXFE) != 0) {                      /* TX done? */
        uint16_t fifo = UART_TXFIFO_DEPTH;       /* max bytes we can accept */
        uint8_t const *block;

        QF_INT_DISABLE();
        block = QS_getBlock(&fifo);    /* try to get next block to transmit */
        QF_INT_ENABLE();

        while (fifo-- != 0) {                    /* any bytes in the block? */
            UART0->DR = *block++;                      /* put into the FIFO */
        }
    }
#elif defined NDEBUG
    /* Put the CPU and peripherals to the low-power mode.
    * you might need to customize the clock management for your application,
    * see the datasheet for your particular Cortex-M3 MCU.
    */
    __WFI();                                          /* Wait-For-Interrupt */
#endif
}
Esempio n. 5
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/*..........................................................................*/
static DWORD WINAPI idleThread(LPVOID par) {/* signature for CreateThread() */
    (void)par;
    l_running = (uint8_t)1;
    while (l_running) {
        Sleep(10);                                      /* wait for a while */
        if (_kbhit()) {                                 /* any key pressed? */
	        char payload[1024];
            if(!gets_s(payload, sizeof(payload))) { // EOF reached
                printf("EOF received; exiting\n");
                QF_stop();
            } else {
                uint16_t len = strlen(payload);
                onPacket(payload, len, BSPConsole_print, NULL);
            }
        }

#ifdef Q_SPY
        {
            uint16_t nBytes = 1024;
            uint8_t const *block;
            QF_CRIT_ENTRY(dummy);
            block = QS_getBlock(&nBytes);
            QF_CRIT_EXIT(dummy);
            if (block != (uint8_t *)0) {
                send(l_sock, (char const *)block, nBytes, 0);
            }
        }
#endif
    }
    return 0;                                             /* return success */
}
Esempio n. 6
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/*..........................................................................*/
void QS_onFlush(void) {
    uint16_t nBytes = 1000;
    uint8_t const *block;
    while ((block = QS_getBlock(&nBytes)) != (uint8_t *)0) {
        send(l_sock, (char const *)block, nBytes, 0);
        nBytes = 1000;
    }
}
Esempio n. 7
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/*..........................................................................*/
void QS_onFlush(void)
{
#ifdef Q_SPY
	uint8_t const *block;
	uint16_t nBytes = QS_SPY_BLOCK;
	while (np.dev && (block = QS_getBlock(&nBytes)) != (uint8_t *)0) {
		QS_send(block, nBytes);
		nBytes = QS_SPY_BLOCK;
	}
#endif
}
Esempio n. 8
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/*..........................................................................*/
void QS_onFlush(void) {
    uint16_t fifo = UART_16550_TXFIFO_DEPTH;         /* 16550 Tx FIFO depth */
    uint8_t const *block;
    while ((block = QS_getBlock(&fifo)) != (uint8_t *)0) {
                                           /* busy-wait until TX FIFO empty */
        while ((inp(l_uart_base + 5) & (1 << 5)) == 0) {
        }

        while (fifo-- != 0) {                    /* any bytes in the block? */
            outp(l_uart_base + 0, *block++);
        }
        fifo = UART_16550_TXFIFO_DEPTH;      /* re-load 16550 Tx FIFO depth */
    }
}
Esempio n. 9
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/*..........................................................................*/
void QF_onIdle(void) {                     /* called with interrupts LOCKED */

    QF_INT_ENABLE();                            /* always enable interrupts */

#ifdef Q_SPY
    if ((inp(l_uart_base + 5) & (1 << 5)) != 0) {             /* THR empty? */
        uint16_t fifo = UART_16550_TXFIFO_DEPTH;     /* 16550 Tx FIFO depth */
        uint8_t const *block;
        QF_INT_DISABLE();
        block = QS_getBlock(&fifo);    /* try to get next block to transmit */
        QF_INT_ENABLE();
        while (fifo-- != 0) {                    /* any bytes in the block? */
            outp(l_uart_base + 0, *block++);
        }
    }
#endif
}
Esempio n. 10
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/*..........................................................................*/
void QS_onFlush(void) {
    for (;;) {
        uint16_t nBytes = 1024;
        uint8_t const *block;

        QF_CRIT_ENTRY(dummy);
        block = QS_getBlock(&nBytes);
        QF_CRIT_EXIT(dummy);

        if (block != (uint8_t const *)0) {
            QSPY_parse(block, nBytes);
            nBytes = 1024;
        }
        else {
            break;
        }
    }
}
Esempio n. 11
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/*..........................................................................*/
static DWORD WINAPI idleThread(LPVOID par) {/* signature for CreateThread() */
    (void)par;

    SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_IDLE);
    l_running = (uint8_t)1;
    while (l_running) {
        uint16_t nBytes = 256;
        uint8_t const *block;
        QF_CRIT_ENTRY(dummy);
        block = QS_getBlock(&nBytes);
        QF_CRIT_EXIT(dummy);
        if (block != (uint8_t *)0) {
            QSPY_parse(block, nBytes);
        }
        Sleep(10);                                      /* wait for a while */
    }
    return 0;                                             /* return success */
}
Esempio n. 12
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/*..........................................................................*/
void QS_onFlush(void) {
    uint16_t fifo = UART_TXFIFO_DEPTH;                     /* Tx FIFO depth */
    uint8_t const *block;
    QF_INT_DISABLE();
    while ((block = QS_getBlock(&fifo)) != (uint8_t *)0) {
        QF_INT_ENABLE();
                                           /* busy-wait until TX FIFO empty */
        while ((UART0->FR & UART_FR_TXFE) == 0) {
        }

        while (fifo-- != 0) {                    /* any bytes in the block? */
            UART0->DR = *block++;                   /* put into the TX FIFO */
        }
        fifo = UART_TXFIFO_DEPTH;              /* re-load the Tx FIFO depth */
        QF_INT_DISABLE();
    }
    QF_INT_ENABLE();
}
Esempio n. 13
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static int idleThread(void *arg)
{
	complete(&idle_done);
	while (idle_running) {
		QF_INT_KEY_TYPE dummy;
		uint8_t const *block;
		uint16_t nBytes = QS_SPY_BLOCK;
		QF_INT_LOCK(dummy);
		block = QS_getBlock(&nBytes);
		QF_INT_UNLOCK(dummy);

		QS_send(block, nBytes);
		schedule_timeout(HZ);
	}
	complete(&idle_done);

	return 0;
}
Esempio n. 14
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/*..........................................................................*/
static DWORD WINAPI idleThread(LPVOID par) {/* signature for CreateThread() */
    (void)par;
    while (l_sock != INVALID_SOCKET) {
        uint16_t nBytes;
        uint8_t const *block;

        /* try to receive bytes from the QS socket... */
        nBytes = QS_rxGetNfree();
        if (nBytes > 0U) {
            uint8_t buf[64];
            int status;

            if (nBytes > sizeof(buf)) {
                nBytes = sizeof(buf);
            }
            status = recv(l_sock, (char *)buf, (int)nBytes, 0);
            if (status != SOCKET_ERROR) {
                uint16_t i;
                nBytes = (uint16_t)status;
                for (i = 0U; i < nBytes; ++i) {
                    QS_RX_PUT(buf[i]);
                }
            }
        }
        QS_rxParse();  /* parse all the received bytes */

        nBytes = 1024U;
        QF_CRIT_ENTRY(dummy);
        block = QS_getBlock(&nBytes);
        QF_CRIT_EXIT(dummy);

        if (block != (uint8_t *)0) {
            send(l_sock, (char const *)block, nBytes, 0);
        }
        Sleep(20); /* sleep for xx milliseconds */
    }
    return (DWORD)0; /* return success */
}
Esempio n. 15
0
File: bsp.c Progetto: alisonjoe/qpc
/*..........................................................................*/
void QV_onIdle(void) { /* called with interrupts disabled, see NOTE01 */
    /* toggle the LED on and then off, see NOTE02 */
    QF_INT_DISABLE();
    LPC_GPIO1->FIOSET = LED_4;  /* turn LED on  */
    __NOP();   /* a couple of NOPs to actually see the LED glow */
    __NOP();
    __NOP();
    __NOP();
    LPC_GPIO1->FIOCLR = LED_4;  /* turn LED off */
    QF_INT_ENABLE();

#ifdef Q_SPY

    if ((LPC_UART0->LSR & 0x20U) != 0U) {  /* TX Holding Register empty? */
        uint16_t fifo = UART_TXFIFO_DEPTH; /* max bytes we can accept */
        uint8_t const *block;

        QF_INT_DISABLE();
        block = QS_getBlock(&fifo); /* try to get next block to transmit */
        QF_INT_ENABLE();

        while (fifo-- != 0) { /* any bytes in the block? */
            LPC_UART0->THR = *block++; /* put into the FIFO */
        }
    }

#elif defined NDEBUG
    /* Put the CPU and peripherals to the low-power mode.
    * you might need to customize the clock management for your application,
    * see the datasheet for your particular Cortex-M MCU.
    */
    QV_CPU_SLEEP();  /* atomically go to sleep and enable interrupts */
#else
    QF_INT_ENABLE(); /* just enable interrupts */
#endif
}