sigma: Use heap for datafeed packet and header.

[libsigrok.git] / hardware / asix-sigma / asix-sigma.c

/*
 * This file is part of the sigrok project.
 *
 * Copyright (C) 2010 Håvard Espeland <gus@ping.uio.no>,
 * Copyright (C) 2010 Martin Stensgård <mastensg@ping.uio.no>
 * Copyright (C) 2010 Carl Henrik Lunde <chlunde@ping.uio.no>
 *
 * 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/>.
 */

/*
 * ASIX SIGMA Logic Analyzer Driver
 */

#include <glib.h>
#include <glib/gstdio.h>
#include <ftdi.h>
#include <string.h>
#include <zlib.h>
#include "sigrok.h"
#include "sigrok-internal.h"
#include "asix-sigma.h"

#define USB_VENDOR                      0xa600
#define USB_PRODUCT                     0xa000
#define USB_DESCRIPTION                 "ASIX SIGMA"
#define USB_VENDOR_NAME                 "ASIX"
#define USB_MODEL_NAME                  "SIGMA"
#define USB_MODEL_VERSION               ""
#define TRIGGER_TYPES                   "rf10"
#define NUM_PROBES                      16

static GSList *dev_insts = NULL;

static uint64_t supported_samplerates[] = {
        SR_KHZ(200),
        SR_KHZ(250),
        SR_KHZ(500),
        SR_MHZ(1),
        SR_MHZ(5),
        SR_MHZ(10),
        SR_MHZ(25),
        SR_MHZ(50),
        SR_MHZ(100),
        SR_MHZ(200),
        0,
};

/*
 * Probe numbers seem to go from 1-16, according to this image:
 * http://tools.asix.net/img/sigma_sigmacab_pins_720.jpg
 * (the cable has two additional GND pins, and a TI and TO pin)
 */
static const char *probe_names[NUM_PROBES + 1] = {
        "1",
        "2",
        "3",
        "4",
        "5",
        "6",
        "7",
        "8",
        "9",
        "10",
        "11",
        "12",
        "13",
        "14",
        "15",
        "16",
        NULL,
};

static struct sr_samplerates samplerates = {
        0,
        0,
        0,
        supported_samplerates,
};

static int hwcaps[] = {
        SR_HWCAP_LOGIC_ANALYZER,
        SR_HWCAP_SAMPLERATE,
        SR_HWCAP_CAPTURE_RATIO,
        SR_HWCAP_PROBECONFIG,

        SR_HWCAP_LIMIT_MSEC,
        0,
};

/* Force the FPGA to reboot. */
static uint8_t suicide[] = {
        0x84, 0x84, 0x88, 0x84, 0x88, 0x84, 0x88, 0x84,
};

/* Prepare to upload firmware (FPGA specific). */
static uint8_t init[] = {
        0x03, 0x03, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
};

/* Initialize the logic analyzer mode. */
static uint8_t logic_mode_start[] = {
        0x00, 0x40, 0x0f, 0x25, 0x35, 0x40,
        0x2a, 0x3a, 0x40, 0x03, 0x20, 0x38,
};

static const char *firmware_files[] = {
        "asix-sigma-50.fw",     /* 50 MHz, supports 8 bit fractions */
        "asix-sigma-100.fw",    /* 100 MHz */
        "asix-sigma-200.fw",    /* 200 MHz */
        "asix-sigma-50sync.fw", /* Synchronous clock from pin */
        "asix-sigma-phasor.fw", /* Frequency counter */
};

static int hw_dev_acquisition_stop(int dev_index, void *cb_data);

static int sigma_read(void *buf, size_t size, struct context *ctx)
{
        int ret;

        ret = ftdi_read_data(&ctx->ftdic, (unsigned char *)buf, size);
        if (ret < 0) {
                sr_err("sigma: ftdi_read_data failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));
        }

        return ret;
}

static int sigma_write(void *buf, size_t size, struct context *ctx)
{
        int ret;

        ret = ftdi_write_data(&ctx->ftdic, (unsigned char *)buf, size);
        if (ret < 0) {
                sr_err("sigma: ftdi_write_data failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));
        } else if ((size_t) ret != size) {
                sr_err("sigma: ftdi_write_data did not complete write.");
        }

        return ret;
}

static int sigma_write_register(uint8_t reg, uint8_t *data, size_t len,
                                struct context *ctx)
{
        size_t i;
        uint8_t buf[len + 2];
        int idx = 0;

        buf[idx++] = REG_ADDR_LOW | (reg & 0xf);
        buf[idx++] = REG_ADDR_HIGH | (reg >> 4);

        for (i = 0; i < len; ++i) {
                buf[idx++] = REG_DATA_LOW | (data[i] & 0xf);
                buf[idx++] = REG_DATA_HIGH_WRITE | (data[i] >> 4);
        }

        return sigma_write(buf, idx, ctx);
}

static int sigma_set_register(uint8_t reg, uint8_t value, struct context *ctx)
{
        return sigma_write_register(reg, &value, 1, ctx);
}

static int sigma_read_register(uint8_t reg, uint8_t *data, size_t len,
                               struct context *ctx)
{
        uint8_t buf[3];

        buf[0] = REG_ADDR_LOW | (reg & 0xf);
        buf[1] = REG_ADDR_HIGH | (reg >> 4);
        buf[2] = REG_READ_ADDR;

        sigma_write(buf, sizeof(buf), ctx);

        return sigma_read(data, len, ctx);
}

static uint8_t sigma_get_register(uint8_t reg, struct context *ctx)
{
        uint8_t value;

        if (1 != sigma_read_register(reg, &value, 1, ctx)) {
                sr_err("sigma: sigma_get_register: 1 byte expected");
                return 0;
        }

        return value;
}

static int sigma_read_pos(uint32_t *stoppos, uint32_t *triggerpos,
                          struct context *ctx)
{
        uint8_t buf[] = {
                REG_ADDR_LOW | READ_TRIGGER_POS_LOW,

                REG_READ_ADDR | NEXT_REG,
                REG_READ_ADDR | NEXT_REG,
                REG_READ_ADDR | NEXT_REG,
                REG_READ_ADDR | NEXT_REG,
                REG_READ_ADDR | NEXT_REG,
                REG_READ_ADDR | NEXT_REG,
        };
        uint8_t result[6];

        sigma_write(buf, sizeof(buf), ctx);

        sigma_read(result, sizeof(result), ctx);

        *triggerpos = result[0] | (result[1] << 8) | (result[2] << 16);
        *stoppos = result[3] | (result[4] << 8) | (result[5] << 16);

        /* Not really sure why this must be done, but according to spec. */
        if ((--*stoppos & 0x1ff) == 0x1ff)
                stoppos -= 64;

        if ((*--triggerpos & 0x1ff) == 0x1ff)
                triggerpos -= 64;

        return 1;
}

static int sigma_read_dram(uint16_t startchunk, size_t numchunks,
                           uint8_t *data, struct context *ctx)
{
        size_t i;
        uint8_t buf[4096];
        int idx = 0;

        /* Send the startchunk. Index start with 1. */
        buf[0] = startchunk >> 8;
        buf[1] = startchunk & 0xff;
        sigma_write_register(WRITE_MEMROW, buf, 2, ctx);

        /* Read the DRAM. */
        buf[idx++] = REG_DRAM_BLOCK;
        buf[idx++] = REG_DRAM_WAIT_ACK;

        for (i = 0; i < numchunks; ++i) {
                /* Alternate bit to copy from DRAM to cache. */
                if (i != (numchunks - 1))
                        buf[idx++] = REG_DRAM_BLOCK | (((i + 1) % 2) << 4);

                buf[idx++] = REG_DRAM_BLOCK_DATA | ((i % 2) << 4);

                if (i != (numchunks - 1))
                        buf[idx++] = REG_DRAM_WAIT_ACK;
        }

        sigma_write(buf, idx, ctx);

        return sigma_read(data, numchunks * CHUNK_SIZE, ctx);
}

/* Upload trigger look-up tables to Sigma. */
static int sigma_write_trigger_lut(struct triggerlut *lut, struct context *ctx)
{
        int i;
        uint8_t tmp[2];
        uint16_t bit;

        /* Transpose the table and send to Sigma. */
        for (i = 0; i < 16; ++i) {
                bit = 1 << i;

                tmp[0] = tmp[1] = 0;

                if (lut->m2d[0] & bit)
                        tmp[0] |= 0x01;
                if (lut->m2d[1] & bit)
                        tmp[0] |= 0x02;
                if (lut->m2d[2] & bit)
                        tmp[0] |= 0x04;
                if (lut->m2d[3] & bit)
                        tmp[0] |= 0x08;

                if (lut->m3 & bit)
                        tmp[0] |= 0x10;
                if (lut->m3s & bit)
                        tmp[0] |= 0x20;
                if (lut->m4 & bit)
                        tmp[0] |= 0x40;

                if (lut->m0d[0] & bit)
                        tmp[1] |= 0x01;
                if (lut->m0d[1] & bit)
                        tmp[1] |= 0x02;
                if (lut->m0d[2] & bit)
                        tmp[1] |= 0x04;
                if (lut->m0d[3] & bit)
                        tmp[1] |= 0x08;

                if (lut->m1d[0] & bit)
                        tmp[1] |= 0x10;
                if (lut->m1d[1] & bit)
                        tmp[1] |= 0x20;
                if (lut->m1d[2] & bit)
                        tmp[1] |= 0x40;
                if (lut->m1d[3] & bit)
                        tmp[1] |= 0x80;

                sigma_write_register(WRITE_TRIGGER_SELECT0, tmp, sizeof(tmp),
                                     ctx);
                sigma_set_register(WRITE_TRIGGER_SELECT1, 0x30 | i, ctx);
        }

        /* Send the parameters */
        sigma_write_register(WRITE_TRIGGER_SELECT0, (uint8_t *) &lut->params,
                             sizeof(lut->params), ctx);

        return SR_OK;
}

/* Generate the bitbang stream for programming the FPGA. */
static int bin2bitbang(const char *filename,
                       unsigned char **buf, size_t *buf_size)
{
        FILE *f;
        long file_size;
        unsigned long offset = 0;
        unsigned char *p;
        uint8_t *compressed_buf, *firmware;
        uLongf csize, fwsize;
        const int buffer_size = 65536;
        size_t i;
        int c, ret, bit, v;
        uint32_t imm = 0x3f6df2ab;

        f = g_fopen(filename, "rb");
        if (!f) {
                sr_err("sigma: g_fopen(\"%s\", \"rb\")", filename);
                return SR_ERR;
        }

        if (-1 == fseek(f, 0, SEEK_END)) {
                sr_err("sigma: fseek on %s failed", filename);
                fclose(f);
                return SR_ERR;
        }

        file_size = ftell(f);

        fseek(f, 0, SEEK_SET);

        if (!(compressed_buf = g_try_malloc(file_size))) {
                sr_err("sigma: %s: compressed_buf malloc failed", __func__);
                fclose(f);
                return SR_ERR_MALLOC;
        }

        if (!(firmware = g_try_malloc(buffer_size))) {
                sr_err("sigma: %s: firmware malloc failed", __func__);
                fclose(f);
                g_free(compressed_buf);
                return SR_ERR_MALLOC;
        }

        csize = 0;
        while ((c = getc(f)) != EOF) {
                imm = (imm + 0xa853753) % 177 + (imm * 0x8034052);
                compressed_buf[csize++] = c ^ imm;
        }
        fclose(f);

        fwsize = buffer_size;
        ret = uncompress(firmware, &fwsize, compressed_buf, csize);
        if (ret < 0) {
                g_free(compressed_buf);
                g_free(firmware);
                sr_err("sigma: Could not unpack Sigma firmware. "
                       "(Error %d).", ret);
                return SR_ERR;
        }

        g_free(compressed_buf);

        *buf_size = fwsize * 2 * 8;

        *buf = p = (unsigned char *)g_try_malloc(*buf_size);
        if (!p) {
                sr_err("sigma: %s: buf/p malloc failed", __func__);
                g_free(compressed_buf);
                g_free(firmware);
                return SR_ERR_MALLOC;
        }

        for (i = 0; i < fwsize; ++i) {
                for (bit = 7; bit >= 0; --bit) {
                        v = firmware[i] & 1 << bit ? 0x40 : 0x00;
                        p[offset++] = v | 0x01;
                        p[offset++] = v;
                }
        }

        g_free(firmware);

        if (offset != *buf_size) {
                g_free(*buf);
                sr_err("sigma: Error reading firmware %s "
                       "offset=%ld, file_size=%ld, buf_size=%zd.",
                       filename, offset, file_size, *buf_size);

                return SR_ERR;
        }

        return SR_OK;
}

static int hw_init(const char *devinfo)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;

        /* Avoid compiler warnings. */
        (void)devinfo;

        if (!(ctx = g_try_malloc(sizeof(struct context)))) {
                sr_err("sigma: %s: ctx malloc failed", __func__);
                return 0; /* FIXME: Should be SR_ERR_MALLOC. */
        }

        ftdi_init(&ctx->ftdic);

        /* Look for SIGMAs. */
        if (ftdi_usb_open_desc(&ctx->ftdic, USB_VENDOR, USB_PRODUCT,
                               USB_DESCRIPTION, NULL) < 0)
                goto free;

        ctx->cur_samplerate = 0;
        ctx->period_ps = 0;
        ctx->limit_msec = 0;
        ctx->cur_firmware = -1;
        ctx->num_probes = 0;
        ctx->samples_per_event = 0;
        ctx->capture_ratio = 50;
        ctx->use_triggers = 0;

        /* Register SIGMA device. */
        if (!(sdi = sr_dev_inst_new(0, SR_ST_INITIALIZING, USB_VENDOR_NAME,
                                    USB_MODEL_NAME, USB_MODEL_VERSION))) {
                sr_err("sigma: %s: sdi was NULL", __func__);
                goto free;
        }

        sdi->priv = ctx;

        dev_insts = g_slist_append(dev_insts, sdi);

        /* We will open the device again when we need it. */
        ftdi_usb_close(&ctx->ftdic);

        return 1;

free:
        g_free(ctx);
        return 0;
}

static int upload_firmware(int firmware_idx, struct context *ctx)
{
        int ret;
        unsigned char *buf;
        unsigned char pins;
        size_t buf_size;
        unsigned char result[32];
        char firmware_path[128];

        /* Make sure it's an ASIX SIGMA. */
        if ((ret = ftdi_usb_open_desc(&ctx->ftdic,
                USB_VENDOR, USB_PRODUCT, USB_DESCRIPTION, NULL)) < 0) {
                sr_err("sigma: ftdi_usb_open failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));
                return 0;
        }

        if ((ret = ftdi_set_bitmode(&ctx->ftdic, 0xdf, BITMODE_BITBANG)) < 0) {
                sr_err("sigma: ftdi_set_bitmode failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));
                return 0;
        }

        /* Four times the speed of sigmalogan - Works well. */
        if ((ret = ftdi_set_baudrate(&ctx->ftdic, 750000)) < 0) {
                sr_err("sigma: ftdi_set_baudrate failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));
                return 0;
        }

        /* Force the FPGA to reboot. */
        sigma_write(suicide, sizeof(suicide), ctx);
        sigma_write(suicide, sizeof(suicide), ctx);
        sigma_write(suicide, sizeof(suicide), ctx);
        sigma_write(suicide, sizeof(suicide), ctx);

        /* Prepare to upload firmware (FPGA specific). */
        sigma_write(init, sizeof(init), ctx);

        ftdi_usb_purge_buffers(&ctx->ftdic);

        /* Wait until the FPGA asserts INIT_B. */
        while (1) {
                ret = sigma_read(result, 1, ctx);
                if (result[0] & 0x20)
                        break;
        }

        /* Prepare firmware. */
        snprintf(firmware_path, sizeof(firmware_path), "%s/%s", FIRMWARE_DIR,
                 firmware_files[firmware_idx]);

        if ((ret = bin2bitbang(firmware_path, &buf, &buf_size)) != SR_OK) {
                sr_err("sigma: An error occured while reading the firmware: %s",
                       firmware_path);
                return ret;
        }

        /* Upload firmare. */
        sigma_write(buf, buf_size, ctx);

        g_free(buf);

        if ((ret = ftdi_set_bitmode(&ctx->ftdic, 0x00, BITMODE_RESET)) < 0) {
                sr_err("sigma: ftdi_set_bitmode failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));
                return SR_ERR;
        }

        ftdi_usb_purge_buffers(&ctx->ftdic);

        /* Discard garbage. */
        while (1 == sigma_read(&pins, 1, ctx))
                ;

        /* Initialize the logic analyzer mode. */
        sigma_write(logic_mode_start, sizeof(logic_mode_start), ctx);

        /* Expect a 3 byte reply. */
        ret = sigma_read(result, 3, ctx);
        if (ret != 3 ||
            result[0] != 0xa6 || result[1] != 0x55 || result[2] != 0xaa) {
                sr_err("sigma: Configuration failed. Invalid reply received.");
                return SR_ERR;
        }

        ctx->cur_firmware = firmware_idx;

        return SR_OK;
}

static int hw_dev_open(int dev_index)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;
        int ret;

        if (!(sdi = sr_dev_inst_get(dev_insts, dev_index)))
                return SR_ERR;

        ctx = sdi->priv;

        /* Make sure it's an ASIX SIGMA. */
        if ((ret = ftdi_usb_open_desc(&ctx->ftdic,
                USB_VENDOR, USB_PRODUCT, USB_DESCRIPTION, NULL)) < 0) {

                sr_err("sigma: ftdi_usb_open failed: %s",
                       ftdi_get_error_string(&ctx->ftdic));

                return 0;
        }

        sdi->status = SR_ST_ACTIVE;

        return SR_OK;
}

static int set_samplerate(struct sr_dev_inst *sdi, uint64_t samplerate)
{
        int i, ret;
        struct context *ctx = sdi->priv;

        for (i = 0; supported_samplerates[i]; i++) {
                if (supported_samplerates[i] == samplerate)
                        break;
        }
        if (supported_samplerates[i] == 0)
                return SR_ERR_SAMPLERATE;

        if (samplerate <= SR_MHZ(50)) {
                ret = upload_firmware(0, ctx);
                ctx->num_probes = 16;
        }
        if (samplerate == SR_MHZ(100)) {
                ret = upload_firmware(1, ctx);
                ctx->num_probes = 8;
        }
        else if (samplerate == SR_MHZ(200)) {
                ret = upload_firmware(2, ctx);
                ctx->num_probes = 4;
        }

        ctx->cur_samplerate = samplerate;
        ctx->period_ps = 1000000000000 / samplerate;
        ctx->samples_per_event = 16 / ctx->num_probes;
        ctx->state.state = SIGMA_IDLE;

        sr_info("sigma: Firmware uploaded");

        return ret;
}

/*
 * In 100 and 200 MHz mode, only a single pin rising/falling can be
 * set as trigger. In other modes, two rising/falling triggers can be set,
 * in addition to value/mask trigger for any number of probes.
 *
 * The Sigma supports complex triggers using boolean expressions, but this
 * has not been implemented yet.
 */
static int configure_probes(struct sr_dev_inst *sdi, GSList *probes)
{
        struct context *ctx = sdi->priv;
        struct sr_probe *probe;
        GSList *l;
        int trigger_set = 0;
        int probebit;

        memset(&ctx->trigger, 0, sizeof(struct sigma_trigger));

        for (l = probes; l; l = l->next) {
                probe = (struct sr_probe *)l->data;
                probebit = 1 << (probe->index - 1);

                if (!probe->enabled || !probe->trigger)
                        continue;

                if (ctx->cur_samplerate >= SR_MHZ(100)) {
                        /* Fast trigger support. */
                        if (trigger_set) {
                                sr_err("sigma: ASIX SIGMA only supports a single "
                                       "pin trigger in 100 and 200MHz mode.");
                                return SR_ERR;
                        }
                        if (probe->trigger[0] == 'f')
                                ctx->trigger.fallingmask |= probebit;
                        else if (probe->trigger[0] == 'r')
                                ctx->trigger.risingmask |= probebit;
                        else {
                                sr_err("sigma: ASIX SIGMA only supports "
                                       "rising/falling trigger in 100 "
                                       "and 200MHz mode.");
                                return SR_ERR;
                        }

                        ++trigger_set;
                } else {
                        /* Simple trigger support (event). */
                        if (probe->trigger[0] == '1') {
                                ctx->trigger.simplevalue |= probebit;
                                ctx->trigger.simplemask |= probebit;
                        }
                        else if (probe->trigger[0] == '0') {
                                ctx->trigger.simplevalue &= ~probebit;
                                ctx->trigger.simplemask |= probebit;
                        }
                        else if (probe->trigger[0] == 'f') {
                                ctx->trigger.fallingmask |= probebit;
                                ++trigger_set;
                        }
                        else if (probe->trigger[0] == 'r') {
                                ctx->trigger.risingmask |= probebit;
                                ++trigger_set;
                        }

                        /*
                         * Actually, Sigma supports 2 rising/falling triggers,
                         * but they are ORed and the current trigger syntax
                         * does not permit ORed triggers.
                         */
                        if (trigger_set > 1) {
                                sr_err("sigma: ASIX SIGMA only supports 1 "
                                       "rising/falling triggers.");
                                return SR_ERR;
                        }
                }

                if (trigger_set)
                        ctx->use_triggers = 1;
        }

        return SR_OK;
}

static int hw_dev_close(int dev_index)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;

        if (!(sdi = sr_dev_inst_get(dev_insts, dev_index))) {
                sr_err("sigma: %s: sdi was NULL", __func__);
                return SR_ERR_BUG;
        }

        if (!(ctx = sdi->priv)) {
                sr_err("sigma: %s: sdi->priv was NULL", __func__);
                return SR_ERR_BUG;
        }

        /* TODO */
        if (sdi->status == SR_ST_ACTIVE)
                ftdi_usb_close(&ctx->ftdic);

        sdi->status = SR_ST_INACTIVE;

        return SR_OK;
}

static int hw_cleanup(void)
{
        GSList *l;
        struct sr_dev_inst *sdi;
        int ret = SR_OK;

        /* Properly close all devices. */
        for (l = dev_insts; l; l = l->next) {
                if (!(sdi = l->data)) {
                        /* Log error, but continue cleaning up the rest. */
                        sr_err("sigma: %s: sdi was NULL, continuing", __func__);
                        ret = SR_ERR_BUG;
                        continue;
                }
                sr_dev_inst_free(sdi);
        }
        g_slist_free(dev_insts);
        dev_insts = NULL;

        return ret;
}

static void *hw_dev_info_get(int dev_index, int dev_info_id)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;
        void *info = NULL;

        if (!(sdi = sr_dev_inst_get(dev_insts, dev_index))) {
                sr_err("sigma: %s: sdi was NULL", __func__);
                return NULL;
        }

        ctx = sdi->priv;

        switch (dev_info_id) {
        case SR_DI_INST:
                info = sdi;
                break;
        case SR_DI_NUM_PROBES:
                info = GINT_TO_POINTER(NUM_PROBES);
                break;
        case SR_DI_PROBE_NAMES:
                info = probe_names;
                break;
        case SR_DI_SAMPLERATES:
                info = &samplerates;
                break;
        case SR_DI_TRIGGER_TYPES:
                info = (char *)TRIGGER_TYPES;
                break;
        case SR_DI_CUR_SAMPLERATE:
                info = &ctx->cur_samplerate;
                break;
        }

        return info;
}

static int hw_dev_status_get(int dev_index)
{
        struct sr_dev_inst *sdi;

        sdi = sr_dev_inst_get(dev_insts, dev_index);
        if (sdi)
                return sdi->status;
        else
                return SR_ST_NOT_FOUND;
}

static int *hw_hwcap_get_all(void)
{
        return hwcaps;
}

static int hw_dev_config_set(int dev_index, int hwcap, void *value)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;
        int ret;

        if (!(sdi = sr_dev_inst_get(dev_insts, dev_index)))
                return SR_ERR;

        ctx = sdi->priv;

        if (hwcap == SR_HWCAP_SAMPLERATE) {
                ret = set_samplerate(sdi, *(uint64_t *)value);
        } else if (hwcap == SR_HWCAP_PROBECONFIG) {
                ret = configure_probes(sdi, value);
        } else if (hwcap == SR_HWCAP_LIMIT_MSEC) {
                ctx->limit_msec = *(uint64_t *)value;
                if (ctx->limit_msec > 0)
                        ret = SR_OK;
                else
                        ret = SR_ERR;
        } else if (hwcap == SR_HWCAP_CAPTURE_RATIO) {
                ctx->capture_ratio = *(uint64_t *)value;
                if (ctx->capture_ratio < 0 || ctx->capture_ratio > 100)
                        ret = SR_ERR;
                else
                        ret = SR_OK;
        } else {
                ret = SR_ERR;
        }

        return ret;
}

/* Software trigger to determine exact trigger position. */
static int get_trigger_offset(uint16_t *samples, uint16_t last_sample,
                              struct sigma_trigger *t)
{
        int i;

        for (i = 0; i < 8; ++i) {
                if (i > 0)
                        last_sample = samples[i-1];

                /* Simple triggers. */
                if ((samples[i] & t->simplemask) != t->simplevalue)
                        continue;

                /* Rising edge. */
                if ((last_sample & t->risingmask) != 0 || (samples[i] &
                    t->risingmask) != t->risingmask)
                        continue;

                /* Falling edge. */
                if ((last_sample & t->fallingmask) != t->fallingmask ||
                    (samples[i] & t->fallingmask) != 0)
                        continue;

                break;
        }

        /* If we did not match, return original trigger pos. */
        return i & 0x7;
}

/*
 * Decode chunk of 1024 bytes, 64 clusters, 7 events per cluster.
 * Each event is 20ns apart, and can contain multiple samples.
 *
 * For 200 MHz, events contain 4 samples for each channel, spread 5 ns apart.
 * For 100 MHz, events contain 2 samples for each channel, spread 10 ns apart.
 * For 50 MHz and below, events contain one sample for each channel,
 * spread 20 ns apart.
 */
static int decode_chunk_ts(uint8_t *buf, uint16_t *lastts,
                           uint16_t *lastsample, int triggerpos,
                           uint16_t limit_chunk, void *cb_data)
{
        struct sr_dev_inst *sdi = cb_data;
        struct context *ctx = sdi->priv;
        uint16_t tsdiff, ts;
        uint16_t samples[65536 * ctx->samples_per_event];
        struct sr_datafeed_packet packet;
        struct sr_datafeed_logic logic;
        int i, j, k, l, numpad, tosend;
        size_t n = 0, sent = 0;
        int clustersize = EVENTS_PER_CLUSTER * ctx->samples_per_event;
        uint16_t *event;
        uint16_t cur_sample;
        int triggerts = -1;

        /* Check if trigger is in this chunk. */
        if (triggerpos != -1) {
                if (ctx->cur_samplerate <= SR_MHZ(50))
                        triggerpos -= EVENTS_PER_CLUSTER - 1;

                if (triggerpos < 0)
                        triggerpos = 0;

                /* Find in which cluster the trigger occured. */
                triggerts = triggerpos / 7;
        }

        /* For each ts. */
        for (i = 0; i < 64; ++i) {
                ts = *(uint16_t *) &buf[i * 16];
                tsdiff = ts - *lastts;
                *lastts = ts;

                /* Decode partial chunk. */
                if (limit_chunk && ts > limit_chunk)
                        return SR_OK;

                /* Pad last sample up to current point. */
                numpad = tsdiff * ctx->samples_per_event - clustersize;
                if (numpad > 0) {
                        for (j = 0; j < numpad; ++j)
                                samples[j] = *lastsample;

                        n = numpad;
                }

                /* Send samples between previous and this timestamp to sigrok. */
                sent = 0;
                while (sent < n) {
                        tosend = MIN(2048, n - sent);

                        packet.type = SR_DF_LOGIC;
                        packet.payload = &logic;
                        logic.length = tosend * sizeof(uint16_t);
                        logic.unitsize = 2;
                        logic.data = samples + sent;
                        sr_session_send(ctx->session_dev_id, &packet);

                        sent += tosend;
                }
                n = 0;

                event = (uint16_t *) &buf[i * 16 + 2];
                cur_sample = 0;

                /* For each event in cluster. */
                for (j = 0; j < 7; ++j) {

                        /* For each sample in event. */
                        for (k = 0; k < ctx->samples_per_event; ++k) {
                                cur_sample = 0;

                                /* For each probe. */
                                for (l = 0; l < ctx->num_probes; ++l)
                                        cur_sample |= (!!(event[j] & (1 << (l *
                                           ctx->samples_per_event + k)))) << l;

                                samples[n++] = cur_sample;
                        }
                }

                /* Send data up to trigger point (if triggered). */
                sent = 0;
                if (i == triggerts) {
                        /*
                         * Trigger is not always accurate to sample because of
                         * pipeline delay. However, it always triggers before
                         * the actual event. We therefore look at the next
                         * samples to pinpoint the exact position of the trigger.
                         */
                        tosend = get_trigger_offset(samples, *lastsample,
                                                    &ctx->trigger);

                        if (tosend > 0) {
                                packet.type = SR_DF_LOGIC;
                                packet.payload = &logic;
                                logic.length = tosend * sizeof(uint16_t);
                                logic.unitsize = 2;
                                logic.data = samples;
                                sr_session_send(ctx->session_dev_id, &packet);

                                sent += tosend;
                        }

                        /* Only send trigger if explicitly enabled. */
                        if (ctx->use_triggers) {
                                packet.type = SR_DF_TRIGGER;
                                sr_session_send(ctx->session_dev_id, &packet);
                        }
                }

                /* Send rest of the chunk to sigrok. */
                tosend = n - sent;

                if (tosend > 0) {
                        packet.type = SR_DF_LOGIC;
                        packet.payload = &logic;
                        logic.length = tosend * sizeof(uint16_t);
                        logic.unitsize = 2;
                        logic.data = samples + sent;
                        sr_session_send(ctx->session_dev_id, &packet);
                }

                *lastsample = samples[n - 1];
        }

        return SR_OK;
}

static int receive_data(int fd, int revents, void *cb_data)
{
        struct sr_dev_inst *sdi = cb_data;
        struct context *ctx = sdi->priv;
        struct sr_datafeed_packet packet;
        const int chunks_per_read = 32;
        unsigned char buf[chunks_per_read * CHUNK_SIZE];
        int bufsz, numchunks, i, newchunks;
        uint64_t running_msec;
        struct timeval tv;

        /* Avoid compiler warnings. */
        (void)fd;
        (void)revents;

        /* Get the current position. */
        sigma_read_pos(&ctx->state.stoppos, &ctx->state.triggerpos, ctx);

        numchunks = (ctx->state.stoppos + 511) / 512;

        if (ctx->state.state == SIGMA_IDLE)
                return TRUE;

        if (ctx->state.state == SIGMA_CAPTURE) {
                /* Check if the timer has expired, or memory is full. */
                gettimeofday(&tv, 0);
                running_msec = (tv.tv_sec - ctx->start_tv.tv_sec) * 1000 +
                        (tv.tv_usec - ctx->start_tv.tv_usec) / 1000;

                if (running_msec < ctx->limit_msec && numchunks < 32767)
                        return TRUE; /* While capturing... */
                else {

                hw_dev_acquisition_stop(sdi->index, sdi);

        } else if (ctx->state.state == SIGMA_DOWNLOAD) {
                if (ctx->state.chunks_downloaded >= numchunks) {
                        /* End of samples. */
                        packet.type = SR_DF_END;
                        sr_session_send(ctx->session_dev_id, &packet);

                        ctx->state.state = SIGMA_IDLE;

                        return TRUE;
                }

                newchunks = MIN(chunks_per_read,
                                numchunks - ctx->state.chunks_downloaded);

                sr_info("sigma: Downloading sample data: %.0f %%",
                        100.0 * ctx->state.chunks_downloaded / numchunks);

                bufsz = sigma_read_dram(ctx->state.chunks_downloaded,
                                        newchunks, buf, ctx);
                /* TODO: Check bufsz. For now, just avoid compiler warnings. */
                (void)bufsz;

                /* Find first ts. */
                if (ctx->state.chunks_downloaded == 0) {
                        ctx->state.lastts = *(uint16_t *) buf - 1;
                        ctx->state.lastsample = 0;
                }

                /* Decode chunks and send them to sigrok. */
                for (i = 0; i < newchunks; ++i) {
                        int limit_chunk = 0;

                        /* The last chunk may potentially be only in part. */
                        if (ctx->state.chunks_downloaded == numchunks - 1) {
                                /* Find the last valid timestamp */
                                limit_chunk = ctx->state.stoppos % 512 + ctx->state.lastts;
                        }

                        if (ctx->state.chunks_downloaded + i == ctx->state.triggerchunk)
                                decode_chunk_ts(buf + (i * CHUNK_SIZE),
                                                &ctx->state.lastts,
                                                &ctx->state.lastsample,
                                                ctx->state.triggerpos & 0x1ff,
                                                limit_chunk, sdi);
                        else
                                decode_chunk_ts(buf + (i * CHUNK_SIZE),
                                                &ctx->state.lastts,
                                                &ctx->state.lastsample,
                                                -1, limit_chunk, sdi);

                        ++ctx->state.chunks_downloaded;
                }
        }

        return TRUE;
}

/* Build a LUT entry used by the trigger functions. */
static void build_lut_entry(uint16_t value, uint16_t mask, uint16_t *entry)
{
        int i, j, k, bit;

        /* For each quad probe. */
        for (i = 0; i < 4; ++i) {
                entry[i] = 0xffff;

                /* For each bit in LUT. */
                for (j = 0; j < 16; ++j)

                        /* For each probe in quad. */
                        for (k = 0; k < 4; ++k) {
                                bit = 1 << (i * 4 + k);

                                /* Set bit in entry */
                                if ((mask & bit) &&
                                    ((!(value & bit)) !=
                                    (!(j & (1 << k)))))
                                        entry[i] &= ~(1 << j);
                        }
        }
}

/* Add a logical function to LUT mask. */
static void add_trigger_function(enum triggerop oper, enum triggerfunc func,
                                 int index, int neg, uint16_t *mask)
{
        int i, j;
        int x[2][2], tmp, a, b, aset, bset, rset;

        memset(x, 0, 4 * sizeof(int));

        /* Trigger detect condition. */
        switch (oper) {
        case OP_LEVEL:
                x[0][1] = 1;
                x[1][1] = 1;
                break;
        case OP_NOT:
                x[0][0] = 1;
                x[1][0] = 1;
                break;
        case OP_RISE:
                x[0][1] = 1;
                break;
        case OP_FALL:
                x[1][0] = 1;
                break;
        case OP_RISEFALL:
                x[0][1] = 1;
                x[1][0] = 1;
                break;
        case OP_NOTRISE:
                x[1][1] = 1;
                x[0][0] = 1;
                x[1][0] = 1;
                break;
        case OP_NOTFALL:
                x[1][1] = 1;
                x[0][0] = 1;
                x[0][1] = 1;
                break;
        case OP_NOTRISEFALL:
                x[1][1] = 1;
                x[0][0] = 1;
                break;
        }

        /* Transpose if neg is set. */
        if (neg) {
                for (i = 0; i < 2; ++i) {
                        for (j = 0; j < 2; ++j) {
                                tmp = x[i][j];
                                x[i][j] = x[1-i][1-j];
                                x[1-i][1-j] = tmp;
                        }
                }
        }

        /* Update mask with function. */
        for (i = 0; i < 16; ++i) {
                a = (i >> (2 * index + 0)) & 1;
                b = (i >> (2 * index + 1)) & 1;

                aset = (*mask >> i) & 1;
                bset = x[b][a];

                if (func == FUNC_AND || func == FUNC_NAND)
                        rset = aset & bset;
                else if (func == FUNC_OR || func == FUNC_NOR)
                        rset = aset | bset;
                else if (func == FUNC_XOR || func == FUNC_NXOR)
                        rset = aset ^ bset;

                if (func == FUNC_NAND || func == FUNC_NOR || func == FUNC_NXOR)
                        rset = !rset;

                *mask &= ~(1 << i);

                if (rset)
                        *mask |= 1 << i;
        }
}

/*
 * Build trigger LUTs used by 50 MHz and lower sample rates for supporting
 * simple pin change and state triggers. Only two transitions (rise/fall) can be
 * set at any time, but a full mask and value can be set (0/1).
 */
static int build_basic_trigger(struct triggerlut *lut, struct context *ctx)
{
        int i,j;
        uint16_t masks[2] = { 0, 0 };

        memset(lut, 0, sizeof(struct triggerlut));

        /* Contant for simple triggers. */
        lut->m4 = 0xa000;

        /* Value/mask trigger support. */
        build_lut_entry(ctx->trigger.simplevalue, ctx->trigger.simplemask,
                        lut->m2d);

        /* Rise/fall trigger support. */
        for (i = 0, j = 0; i < 16; ++i) {
                if (ctx->trigger.risingmask & (1 << i) ||
                    ctx->trigger.fallingmask & (1 << i))
                        masks[j++] = 1 << i;
        }

        build_lut_entry(masks[0], masks[0], lut->m0d);
        build_lut_entry(masks[1], masks[1], lut->m1d);

        /* Add glue logic */
        if (masks[0] || masks[1]) {
                /* Transition trigger. */
                if (masks[0] & ctx->trigger.risingmask)
                        add_trigger_function(OP_RISE, FUNC_OR, 0, 0, &lut->m3);
                if (masks[0] & ctx->trigger.fallingmask)
                        add_trigger_function(OP_FALL, FUNC_OR, 0, 0, &lut->m3);
                if (masks[1] & ctx->trigger.risingmask)
                        add_trigger_function(OP_RISE, FUNC_OR, 1, 0, &lut->m3);
                if (masks[1] & ctx->trigger.fallingmask)
                        add_trigger_function(OP_FALL, FUNC_OR, 1, 0, &lut->m3);
        } else {
                /* Only value/mask trigger. */
                lut->m3 = 0xffff;
        }

        /* Triggertype: event. */
        lut->params.selres = 3;

        return SR_OK;
}

static int hw_dev_acquisition_start(int dev_index, void *cb_data)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;
        struct sr_datafeed_packet *packet;
        struct sr_datafeed_header *header;
        struct clockselect_50 clockselect;
        int frac, triggerpin, ret;
        uint8_t triggerselect;
        struct triggerinout triggerinout_conf;
        struct triggerlut lut;

        if (!(sdi = sr_dev_inst_get(dev_insts, dev_index)))
                return SR_ERR;

        ctx = sdi->priv;

        /* If the samplerate has not been set, default to 200 kHz. */
        if (ctx->cur_firmware == -1) {
                if ((ret = set_samplerate(sdi, SR_KHZ(200))) != SR_OK)
                        return ret;
        }

        /* Enter trigger programming mode. */
        sigma_set_register(WRITE_TRIGGER_SELECT1, 0x20, ctx);

        /* 100 and 200 MHz mode. */
        if (ctx->cur_samplerate >= SR_MHZ(100)) {
                sigma_set_register(WRITE_TRIGGER_SELECT1, 0x81, ctx);

                /* Find which pin to trigger on from mask. */
                for (triggerpin = 0; triggerpin < 8; ++triggerpin)
                        if ((ctx->trigger.risingmask | ctx->trigger.fallingmask) &
                            (1 << triggerpin))
                                break;

                /* Set trigger pin and light LED on trigger. */
                triggerselect = (1 << LEDSEL1) | (triggerpin & 0x7);

                /* Default rising edge. */
                if (ctx->trigger.fallingmask)
                        triggerselect |= 1 << 3;

        /* All other modes. */
        } else if (ctx->cur_samplerate <= SR_MHZ(50)) {
                build_basic_trigger(&lut, ctx);

                sigma_write_trigger_lut(&lut, ctx);

                triggerselect = (1 << LEDSEL1) | (1 << LEDSEL0);
        }

        /* Setup trigger in and out pins to default values. */
        memset(&triggerinout_conf, 0, sizeof(struct triggerinout));
        triggerinout_conf.trgout_bytrigger = 1;
        triggerinout_conf.trgout_enable = 1;

        sigma_write_register(WRITE_TRIGGER_OPTION,
                             (uint8_t *) &triggerinout_conf,
                             sizeof(struct triggerinout), ctx);

        /* Go back to normal mode. */
        sigma_set_register(WRITE_TRIGGER_SELECT1, triggerselect, ctx);

        /* Set clock select register. */
        if (ctx->cur_samplerate == SR_MHZ(200))
                /* Enable 4 probes. */
                sigma_set_register(WRITE_CLOCK_SELECT, 0xf0, ctx);
        else if (ctx->cur_samplerate == SR_MHZ(100))
                /* Enable 8 probes. */
                sigma_set_register(WRITE_CLOCK_SELECT, 0x00, ctx);
        else {
                /*
                 * 50 MHz mode (or fraction thereof). Any fraction down to
                 * 50 MHz / 256 can be used, but is not supported by sigrok API.
                 */
                frac = SR_MHZ(50) / ctx->cur_samplerate - 1;

                clockselect.async = 0;
                clockselect.fraction = frac;
                clockselect.disabled_probes = 0;

                sigma_write_register(WRITE_CLOCK_SELECT,
                                     (uint8_t *) &clockselect,
                                     sizeof(clockselect), ctx);
        }

        /* Setup maximum post trigger time. */
        sigma_set_register(WRITE_POST_TRIGGER,
                        (ctx->capture_ratio * 255) / 100, ctx);

        /* Start acqusition. */
        gettimeofday(&ctx->start_tv, 0);
        sigma_set_register(WRITE_MODE, 0x0d, ctx);

        ctx->session_dev_id = cb_data;

        if (!(packet = g_try_malloc(sizeof(struct sr_datafeed_packet)))) {
                sr_err("sigma: %s: packet malloc failed.", __func__);
                return SR_ERR_MALLOC;
        }

        if (!(header = g_try_malloc(sizeof(struct sr_datafeed_header)))) {
                sr_err("sigma: %s: header malloc failed.", __func__);
                return SR_ERR_MALLOC;
        }

        /* Add capture source. */
        sr_source_add(0, G_IO_IN, 10, receive_data, sdi);

        /* Send header packet to the session bus. */
        packet->type = SR_DF_HEADER;
        packet->payload = header;
        header->feed_version = 1;
        gettimeofday(&header->starttime, NULL);
        header->samplerate = ctx->cur_samplerate;
        header->num_logic_probes = ctx->num_probes;
        sr_session_send(ctx->session_dev_id, packet);
        g_free(header);
        g_free(packet);

        ctx->state.state = SIGMA_CAPTURE;

        return SR_OK;
}

static int hw_dev_acquisition_stop(int dev_index, void *cb_data)
{
        struct sr_dev_inst *sdi;
        struct context *ctx;
        uint8_t modestatus;

        /* Avoid compiler warnings. */
        (void)cb_data;

        if (!(sdi = sr_dev_inst_get(dev_insts, dev_index))) {
                sr_err("sigma: %s: sdi was NULL", __func__);
                return SR_ERR_BUG;
        }

        if (!(ctx = sdi->priv)) {
                sr_err("sigma: %s: sdi->priv was NULL", __func__);
                return SR_ERR_BUG;
        }

        /* Stop acquisition. */
        sigma_set_register(WRITE_MODE, 0x11, ctx);

        /* Set SDRAM Read Enable. */
        sigma_set_register(WRITE_MODE, 0x02, ctx);

        /* Get the current position. */
        sigma_read_pos(&ctx->state.stoppos, &ctx->state.triggerpos, ctx);

        /* Check if trigger has fired. */
        modestatus = sigma_get_register(READ_MODE, ctx);
        if (modestatus & 0x20)
                ctx->state.triggerchunk = ctx->state.triggerpos / 512;
        else
                ctx->state.triggerchunk = -1;

        ctx->state.chunks_downloaded = 0;

        ctx->state.state = SIGMA_DOWNLOAD;

        return SR_OK;
}

SR_PRIV struct sr_dev_driver asix_sigma_driver_info = {
        .name = "asix-sigma",
        .longname = "ASIX SIGMA",
        .api_version = 1,
        .init = hw_init,
        .cleanup = hw_cleanup,
        .dev_open = hw_dev_open,
        .dev_close = hw_dev_close,
        .dev_info_get = hw_dev_info_get,
        .dev_status_get = hw_dev_status_get,
        .hwcap_get_all = hw_hwcap_get_all,
        .dev_config_set = hw_dev_config_set,
        .dev_acquisition_start = hw_dev_acquisition_start,
        .dev_acquisition_stop = hw_dev_acquisition_stop,
};