/* * This file is part of the libsigrok project. * * Copyright (C) 2013 Marcus Comstedt * Copyright (C) 2013 Bert Vermeulen * Copyright (C) 2012 Joel Holdsworth * * 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 . */ #include "protocol.h" #include #include #include #include #include #include #include #include "libsigrok.h" #include "libsigrok-internal.h" #define FPGA_FIRMWARE_18 FIRMWARE_DIR"/saleae-logic16-fpga-18.bitstream" #define FPGA_FIRMWARE_33 FIRMWARE_DIR"/saleae-logic16-fpga-33.bitstream" #define MAX_SAMPLE_RATE SR_MHZ(100) #define MAX_4CH_SAMPLE_RATE SR_MHZ(50) #define MAX_7CH_SAMPLE_RATE SR_MHZ(40) #define MAX_8CH_SAMPLE_RATE SR_MHZ(32) #define MAX_10CH_SAMPLE_RATE SR_MHZ(25) #define MAX_13CH_SAMPLE_RATE SR_MHZ(16) #define BASE_CLOCK_0_FREQ SR_MHZ(100) #define BASE_CLOCK_1_FREQ SR_MHZ(160) #define COMMAND_START_ACQUISITION 1 #define COMMAND_ABORT_ACQUISITION_ASYNC 2 #define COMMAND_WRITE_EEPROM 6 #define COMMAND_READ_EEPROM 7 #define COMMAND_WRITE_LED_TABLE 0x7a #define COMMAND_SET_LED_MODE 0x7b #define COMMAND_RETURN_TO_BOOTLOADER 0x7c #define COMMAND_ABORT_ACQUISITION_SYNC 0x7d #define COMMAND_FPGA_UPLOAD_INIT 0x7e #define COMMAND_FPGA_UPLOAD_SEND_DATA 0x7f #define COMMAND_FPGA_WRITE_REGISTER 0x80 #define COMMAND_FPGA_READ_REGISTER 0x81 #define COMMAND_GET_REVID 0x82 #define WRITE_EEPROM_COOKIE1 0x42 #define WRITE_EEPROM_COOKIE2 0x55 #define READ_EEPROM_COOKIE1 0x33 #define READ_EEPROM_COOKIE2 0x81 #define ABORT_ACQUISITION_SYNC_PATTERN 0x55 #define MAX_EMPTY_TRANSFERS 64 static void encrypt(uint8_t *dest, const uint8_t *src, uint8_t cnt) { uint8_t state1 = 0x9b, state2 = 0x54; uint8_t t, v; int i; for (i = 0; i < cnt; i++) { v = src[i]; t = (((v ^ state2 ^ 0x2b) - 0x05) ^ 0x35) - 0x39; t = (((t ^ state1 ^ 0x5a) - 0xb0) ^ 0x38) - 0x45; dest[i] = state2 = t; state1 = v; } } static void decrypt(uint8_t *dest, const uint8_t *src, uint8_t cnt) { uint8_t state1 = 0x9b, state2 = 0x54; uint8_t t, v; int i; for (i = 0; i < cnt; i++) { v = src[i]; t = (((v + 0x45) ^ 0x38) + 0xb0) ^ 0x5a ^ state1; t = (((t + 0x39) ^ 0x35) + 0x05) ^ 0x2b ^ state2; dest[i] = state1 = t; state2 = v; } } static int do_ep1_command(const struct sr_dev_inst *sdi, const uint8_t *command, uint8_t cmd_len, uint8_t *reply, uint8_t reply_len) { uint8_t buf[64]; struct sr_usb_dev_inst *usb; int ret, xfer; usb = sdi->conn; if (cmd_len < 1 || cmd_len > 64 || reply_len > 64 || command == NULL || (reply_len > 0 && reply == NULL)) return SR_ERR_ARG; encrypt(buf, command, cmd_len); ret = libusb_bulk_transfer(usb->devhdl, 1, buf, cmd_len, &xfer, 1000); if (ret != 0) { sr_dbg("Failed to send EP1 command 0x%02x: %s.", command[0], libusb_error_name(ret)); return SR_ERR; } if (xfer != cmd_len) { sr_dbg("Failed to send EP1 command 0x%02x: incorrect length " "%d != %d.", xfer, cmd_len); return SR_ERR; } if (reply_len == 0) return SR_OK; ret = libusb_bulk_transfer(usb->devhdl, 0x80 | 1, buf, reply_len, &xfer, 1000); if (ret != 0) { sr_dbg("Failed to receive reply to EP1 command 0x%02x: %s.", command[0], libusb_error_name(ret)); return SR_ERR; } if (xfer != reply_len) { sr_dbg("Failed to receive reply to EP1 command 0x%02x: " "incorrect length %d != %d.", xfer, reply_len); return SR_ERR; } decrypt(reply, buf, reply_len); return SR_OK; } static int read_eeprom(const struct sr_dev_inst *sdi, uint8_t address, uint8_t length, uint8_t *buf) { uint8_t command[5] = { COMMAND_READ_EEPROM, READ_EEPROM_COOKIE1, READ_EEPROM_COOKIE2, address, length, }; return do_ep1_command(sdi, command, 5, buf, length); } static int upload_led_table(const struct sr_dev_inst *sdi, const uint8_t *table, uint8_t offset, uint8_t cnt) { uint8_t chunk, command[64]; int ret; if (cnt < 1 || cnt + offset > 64 || table == NULL) return SR_ERR_ARG; while (cnt > 0) { chunk = (cnt > 32 ? 32 : cnt); command[0] = COMMAND_WRITE_LED_TABLE; command[1] = offset; command[2] = chunk; memcpy(command + 3, table, chunk); ret = do_ep1_command(sdi, command, 3 + chunk, NULL, 0); if (ret != SR_OK) return ret; table += chunk; offset += chunk; cnt -= chunk; } return SR_OK; } static int set_led_mode(const struct sr_dev_inst *sdi, uint8_t animate, uint16_t t2reload, uint8_t div, uint8_t repeat) { uint8_t command[6] = { COMMAND_SET_LED_MODE, animate, t2reload & 0xff, t2reload >> 8, div, repeat, }; return do_ep1_command(sdi, command, 6, NULL, 0); } static int read_fpga_register(const struct sr_dev_inst *sdi, uint8_t address, uint8_t *value) { uint8_t command[3] = { COMMAND_FPGA_READ_REGISTER, 1, address, }; return do_ep1_command(sdi, command, 3, value, 1); } static int write_fpga_registers(const struct sr_dev_inst *sdi, uint8_t (*regs)[2], uint8_t cnt) { uint8_t command[64]; int i; if (cnt < 1 || cnt > 31) return SR_ERR_ARG; command[0] = COMMAND_FPGA_WRITE_REGISTER; command[1] = cnt; for (i = 0; i < cnt; i++) { command[2 + 2 * i] = regs[i][0]; command[3 + 2 * i] = regs[i][1]; } return do_ep1_command(sdi, command, 2 * (cnt + 1), NULL, 0); } static int write_fpga_register(const struct sr_dev_inst *sdi, uint8_t address, uint8_t value) { uint8_t regs[2] = { address, value }; return write_fpga_registers(sdi, ®s, 1); } static uint8_t map_eeprom_data(uint8_t v) { return (((v ^ 0x80) + 0x44) ^ 0xd5) + 0x69; } static int prime_fpga(const struct sr_dev_inst *sdi) { uint8_t eeprom_data[16]; uint8_t old_reg_10, version; uint8_t regs[8][2] = { {10, 0x00}, {10, 0x40}, {12, 0}, {10, 0xc0}, {10, 0x40}, {6, 0}, {7, 1}, {7, 0} }; int i, ret; if ((ret = read_eeprom(sdi, 16, 16, eeprom_data)) != SR_OK) return ret; if ((ret = read_fpga_register(sdi, 10, &old_reg_10)) != SR_OK) return ret; regs[0][1] = (old_reg_10 &= 0x7f); regs[1][1] |= old_reg_10; regs[3][1] |= old_reg_10; regs[4][1] |= old_reg_10; for (i = 0; i < 16; i++) { regs[2][1] = eeprom_data[i]; regs[5][1] = map_eeprom_data(eeprom_data[i]); if (i) ret = write_fpga_registers(sdi, ®s[2], 6); else ret = write_fpga_registers(sdi, ®s[0], 8); if (ret != SR_OK) return ret; } if ((ret = write_fpga_register(sdi, 10, old_reg_10)) != SR_OK) return ret; if ((ret = read_fpga_register(sdi, 0, &version)) != SR_OK) return ret; if (version != 0x10) { sr_err("Invalid FPGA bitstream version: 0x%02x != 0x10.", version); return SR_ERR; } return SR_OK; } static void make_heartbeat(uint8_t *table, int len) { int i, j; memset(table, 0, len); len >>= 3; for (i = 0; i < 2; i++) for (j = 0; j < len; j++) *table++ = sin(j * M_PI / len) * 255; } static int configure_led(const struct sr_dev_inst *sdi) { uint8_t table[64]; int ret; make_heartbeat(table, 64); if ((ret = upload_led_table(sdi, table, 0, 64)) != SR_OK) return ret; return set_led_mode(sdi, 1, 6250, 0, 1); } static int upload_fpga_bitstream(const struct sr_dev_inst *sdi, enum voltage_range vrange) { struct dev_context *devc; int offset, chunksize, ret; const char *filename; uint8_t len, buf[256 * 62], command[64]; FILE *fw; devc = sdi->priv; if (devc->cur_voltage_range == vrange) return SR_OK; switch (vrange) { case VOLTAGE_RANGE_18_33_V: filename = FPGA_FIRMWARE_18; break; case VOLTAGE_RANGE_5_V: filename = FPGA_FIRMWARE_33; break; default: sr_err("Unsupported voltage range."); return SR_ERR; } sr_info("Uploading FPGA bitstream at %s.", filename); if ((fw = g_fopen(filename, "rb")) == NULL) { sr_err("Unable to open bitstream file %s for reading: %s.", filename, strerror(errno)); return SR_ERR; } buf[0] = COMMAND_FPGA_UPLOAD_INIT; if ((ret = do_ep1_command(sdi, buf, 1, NULL, 0)) != SR_OK) { fclose(fw); return ret; } while (1) { chunksize = fread(buf, 1, sizeof(buf), fw); if (chunksize == 0) break; for (offset = 0; offset < chunksize; offset += 62) { len = (offset + 62 > chunksize ? chunksize - offset : 62); command[0] = COMMAND_FPGA_UPLOAD_SEND_DATA; command[1] = len; memcpy(command + 2, buf + offset, len); ret = do_ep1_command(sdi, command, len + 2, NULL, 0); if (ret != SR_OK) { fclose(fw); return ret; } } sr_info("Uploaded %d bytes.", chunksize); } fclose(fw); sr_info("FPGA bitstream upload done."); if ((ret = prime_fpga(sdi)) != SR_OK) return ret; if ((ret = configure_led(sdi)) != SR_OK) return ret; devc->cur_voltage_range = vrange; return SR_OK; } static int abort_acquisition_sync(const struct sr_dev_inst *sdi) { static const uint8_t command[2] = { COMMAND_ABORT_ACQUISITION_SYNC, ABORT_ACQUISITION_SYNC_PATTERN, }; uint8_t reply, expected_reply; int ret; if ((ret = do_ep1_command(sdi, command, 2, &reply, 1)) != SR_OK) return ret; expected_reply = ~command[1]; if (reply != expected_reply) { sr_err("Invalid response for abort acquisition command: " "0x%02x != 0x%02x.", reply, expected_reply); return SR_ERR; } return SR_OK; } SR_PRIV int logic16_setup_acquisition(const struct sr_dev_inst *sdi, uint64_t samplerate, uint16_t channels) { uint8_t clock_select, reg1, reg10; uint64_t div; int i, ret, nchan = 0; struct dev_context *devc; devc = sdi->priv; if (samplerate == 0 || samplerate > MAX_SAMPLE_RATE) { sr_err("Unable to sample at %" PRIu64 "Hz.", samplerate); return SR_ERR; } if (BASE_CLOCK_0_FREQ % samplerate == 0 && (div = BASE_CLOCK_0_FREQ / samplerate) <= 256) { clock_select = 0; } else if (BASE_CLOCK_1_FREQ % samplerate == 0 && (div = BASE_CLOCK_1_FREQ / samplerate) <= 256) { clock_select = 1; } else { sr_err("Unable to sample at %" PRIu64 "Hz.", samplerate); return SR_ERR; } for (i = 0; i < 16; i++) if (channels & (1U << i)) nchan++; if ((nchan >= 13 && samplerate > MAX_13CH_SAMPLE_RATE) || (nchan >= 10 && samplerate > MAX_10CH_SAMPLE_RATE) || (nchan >= 8 && samplerate > MAX_8CH_SAMPLE_RATE) || (nchan >= 7 && samplerate > MAX_7CH_SAMPLE_RATE) || (nchan >= 4 && samplerate > MAX_4CH_SAMPLE_RATE)) { sr_err("Unable to sample at %" PRIu64 "Hz " "with this many channels.", samplerate); return SR_ERR; } ret = upload_fpga_bitstream(sdi, devc->selected_voltage_range); if (ret != SR_OK) return ret; if ((ret = read_fpga_register(sdi, 1, ®1)) != SR_OK) return ret; if (reg1 != 0x08) { sr_dbg("Invalid state at acquisition setup: 0x%02x != 0x08.", reg1); return SR_ERR; } if ((ret = write_fpga_register(sdi, 1, 0x40)) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 10, clock_select)) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 4, (uint8_t)(div - 1))) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 2, (uint8_t)(channels & 0xff))) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 3, (uint8_t)(channels >> 8))) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 1, 0x42)) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 1, 0x40)) != SR_OK) return ret; if ((ret = read_fpga_register(sdi, 1, ®1)) != SR_OK) return ret; if (reg1 != 0x48) { sr_dbg("Invalid state at acquisition setup: 0x%02x != 0x48.", reg1); return SR_ERR; } if ((ret = read_fpga_register(sdi, 10, ®10)) != SR_OK) return ret; if (reg10 != clock_select) { sr_dbg("Invalid state at acquisition setup: 0x%02x != 0x%02x.", reg10, clock_select); return SR_ERR; } return SR_OK; } SR_PRIV int logic16_start_acquisition(const struct sr_dev_inst *sdi) { static const uint8_t command[1] = { COMMAND_START_ACQUISITION, }; int ret; if ((ret = do_ep1_command(sdi, command, 1, NULL, 0)) != SR_OK) return ret; return write_fpga_register(sdi, 1, 0x41); } SR_PRIV int logic16_abort_acquisition(const struct sr_dev_inst *sdi) { static const uint8_t command[1] = { COMMAND_ABORT_ACQUISITION_ASYNC, }; int ret; uint8_t reg1, reg8, reg9; if ((ret = do_ep1_command(sdi, command, 1, NULL, 0)) != SR_OK) return ret; if ((ret = write_fpga_register(sdi, 1, 0x00)) != SR_OK) return ret; if ((ret = read_fpga_register(sdi, 1, ®1)) != SR_OK) return ret; if (reg1 != 0x08) { sr_dbg("Invalid state at acquisition stop: 0x%02x != 0x08.", reg1); return SR_ERR; } if ((ret = read_fpga_register(sdi, 8, ®8)) != SR_OK) return ret; if ((ret = read_fpga_register(sdi, 9, ®9)) != SR_OK) return ret; return SR_OK; } SR_PRIV int logic16_init_device(const struct sr_dev_inst *sdi) { struct dev_context *devc; int ret; devc = sdi->priv; devc->cur_voltage_range = VOLTAGE_RANGE_UNKNOWN; if ((ret = abort_acquisition_sync(sdi)) != SR_OK) return ret; if ((ret = read_eeprom(sdi, 8, 8, devc->eeprom_data)) != SR_OK) return ret; ret = upload_fpga_bitstream(sdi, devc->selected_voltage_range); if (ret != SR_OK) return ret; return SR_OK; } static void finish_acquisition(struct dev_context *devc) { struct sr_datafeed_packet packet; /* Terminate session. */ packet.type = SR_DF_END; sr_session_send(devc->cb_data, &packet); /* Remove fds from polling. */ usb_source_remove(devc->ctx); devc->num_transfers = 0; g_free(devc->transfers); g_free(devc->convbuffer); } static void free_transfer(struct libusb_transfer *transfer) { struct dev_context *devc; unsigned int i; devc = transfer->user_data; g_free(transfer->buffer); transfer->buffer = NULL; libusb_free_transfer(transfer); for (i = 0; i < devc->num_transfers; i++) { if (devc->transfers[i] == transfer) { devc->transfers[i] = NULL; break; } } devc->submitted_transfers--; if (devc->submitted_transfers == 0) finish_acquisition(devc); } static void resubmit_transfer(struct libusb_transfer *transfer) { int ret; if ((ret = libusb_submit_transfer(transfer)) == LIBUSB_SUCCESS) return; free_transfer(transfer); /* TODO: Stop session? */ sr_err("%s: %s", __func__, libusb_error_name(ret)); } static size_t convert_sample_data(struct dev_context *devc, uint8_t *dest, size_t destcnt, const uint8_t *src, size_t srccnt) { uint16_t *channel_data; int i, cur_channel; size_t ret = 0; uint16_t sample, channel_mask; srccnt /= 2; channel_data = devc->channel_data; cur_channel = devc->cur_channel; while (srccnt--) { sample = src[0] | (src[1] << 8); src += 2; channel_mask = devc->channel_masks[cur_channel]; for (i = 15; i >= 0; --i, sample >>= 1) if (sample & 1) channel_data[i] |= channel_mask; if (++cur_channel == devc->num_channels) { cur_channel = 0; if (destcnt < 16 * 2) { sr_err("Conversion buffer too small!"); break; } memcpy(dest, channel_data, 16 * 2); memset(channel_data, 0, 16 * 2); dest += 16 * 2; ret += 16 * 2; destcnt -= 16 * 2; } } devc->cur_channel = cur_channel; return ret; } SR_PRIV void logic16_receive_transfer(struct libusb_transfer *transfer) { gboolean packet_has_error = FALSE; struct sr_datafeed_packet packet; struct sr_datafeed_logic logic; struct dev_context *devc; size_t converted_length; devc = transfer->user_data; /* * If acquisition has already ended, just free any queued up * transfer that come in. */ if (devc->num_samples < 0) { free_transfer(transfer); return; } sr_info("receive_transfer(): status %d received %d bytes.", transfer->status, transfer->actual_length); switch (transfer->status) { case LIBUSB_TRANSFER_NO_DEVICE: devc->num_samples = -2; free_transfer(transfer); return; case LIBUSB_TRANSFER_COMPLETED: case LIBUSB_TRANSFER_TIMED_OUT: /* We may have received some data though. */ break; default: packet_has_error = TRUE; break; } if (transfer->actual_length & 1) { sr_err("Got an odd number of bytes from the device. " "This should not happen."); /* Bail out right away. */ packet_has_error = TRUE; devc->empty_transfer_count = MAX_EMPTY_TRANSFERS; } if (transfer->actual_length == 0 || packet_has_error) { devc->empty_transfer_count++; if (devc->empty_transfer_count > MAX_EMPTY_TRANSFERS) { /* * The FX2 gave up. End the acquisition, the frontend * will work out that the samplecount is short. */ devc->num_samples = -2; free_transfer(transfer); } else { resubmit_transfer(transfer); } return; } else { devc->empty_transfer_count = 0; } converted_length = convert_sample_data(devc, devc->convbuffer, devc->convbuffer_size, transfer->buffer, transfer->actual_length); if (converted_length > 0) { /* Cap sample count if needed */ if (devc->limit_samples && (uint64_t)devc->num_samples + converted_length / 2 > devc->limit_samples) { converted_length = (devc->limit_samples - devc->num_samples) * 2; } /* Send the incoming transfer to the session bus. */ packet.type = SR_DF_LOGIC; packet.payload = &logic; logic.length = converted_length; logic.unitsize = 2; logic.data = devc->convbuffer; sr_session_send(devc->cb_data, &packet); devc->num_samples += converted_length / 2; if (devc->limit_samples && (uint64_t)devc->num_samples >= devc->limit_samples) { devc->num_samples = -2; free_transfer(transfer); return; } } resubmit_transfer(transfer); }