scopes: Factor out SET_ANALOG_MODE().

[sigrok-firmware-fx2lafw.git] / fx2lafw.c

/*
 * This file is part of the sigrok-firmware-fx2lafw project.
 *
 * Copyright (C) 2011-2012 Uwe Hermann <uwe@hermann-uwe.de>
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, see <http://www.gnu.org/licenses/>.
 */

/*
 * fx2lafw is an open-source firmware for Cypress FX2 based logic analyzers.
 *
 * It is written in C, using fx2lib as helper library, and sdcc as compiler.
 * The code is licensed under the terms of the GNU GPL, version 2 or later.
 *
 * Technical notes:
 *
 *  - We use the FX2 in GPIF mode to sample the data (asynchronously).
 *  - We use the internal 48MHz clock for GPIF.
 *  - The 8 channels/pins we sample (the GPIF data bus) are PB0-PB7,
 *    or PB0-PB7 + PD0-PD7 for 16-channel sampling. 
 *  - Endpoint 2 (quad-buffered) is used for data transfers from FX2 to host.
 *
 * Documentation:
 *
 *  - See http://sigrok.org/wiki/Fx2lafw
 */

#include <fx2regs.h>
#include <fx2macros.h>
#include <fx2ints.h>
#include <delay.h>
#include <setupdat.h>
#include <eputils.h>
#include <gpif.h>
#include <command.h>
#include <fx2lafw.h>
#include <gpif-acquisition.h>

/* ... */
volatile __bit got_sud;
BYTE vendor_command;

volatile WORD ledcounter = 1000;

extern __bit gpif_acquiring;

static void setup_endpoints(void)
{
        /* Setup EP2 (IN). */
        EP2CFG = (1 << 7) |               /* EP is valid/activated */
                 (1 << 6) |               /* EP direction: IN */
                 (1 << 5) | (0 << 4) |    /* EP Type: bulk */
                 (1 << 3) |               /* EP buffer size: 1024 */
                 (0 << 2) |               /* Reserved. */
                 (0 << 1) | (0 << 0);     /* EP buffering: quad buffering */
        SYNCDELAY();

        /* Disable all other EPs (EP1, EP4, EP6, and EP8). */
        EP1INCFG &= ~bmVALID;
        SYNCDELAY();
        EP1OUTCFG &= ~bmVALID;
        SYNCDELAY();
        EP4CFG &= ~bmVALID;
        SYNCDELAY();
        EP6CFG &= ~bmVALID;
        SYNCDELAY();
        EP8CFG &= ~bmVALID;
        SYNCDELAY();

        /* EP2: Reset the FIFOs. */
        /* Note: RESETFIFO() gets the EP number WITHOUT bit 7 set/cleared. */
        RESETFIFO(0x02)

        /* EP2: Enable AUTOIN mode. Set FIFO width to 8bits. */
        EP2FIFOCFG = bmAUTOIN;
        SYNCDELAY();

        /* EP2: Auto-commit 512 (0x200) byte packets (due to AUTOIN = 1). */
        EP2AUTOINLENH = 0x02;
        SYNCDELAY();
        EP2AUTOINLENL = 0x00;
        SYNCDELAY();

        /* EP2: Set the GPIF flag to 'full'. */
        EP2GPIFFLGSEL = (1 << 1) | (0 << 1);
        SYNCDELAY();
}

static void send_fw_version(void)
{
        /* Populate the buffer. */
        struct version_info *const vi = (struct version_info *)EP0BUF;
        vi->major = FX2LAFW_VERSION_MAJOR;
        vi->minor = FX2LAFW_VERSION_MINOR;

        /* Send the message. */
        EP0BCH = 0;
        EP0BCL = sizeof(struct version_info);
}

static void send_revid_version(void)
{
        uint8_t *p;

        /* Populate the buffer. */
        p = (uint8_t *)EP0BUF;
        *p = REVID;

        /* Send the message. */
        EP0BCH = 0;
        EP0BCL = 1;
}

BOOL handle_vendorcommand(BYTE cmd)
{
        /* Protocol implementation */
        switch (cmd) {
        case CMD_START:
                vendor_command = cmd;
                EP0BCL = 0;
                return TRUE;
                break;
        case CMD_GET_FW_VERSION:
                send_fw_version();
                return TRUE;
                break;
        case CMD_GET_REVID_VERSION:
                send_revid_version();
                return TRUE;
                break;
        }

        return FALSE;
}

BOOL handle_get_interface(BYTE ifc, BYTE *alt_ifc)
{
        /* We only support interface 0, alternate interface 0. */
        if (ifc != 0)
                return FALSE;

        *alt_ifc = 0;
        return TRUE;
}

BOOL handle_set_interface(BYTE ifc, BYTE alt_ifc)
{
        /* We only support interface 0, alternate interface 0. */
        if (ifc != 0 || alt_ifc != 0)
                return FALSE;

        /* Perform procedure from TRM, section 2.3.7: */

        /* (1) TODO. */

        /* (2) Reset data toggles of the EPs in the interface. */
        /* Note: RESETTOGGLE() gets the EP number WITH bit 7 set/cleared. */
        RESETTOGGLE(0x82);

        /* (3) Restore EPs to their default conditions. */
        /* Note: RESETFIFO() gets the EP number WITHOUT bit 7 set/cleared. */
        RESETFIFO(0x02);
        /* TODO */

        /* (4) Clear the HSNAK bit. Not needed, fx2lib does this. */

        return TRUE;
}

BYTE handle_get_configuration(void)
{
        /* We only support configuration 1. */
        return 1;
}

BOOL handle_set_configuration(BYTE cfg)
{
        /* We only support configuration 1. */
        return (cfg == 1) ? TRUE : FALSE;
}

void sudav_isr(void) __interrupt SUDAV_ISR
{
        got_sud = TRUE;
        CLEAR_SUDAV();
}

void sof_isr(void) __interrupt SOF_ISR __using 1
{
        CLEAR_SOF();
}

void usbreset_isr(void) __interrupt USBRESET_ISR
{
        handle_hispeed(FALSE);
        CLEAR_USBRESET();
}

void hispeed_isr(void) __interrupt HISPEED_ISR
{
        handle_hispeed(TRUE);
        CLEAR_HISPEED();
}

void timer2_isr(void) __interrupt TF2_ISR
{
        /* Blink LED during acquisition, keep it on otherwise. */
        if (gpif_acquiring) {
                if (--ledcounter == 0) {
                        PA1 = !PA1;
                        ledcounter = 1000;
                }
        } else {
                PA1 = 1; /* LED on. */
        }
        TF2 = 0;
}

void fx2lafw_init(void)
{
        /* Set DYN_OUT and ENH_PKT bits, as recommended by the TRM. */
        REVCTL = bmNOAUTOARM | bmSKIPCOMMIT;

        got_sud = FALSE;
        vendor_command = 0;

        /* Renumerate. */
        RENUMERATE_UNCOND();

        SETCPUFREQ(CLK_48M);

        USE_USB_INTS();

        /* TODO: Does the order of the following lines matter? */
        ENABLE_SUDAV();
        ENABLE_SOF();
        ENABLE_HISPEED();
        ENABLE_USBRESET();

        /* PA1 (LED) is an output. */
        PORTACFG = 0;
        OEA = (1 << 1);
        PA1 = 1; /* LED on. */

        /* Init timer2. */
        RCAP2L = -500 & 0xff;
        RCAP2H = (-500 & 0xff00) >> 8;
        T2CON = 0;
        ET2 = 1;
        TR2 = 1;

        /* Global (8051) interrupt enable. */
        EA = 1;

        /* Setup the endpoints. */
        setup_endpoints();

        /* Put the FX2 into GPIF master mode and setup the GPIF. */
        gpif_init_la();
}

void fx2lafw_poll(void)
{
        if (got_sud) {
                handle_setupdata();
                got_sud = FALSE;
        }

        if (vendor_command) {
                switch (vendor_command) {
                case CMD_START:
                        if ((EP0CS & bmEPBUSY) != 0)
                                break;

                        if (EP0BCL == sizeof(struct cmd_start_acquisition)) {
                                gpif_acquisition_start(
                                 (const struct cmd_start_acquisition *)EP0BUF);
                        }

                        /* Acknowledge the vendor command. */
                        vendor_command = 0;
                        break;
                default:
                        /* Unimplemented command. */
                        vendor_command = 0;
                        break;
                }
        }

        gpif_poll();
}

void main(void)
{
        fx2lafw_init();
        while (1)
                fx2lafw_poll();
}