hantek-dso: Convert to SR_DF_ANALOG.

[libsigrok.git] / src / hardware / hantek-dso / api.c

/*
 * This file is part of the libsigrok project.
 *
 * Copyright (C) 2012 Bert Vermeulen <bert@biot.com>
 *
 * 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 3 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/>.
 */

#include <config.h>
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <string.h>
#include <sys/time.h>
#include <inttypes.h>
#include <glib.h>
#include <libusb.h>
#include <libsigrok/libsigrok.h>
#include "libsigrok-internal.h"
#include "dso.h"

/* Max time in ms before we want to check on USB events */
/* TODO tune this properly */
#define TICK 1

#define NUM_TIMEBASE  10
#define NUM_VDIV      8

#define NUM_BUFFER_SIZES 2

static const uint32_t scanopts[] = {
        SR_CONF_CONN,
};

static const uint32_t drvopts[] = {
        SR_CONF_OSCILLOSCOPE,
};

static const uint32_t devopts[] = {
        SR_CONF_CONTINUOUS,
        SR_CONF_LIMIT_FRAMES | SR_CONF_SET,
        SR_CONF_CONN | SR_CONF_GET,
        SR_CONF_TIMEBASE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
        SR_CONF_BUFFERSIZE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
        SR_CONF_TRIGGER_SOURCE | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
        SR_CONF_TRIGGER_SLOPE | SR_CONF_GET | SR_CONF_SET,
        SR_CONF_HORIZ_TRIGGERPOS | SR_CONF_GET | SR_CONF_SET,
        SR_CONF_NUM_HDIV | SR_CONF_GET,
        SR_CONF_NUM_VDIV | SR_CONF_GET,
};

static const uint32_t devopts_cg[] = {
        SR_CONF_FILTER | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
        SR_CONF_VDIV | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
        SR_CONF_COUPLING | SR_CONF_GET | SR_CONF_SET | SR_CONF_LIST,
};

static const char *channel_names[] = {
        "CH1", "CH2",
};

static const uint64_t buffersizes_32k[] = {
        (10 * 1024), (32 * 1024),
};
static const uint64_t buffersizes_512k[] = {
        (10 * 1024), (512 * 1024),
};
static const uint64_t buffersizes_14k[] = {
        (10 * 1024), (14 * 1024),
};

static const struct dso_profile dev_profiles[] = {
        {       0x04b4, 0x2090, 0x04b5, 0x2090,
                "Hantek", "DSO-2090",
                buffersizes_32k,
                "hantek-dso-2090.fw" },
        {       0x04b4, 0x2150, 0x04b5, 0x2150,
                "Hantek", "DSO-2150",
                buffersizes_32k,
                "hantek-dso-2150.fw" },
        {       0x04b4, 0x2250, 0x04b5, 0x2250,
                "Hantek", "DSO-2250",
                buffersizes_512k,
                "hantek-dso-2250.fw" },
        {       0x04b4, 0x5200, 0x04b5, 0x5200,
                "Hantek", "DSO-5200",
                buffersizes_14k,
                "hantek-dso-5200.fw" },
        {       0x04b4, 0x520a, 0x04b5, 0x520a,
                "Hantek", "DSO-5200A",
                buffersizes_512k,
                "hantek-dso-5200A.fw" },
        ALL_ZERO
};

static const uint64_t timebases[][2] = {
        /* microseconds */
        { 10, 1000000 },
        { 20, 1000000 },
        { 40, 1000000 },
        { 100, 1000000 },
        { 200, 1000000 },
        { 400, 1000000 },
        /* milliseconds */
        { 1, 1000 },
        { 2, 1000 },
        { 4, 1000 },
        { 10, 1000 },
        { 20, 1000 },
        { 40, 1000 },
        { 100, 1000 },
        { 200, 1000 },
        { 400, 1000 },
};

static const uint64_t vdivs[][2] = {
        /* millivolts */
        { 10, 1000 },
        { 20, 1000 },
        { 50, 1000 },
        { 100, 1000 },
        { 200, 1000 },
        { 500, 1000 },
        /* volts */
        { 1, 1 },
        { 2, 1 },
        { 5, 1 },
};

static const char *trigger_sources[] = {
        "CH1",
        "CH2",
        "EXT",
        /* TODO: forced */
};

static const char *trigger_slopes[] = {
        "r",
        "f",
};

static const char *coupling[] = {
        "AC",
        "DC",
        "GND",
};

static int dev_acquisition_stop(struct sr_dev_inst *sdi);

static struct sr_dev_inst *dso_dev_new(const struct dso_profile *prof)
{
        struct sr_dev_inst *sdi;
        struct sr_channel *ch;
        struct sr_channel_group *cg;
        struct dev_context *devc;
        unsigned int i;

        sdi = g_malloc0(sizeof(struct sr_dev_inst));
        sdi->status = SR_ST_INITIALIZING;
        sdi->vendor = g_strdup(prof->vendor);
        sdi->model = g_strdup(prof->model);

        /*
         * Add only the real channels -- EXT isn't a source of data, only
         * a trigger source internal to the device.
         */
        for (i = 0; i < ARRAY_SIZE(channel_names); i++) {
                ch = sr_channel_new(sdi, i, SR_CHANNEL_ANALOG, TRUE, channel_names[i]);
                cg = g_malloc0(sizeof(struct sr_channel_group));
                cg->name = g_strdup(channel_names[i]);
                cg->channels = g_slist_append(cg->channels, ch);
                sdi->channel_groups = g_slist_append(sdi->channel_groups, cg);
        }

        devc = g_malloc0(sizeof(struct dev_context));
        devc->profile = prof;
        devc->dev_state = IDLE;
        devc->timebase = DEFAULT_TIMEBASE;
        devc->ch1_enabled = TRUE;
        devc->ch2_enabled = TRUE;
        devc->voltage[0] = DEFAULT_VOLTAGE;
        devc->voltage[1] = DEFAULT_VOLTAGE;
        devc->coupling[0] = DEFAULT_COUPLING;
        devc->coupling[1] = DEFAULT_COUPLING;
        devc->voffset_ch1 = DEFAULT_VERT_OFFSET;
        devc->voffset_ch2 = DEFAULT_VERT_OFFSET;
        devc->voffset_trigger = DEFAULT_VERT_TRIGGERPOS;
        devc->framesize = DEFAULT_FRAMESIZE;
        devc->triggerslope = SLOPE_POSITIVE;
        devc->triggersource = g_strdup(DEFAULT_TRIGGER_SOURCE);
        devc->triggerposition = DEFAULT_HORIZ_TRIGGERPOS;
        sdi->priv = devc;

        return sdi;
}

static int configure_channels(const struct sr_dev_inst *sdi)
{
        struct dev_context *devc;
        struct sr_channel *ch;
        const GSList *l;
        int p;

        devc = sdi->priv;

        g_slist_free(devc->enabled_channels);
        devc->ch1_enabled = devc->ch2_enabled = FALSE;
        for (l = sdi->channels, p = 0; l; l = l->next, p++) {
                ch = l->data;
                if (p == 0)
                        devc->ch1_enabled = ch->enabled;
                else
                        devc->ch2_enabled = ch->enabled;
                if (ch->enabled)
                        devc->enabled_channels = g_slist_append(devc->enabled_channels, ch);
        }

        return SR_OK;
}

static void clear_dev_context(void *priv)
{
        struct dev_context *devc;

        devc = priv;
        g_free(devc->triggersource);
        g_slist_free(devc->enabled_channels);

}

static int dev_clear(const struct sr_dev_driver *di)
{
        return std_dev_clear(di, clear_dev_context);
}

static GSList *scan(struct sr_dev_driver *di, GSList *options)
{
        struct drv_context *drvc;
        struct dev_context *devc;
        struct sr_dev_inst *sdi;
        struct sr_usb_dev_inst *usb;
        struct sr_config *src;
        const struct dso_profile *prof;
        GSList *l, *devices, *conn_devices;
        struct libusb_device_descriptor des;
        libusb_device **devlist;
        int i, j;
        const char *conn;
        char connection_id[64];

        drvc = di->context;

        devices = 0;

        conn = NULL;
        for (l = options; l; l = l->next) {
                src = l->data;
                if (src->key == SR_CONF_CONN) {
                        conn = g_variant_get_string(src->data, NULL);
                        break;
                }
        }
        if (conn)
                conn_devices = sr_usb_find(drvc->sr_ctx->libusb_ctx, conn);
        else
                conn_devices = NULL;

        /* Find all Hantek DSO devices and upload firmware to all of them. */
        libusb_get_device_list(drvc->sr_ctx->libusb_ctx, &devlist);
        for (i = 0; devlist[i]; i++) {
                if (conn) {
                        usb = NULL;
                        for (l = conn_devices; l; l = l->next) {
                                usb = l->data;
                                if (usb->bus == libusb_get_bus_number(devlist[i])
                                        && usb->address == libusb_get_device_address(devlist[i]))
                                        break;
                        }
                        if (!l)
                                /* This device matched none of the ones that
                                 * matched the conn specification. */
                                continue;
                }

                libusb_get_device_descriptor(devlist[i], &des);

                usb_get_port_path(devlist[i], connection_id, sizeof(connection_id));

                prof = NULL;
                for (j = 0; dev_profiles[j].orig_vid; j++) {
                        if (des.idVendor == dev_profiles[j].orig_vid
                                && des.idProduct == dev_profiles[j].orig_pid) {
                                /* Device matches the pre-firmware profile. */
                                prof = &dev_profiles[j];
                                sr_dbg("Found a %s %s.", prof->vendor, prof->model);
                                sdi = dso_dev_new(prof);
                                sdi->connection_id = g_strdup(connection_id);
                                devices = g_slist_append(devices, sdi);
                                devc = sdi->priv;
                                if (ezusb_upload_firmware(drvc->sr_ctx, devlist[i],
                                                USB_CONFIGURATION, prof->firmware) == SR_OK)
                                        /* Remember when the firmware on this device was updated */
                                        devc->fw_updated = g_get_monotonic_time();
                                else
                                        sr_err("Firmware upload failed");
                                /* Dummy USB address of 0xff will get overwritten later. */
                                sdi->conn = sr_usb_dev_inst_new(
                                                libusb_get_bus_number(devlist[i]), 0xff, NULL);
                                break;
                        } else if (des.idVendor == dev_profiles[j].fw_vid
                                && des.idProduct == dev_profiles[j].fw_pid) {
                                /* Device matches the post-firmware profile. */
                                prof = &dev_profiles[j];
                                sr_dbg("Found a %s %s.", prof->vendor, prof->model);
                                sdi = dso_dev_new(prof);
                                sdi->connection_id = g_strdup(connection_id);
                                sdi->status = SR_ST_INACTIVE;
                                devices = g_slist_append(devices, sdi);
                                sdi->inst_type = SR_INST_USB;
                                sdi->conn = sr_usb_dev_inst_new(
                                                libusb_get_bus_number(devlist[i]),
                                                libusb_get_device_address(devlist[i]), NULL);
                                break;
                        }
                }
                if (!prof)
                        /* not a supported VID/PID */
                        continue;
        }
        libusb_free_device_list(devlist, 1);

        return std_scan_complete(di, devices);
}

static int dev_open(struct sr_dev_inst *sdi)
{
        struct dev_context *devc;
        struct sr_usb_dev_inst *usb;
        int64_t timediff_us, timediff_ms;
        int err;

        devc = sdi->priv;
        usb = sdi->conn;

        /*
         * If the firmware was recently uploaded, wait up to MAX_RENUM_DELAY_MS
         * for the FX2 to renumerate.
         */
        err = SR_ERR;
        if (devc->fw_updated > 0) {
                sr_info("Waiting for device to reset.");
                /* Takes >= 300ms for the FX2 to be gone from the USB bus. */
                g_usleep(300 * 1000);
                timediff_ms = 0;
                while (timediff_ms < MAX_RENUM_DELAY_MS) {
                        if ((err = dso_open(sdi)) == SR_OK)
                                break;
                        g_usleep(100 * 1000);
                        timediff_us = g_get_monotonic_time() - devc->fw_updated;
                        timediff_ms = timediff_us / 1000;
                        sr_spew("Waited %" PRIi64 " ms.", timediff_ms);
                }
                sr_info("Device came back after %" PRIi64 " ms.", timediff_ms);
        } else {
                err = dso_open(sdi);
        }

        if (err != SR_OK) {
                sr_err("Unable to open device.");
                return SR_ERR;
        }

        err = libusb_claim_interface(usb->devhdl, USB_INTERFACE);
        if (err != 0) {
                sr_err("Unable to claim interface: %s.",
                           libusb_error_name(err));
                return SR_ERR;
        }

        return SR_OK;
}

static int dev_close(struct sr_dev_inst *sdi)
{
        dso_close(sdi);

        return SR_OK;
}

static int config_get(uint32_t key, GVariant **data, const struct sr_dev_inst *sdi,
                const struct sr_channel_group *cg)
{
        struct dev_context *devc;
        struct sr_usb_dev_inst *usb;
        char str[128];
        const char *s;
        const uint64_t *vdiv;
        int ch_idx;

        switch (key) {
        case SR_CONF_NUM_HDIV:
                *data = g_variant_new_int32(NUM_TIMEBASE);
                break;
        case SR_CONF_NUM_VDIV:
                *data = g_variant_new_int32(NUM_VDIV);
                break;
        }

        if (!sdi)
                return SR_ERR_ARG;

        devc = sdi->priv;
        if (!cg) {
                switch (key) {
                case SR_CONF_CONN:
                        if (!sdi->conn)
                                return SR_ERR_ARG;
                        usb = sdi->conn;
                        if (usb->address == 255)
                                /* Device still needs to re-enumerate after firmware
                                 * upload, so we don't know its (future) address. */
                                return SR_ERR;
                        snprintf(str, 128, "%d.%d", usb->bus, usb->address);
                        *data = g_variant_new_string(str);
                        break;
                case SR_CONF_TIMEBASE:
                        *data = g_variant_new("(tt)", timebases[devc->timebase][0],
                                        timebases[devc->timebase][1]);
                        break;
                case SR_CONF_BUFFERSIZE:
                        *data = g_variant_new_uint64(devc->framesize);
                        break;
                case SR_CONF_TRIGGER_SOURCE:
                        *data = g_variant_new_string(devc->triggersource);
                        break;
                case SR_CONF_TRIGGER_SLOPE:
                        s = (devc->triggerslope == SLOPE_POSITIVE) ? "r" : "f";
                        *data = g_variant_new_string(s);
                        break;
                case SR_CONF_HORIZ_TRIGGERPOS:
                        *data = g_variant_new_double(devc->triggerposition);
                        break;
                default:
                        return SR_ERR_NA;
                }
        } else {
                if (sdi->channel_groups->data == cg)
                        ch_idx = 0;
                else if (sdi->channel_groups->next->data == cg)
                        ch_idx = 1;
                else
                        return SR_ERR_ARG;
                switch (key) {
                case SR_CONF_FILTER:
                        *data = g_variant_new_boolean(devc->filter[ch_idx]);
                        break;
                case SR_CONF_VDIV:
                        vdiv = vdivs[devc->voltage[ch_idx]];
                        *data = g_variant_new("(tt)", vdiv[0], vdiv[1]);
                        break;
                case SR_CONF_COUPLING:
                        *data = g_variant_new_string(coupling[devc->coupling[ch_idx]]);
                        break;
                }
        }

        return SR_OK;
}

static int config_set(uint32_t key, GVariant *data, const struct sr_dev_inst *sdi,
                const struct sr_channel_group *cg)
{
        struct dev_context *devc;
        double tmp_double;
        uint64_t tmp_u64, p, q;
        int tmp_int, ch_idx, ret;
        unsigned int i;
        const char *tmp_str;

        if (sdi->status != SR_ST_ACTIVE)
                return SR_ERR_DEV_CLOSED;

        ret = SR_OK;
        devc = sdi->priv;
        if (!cg) {
                switch (key) {
                case SR_CONF_LIMIT_FRAMES:
                        devc->limit_frames = g_variant_get_uint64(data);
                        break;
                case SR_CONF_TRIGGER_SLOPE:
                        tmp_str = g_variant_get_string(data, NULL);
                        if (!tmp_str || !(tmp_str[0] == 'f' || tmp_str[0] == 'r'))
                                return SR_ERR_ARG;
                        devc->triggerslope = (tmp_str[0] == 'r')
                                ? SLOPE_POSITIVE : SLOPE_NEGATIVE;
                        break;
                case SR_CONF_HORIZ_TRIGGERPOS:
                        tmp_double = g_variant_get_double(data);
                        if (tmp_double < 0.0 || tmp_double > 1.0) {
                                sr_err("Trigger position should be between 0.0 and 1.0.");
                                ret = SR_ERR_ARG;
                        } else
                                devc->triggerposition = tmp_double;
                        break;
                case SR_CONF_BUFFERSIZE:
                        tmp_u64 = g_variant_get_uint64(data);
                        for (i = 0; i < NUM_BUFFER_SIZES; i++) {
                                if (devc->profile->buffersizes[i] == tmp_u64) {
                                        devc->framesize = tmp_u64;
                                        break;
                                }
                        }
                        if (i == NUM_BUFFER_SIZES)
                                ret = SR_ERR_ARG;
                        break;
                case SR_CONF_TIMEBASE:
                        g_variant_get(data, "(tt)", &p, &q);
                        tmp_int = -1;
                        for (i = 0; i < ARRAY_SIZE(timebases); i++) {
                                if (timebases[i][0] == p && timebases[i][1] == q) {
                                        tmp_int = i;
                                        break;
                                }
                        }
                        if (tmp_int >= 0)
                                devc->timebase = tmp_int;
                        else
                                ret = SR_ERR_ARG;
                        break;
                case SR_CONF_TRIGGER_SOURCE:
                        tmp_str = g_variant_get_string(data, NULL);
                        for (i = 0; trigger_sources[i]; i++) {
                                if (!strcmp(tmp_str, trigger_sources[i])) {
                                        devc->triggersource = g_strdup(tmp_str);
                                        break;
                                }
                        }
                        if (trigger_sources[i] == 0)
                                ret = SR_ERR_ARG;
                        break;
                default:
                        ret = SR_ERR_NA;
                        break;
                }
        } else {
                if (sdi->channel_groups->data == cg)
                        ch_idx = 0;
                else if (sdi->channel_groups->next->data == cg)
                        ch_idx = 1;
                else
                        return SR_ERR_ARG;
                switch (key) {
                case SR_CONF_FILTER:
                        devc->filter[ch_idx] = g_variant_get_boolean(data);
                        break;
                case SR_CONF_VDIV:
                        g_variant_get(data, "(tt)", &p, &q);
                        tmp_int = -1;
                        for (i = 0; i < ARRAY_SIZE(vdivs); i++) {
                                if (vdivs[i][0] == p && vdivs[i][1] == q) {
                                        tmp_int = i;
                                        break;
                                }
                        }
                        if (tmp_int >= 0) {
                                devc->voltage[ch_idx] = tmp_int;
                        } else
                                ret = SR_ERR_ARG;
                        break;
                case SR_CONF_COUPLING:
                        tmp_str = g_variant_get_string(data, NULL);
                        for (i = 0; coupling[i]; i++) {
                                if (!strcmp(tmp_str, coupling[i])) {
                                        devc->coupling[ch_idx] = i;
                                        break;
                                }
                        }
                        if (coupling[i] == 0)
                                ret = SR_ERR_ARG;
                        break;
                default:
                        ret = SR_ERR_NA;
                        break;
                }
        }

        return ret;
}

static int config_list(uint32_t key, GVariant **data, const struct sr_dev_inst *sdi,
                const struct sr_channel_group *cg)
{
        struct dev_context *devc;
        GVariant *tuple, *rational[2];
        GVariantBuilder gvb;
        unsigned int i;

        if (key == SR_CONF_SCAN_OPTIONS) {
                *data = g_variant_new_fixed_array(G_VARIANT_TYPE_UINT32,
                                scanopts, ARRAY_SIZE(scanopts), sizeof(uint32_t));
                return SR_OK;
        } else if (key == SR_CONF_DEVICE_OPTIONS && !sdi) {
                *data = g_variant_new_fixed_array(G_VARIANT_TYPE_UINT32,
                                drvopts, ARRAY_SIZE(drvopts), sizeof(uint32_t));
                return SR_OK;
        }

        if (!sdi)
                return SR_ERR_ARG;

        if (!cg) {
                switch (key) {
                case SR_CONF_DEVICE_OPTIONS:
                        *data = g_variant_new_fixed_array(G_VARIANT_TYPE_UINT32,
                                        devopts, ARRAY_SIZE(devopts), sizeof(uint32_t));
                        break;
                case SR_CONF_BUFFERSIZE:
                        if (!sdi)
                                return SR_ERR_ARG;
                        devc = sdi->priv;
                        *data = g_variant_new_fixed_array(G_VARIANT_TYPE_UINT64,
                                        devc->profile->buffersizes, NUM_BUFFER_SIZES, sizeof(uint64_t));
                        break;
                case SR_CONF_TIMEBASE:
                        g_variant_builder_init(&gvb, G_VARIANT_TYPE_ARRAY);
                        for (i = 0; i < ARRAY_SIZE(timebases); i++) {
                                rational[0] = g_variant_new_uint64(timebases[i][0]);
                                rational[1] = g_variant_new_uint64(timebases[i][1]);
                                tuple = g_variant_new_tuple(rational, 2);
                                g_variant_builder_add_value(&gvb, tuple);
                        }
                        *data = g_variant_builder_end(&gvb);
                        break;
                case SR_CONF_TRIGGER_SOURCE:
                        *data = g_variant_new_strv(trigger_sources,
                                        ARRAY_SIZE(trigger_sources));
                        break;
                case SR_CONF_TRIGGER_SLOPE:
                        *data = g_variant_new_strv(trigger_slopes,
                                        ARRAY_SIZE(trigger_slopes));
                        break;
                default:
                        return SR_ERR_NA;
                }
        } else {
                switch (key) {
                case SR_CONF_DEVICE_OPTIONS:
                        *data = g_variant_new_fixed_array(G_VARIANT_TYPE_UINT32,
                                        devopts_cg, ARRAY_SIZE(devopts_cg), sizeof(uint32_t));
                        break;
                case SR_CONF_COUPLING:
                        *data = g_variant_new_strv(coupling, ARRAY_SIZE(coupling));
                        break;
                case SR_CONF_VDIV:
                        g_variant_builder_init(&gvb, G_VARIANT_TYPE_ARRAY);
                        for (i = 0; i < ARRAY_SIZE(vdivs); i++) {
                                rational[0] = g_variant_new_uint64(vdivs[i][0]);
                                rational[1] = g_variant_new_uint64(vdivs[i][1]);
                                tuple = g_variant_new_tuple(rational, 2);
                                g_variant_builder_add_value(&gvb, tuple);
                        }
                        *data = g_variant_builder_end(&gvb);
                        break;
                default:
                        return SR_ERR_NA;
                }
        }

        return SR_OK;
}

static void send_chunk(struct sr_dev_inst *sdi, unsigned char *buf,
                int num_samples)
{
        struct sr_datafeed_packet packet;
        struct sr_datafeed_analog analog;
        struct sr_analog_encoding encoding;
        struct sr_analog_meaning meaning;
        struct sr_analog_spec spec;
        struct dev_context *devc;
        float ch1, ch2, range;
        int num_channels, data_offset;
        unsigned int i;

        devc = sdi->priv;
        num_channels = (devc->ch1_enabled && devc->ch2_enabled) ? 2 : 1;
        packet.type = SR_DF_ANALOG;
        packet.payload = &analog;
        /* TODO: support for 5xxx series 9-bit samples */
        sr_analog_init(&analog, &encoding, &meaning, &spec, 0);
        analog.meaning->channels = devc->enabled_channels;
        analog.num_samples = num_samples;
        analog.meaning->mq = SR_MQ_VOLTAGE;
        analog.meaning->unit = SR_UNIT_VOLT;
        analog.meaning->mqflags = 0;
        /* TODO: Check malloc return value. */
        analog.data = g_try_malloc(analog.num_samples * sizeof(float) * num_channels);
        data_offset = 0;
        for (i = 0; i < analog.num_samples; i++) {
                /*
                 * The device always sends data for both channels. If a channel
                 * is disabled, it contains a copy of the enabled channel's
                 * data. However, we only send the requested channels to
                 * the bus.
                 *
                 * Voltage values are encoded as a value 0-255 (0-512 on the
                 * DSO-5200*), where the value is a point in the range
                 * represented by the vdiv setting. There are 8 vertical divs,
                 * so e.g. 500mV/div represents 4V peak-to-peak where 0 = -2V
                 * and 255 = +2V.
                 */
                /* TODO: Support for DSO-5xxx series 9-bit samples. */
                if (devc->ch1_enabled) {
                        range = ((float)vdivs[devc->voltage[0]][0] / vdivs[devc->voltage[0]][1]) * 8;
                        ch1 = range / 255 * *(buf + i * 2 + 1);
                        /* Value is centered around 0V. */
                        ch1 -= range / 2;
                        ((float *)analog.data)[data_offset++] = ch1;
                }
                if (devc->ch2_enabled) {
                        range = ((float)vdivs[devc->voltage[1]][0] / vdivs[devc->voltage[1]][1]) * 8;
                        ch2 = range / 255 * *(buf + i * 2);
                        ch2 -= range / 2;
                        ((float *)analog.data)[data_offset++] = ch2;
                }
        }
        sr_session_send(sdi, &packet);
        g_free(analog.data);
}

/*
 * Called by libusb (as triggered by handle_event()) when a transfer comes in.
 * Only channel data comes in asynchronously, and all transfers for this are
 * queued up beforehand, so this just needs to chuck the incoming data onto
 * the libsigrok session bus.
 */
static void LIBUSB_CALL receive_transfer(struct libusb_transfer *transfer)
{
        struct sr_datafeed_packet packet;
        struct sr_dev_inst *sdi;
        struct dev_context *devc;
        int num_samples, pre;

        sdi = transfer->user_data;
        devc = sdi->priv;
        sr_spew("receive_transfer(): status %s received %d bytes.",
                libusb_error_name(transfer->status), transfer->actual_length);

        if (transfer->actual_length == 0)
                /* Nothing to send to the bus. */
                return;

        num_samples = transfer->actual_length / 2;

        sr_spew("Got %d-%d/%d samples in frame.", devc->samp_received + 1,
                   devc->samp_received + num_samples, devc->framesize);

        /*
         * The device always sends a full frame, but the beginning of the frame
         * doesn't represent the trigger point. The offset at which the trigger
         * happened came in with the capture state, so we need to start sending
         * from there up the session bus. The samples in the frame buffer
         * before that trigger point came after the end of the device's frame
         * buffer was reached, and it wrapped around to overwrite up until the
         * trigger point.
         */
        if (devc->samp_received < devc->trigger_offset) {
                /* Trigger point not yet reached. */
                if (devc->samp_received + num_samples < devc->trigger_offset) {
                        /* The entire chunk is before the trigger point. */
                        memcpy(devc->framebuf + devc->samp_buffered * 2,
                                        transfer->buffer, num_samples * 2);
                        devc->samp_buffered += num_samples;
                } else {
                        /*
                         * This chunk hits or overruns the trigger point.
                         * Store the part before the trigger fired, and
                         * send the rest up to the session bus.
                         */
                        pre = devc->trigger_offset - devc->samp_received;
                        memcpy(devc->framebuf + devc->samp_buffered * 2,
                                        transfer->buffer, pre * 2);
                        devc->samp_buffered += pre;

                        /* The rest of this chunk starts with the trigger point. */
                        sr_dbg("Reached trigger point, %d samples buffered.",
                                   devc->samp_buffered);

                        /* Avoid the corner case where the chunk ended at
                         * exactly the trigger point. */
                        if (num_samples > pre)
                                send_chunk(sdi, transfer->buffer + pre * 2,
                                                num_samples - pre);
                }
        } else {
                /* Already past the trigger point, just send it all out. */
                send_chunk(sdi, transfer->buffer, num_samples);
        }

        devc->samp_received += num_samples;

        /* Everything in this transfer was either copied to the buffer or
         * sent to the session bus. */
        g_free(transfer->buffer);
        libusb_free_transfer(transfer);

        if (devc->samp_received >= devc->framesize) {
                /* That was the last chunk in this frame. Send the buffered
                 * pre-trigger samples out now, in one big chunk. */
                sr_dbg("End of frame, sending %d pre-trigger buffered samples.",
                           devc->samp_buffered);
                send_chunk(sdi, devc->framebuf, devc->samp_buffered);

                /* Mark the end of this frame. */
                packet.type = SR_DF_FRAME_END;
                sr_session_send(sdi, &packet);

                if (devc->limit_frames && ++devc->num_frames == devc->limit_frames) {
                        /* Terminate session */
                        devc->dev_state = STOPPING;
                } else {
                        devc->dev_state = NEW_CAPTURE;
                }
        }
}

static int handle_event(int fd, int revents, void *cb_data)
{
        const struct sr_dev_inst *sdi;
        struct sr_datafeed_packet packet;
        struct timeval tv;
        struct sr_dev_driver *di;
        struct dev_context *devc;
        struct drv_context *drvc;
        int num_channels;
        uint32_t trigger_offset;
        uint8_t capturestate;

        (void)fd;
        (void)revents;

        sdi = cb_data;
        di = sdi->driver;
        drvc = di->context;
        devc = sdi->priv;
        if (devc->dev_state == STOPPING) {
                /* We've been told to wind up the acquisition. */
                sr_dbg("Stopping acquisition.");
                /*
                 * TODO: Doesn't really cancel pending transfers so they might
                 * come in after SR_DF_END is sent.
                 */
                usb_source_remove(sdi->session, drvc->sr_ctx);

                std_session_send_df_end(sdi);

                devc->dev_state = IDLE;

                return TRUE;
        }

        /* Always handle pending libusb events. */
        tv.tv_sec = tv.tv_usec = 0;
        libusb_handle_events_timeout(drvc->sr_ctx->libusb_ctx, &tv);

        /* TODO: ugh */
        if (devc->dev_state == NEW_CAPTURE) {
                if (dso_capture_start(sdi) != SR_OK)
                        return TRUE;
                if (dso_enable_trigger(sdi) != SR_OK)
                        return TRUE;
//              if (dso_force_trigger(sdi) != SR_OK)
//                      return TRUE;
                sr_dbg("Successfully requested next chunk.");
                devc->dev_state = CAPTURE;
                return TRUE;
        }
        if (devc->dev_state != CAPTURE)
                return TRUE;

        if ((dso_get_capturestate(sdi, &capturestate, &trigger_offset)) != SR_OK)
                return TRUE;

        sr_dbg("Capturestate %d.", capturestate);
        sr_dbg("Trigger offset 0x%.6x.", trigger_offset);
        switch (capturestate) {
        case CAPTURE_EMPTY:
                if (++devc->capture_empty_count >= MAX_CAPTURE_EMPTY) {
                        devc->capture_empty_count = 0;
                        if (dso_capture_start(sdi) != SR_OK)
                                break;
                        if (dso_enable_trigger(sdi) != SR_OK)
                                break;
//                      if (dso_force_trigger(sdi) != SR_OK)
//                              break;
                        sr_dbg("Successfully requested next chunk.");
                }
                break;
        case CAPTURE_FILLING:
                /* No data yet. */
                break;
        case CAPTURE_READY_8BIT:
                /* Remember where in the captured frame the trigger is. */
                devc->trigger_offset = trigger_offset;

                num_channels = (devc->ch1_enabled && devc->ch2_enabled) ? 2 : 1;
                devc->framebuf = g_malloc(devc->framesize * num_channels * 2);
                devc->samp_buffered = devc->samp_received = 0;

                /* Tell the scope to send us the first frame. */
                if (dso_get_channeldata(sdi, receive_transfer) != SR_OK)
                        break;

                /*
                 * Don't hit the state machine again until we're done fetching
                 * the data we just told the scope to send.
                 */
                devc->dev_state = FETCH_DATA;

                /* Tell the frontend a new frame is on the way. */
                packet.type = SR_DF_FRAME_BEGIN;
                sr_session_send(sdi, &packet);
                break;
        case CAPTURE_READY_9BIT:
                /* TODO */
                sr_err("Not yet supported.");
                break;
        case CAPTURE_TIMEOUT:
                /* Doesn't matter, we'll try again next time. */
                break;
        default:
                sr_dbg("Unknown capture state: %d.", capturestate);
                break;
        }

        return TRUE;
}

static int dev_acquisition_start(const struct sr_dev_inst *sdi)
{
        struct dev_context *devc;
        struct sr_dev_driver *di = sdi->driver;
        struct drv_context *drvc = di->context;

        if (sdi->status != SR_ST_ACTIVE)
                return SR_ERR_DEV_CLOSED;

        devc = sdi->priv;

        if (configure_channels(sdi) != SR_OK) {
                sr_err("Failed to configure channels.");
                return SR_ERR;
        }

        if (dso_init(sdi) != SR_OK)
                return SR_ERR;

        if (dso_capture_start(sdi) != SR_OK)
                return SR_ERR;

        devc->dev_state = CAPTURE;
        usb_source_add(sdi->session, drvc->sr_ctx, TICK, handle_event, (void *)sdi);

        std_session_send_df_header(sdi);

        return SR_OK;
}

static int dev_acquisition_stop(struct sr_dev_inst *sdi)
{
        struct dev_context *devc;

        if (sdi->status != SR_ST_ACTIVE)
                return SR_ERR;

        devc = sdi->priv;
        devc->dev_state = STOPPING;

        return SR_OK;
}

static struct sr_dev_driver hantek_dso_driver_info = {
        .name = "hantek-dso",
        .longname = "Hantek DSO",
        .api_version = 1,
        .init = std_init,
        .cleanup = std_cleanup,
        .scan = scan,
        .dev_list = std_dev_list,
        .dev_clear = dev_clear,
        .config_get = config_get,
        .config_set = config_set,
        .config_list = config_list,
        .dev_open = dev_open,
        .dev_close = dev_close,
        .dev_acquisition_start = dev_acquisition_start,
        .dev_acquisition_stop = dev_acquisition_stop,
        .context = NULL,
};
SR_REGISTER_DEV_DRIVER(hantek_dso_driver_info);