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hackrf/firmware/hackrf_usb/usb_api_transceiver.c
Martin Ling 7057235a14 Increment a sequence number when transceiver mode changes. 
This fixes bug #1042, which occured when an RX->OFF->RX sequence
happened quickly enough that the loop in rx_mode() did not see the
change. As a result, the enable_baseband_streaming() call at the start
of that function was not repeated for the new RX operation, so RX
progress stalled.

To solve this, the vendor request handler now increments a sequence
number when it changes the transceiver mode. Instead of the RX loop
checking whether the transceiver mode is still RX, it now checks whether
the current sequence number is the same as when it was started. If not,
there must have been at least one mode change, so the loop exits, and
the main loop starts the necessary loop for the new mode. The same
behaviour is implemented for the TX and sweep loops.

For this approach to be reliable, we must ensure that when deciding
which mode and sequence number to use, we take both values from the same
set_transceiver_mode request.

To achieve this, we briefly disable the USB0 interrupt to stop the
vendor request handler from running whilst reading the mode and sequence
number together. Then the loop dispatch proceeds using those pre-read
values.
2022-02-03 07:36:34 +00:00

400 lines
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/*
* Copyright 2012 Jared Boone
* Copyright 2013 Benjamin Vernoux
*
* This file is part of HackRF.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, 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; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include "usb_api_transceiver.h"
#include "hackrf_ui.h"
#include "operacake_sctimer.h"
#include <libopencm3/cm3/vector.h>
#include "usb_bulk_buffer.h"
#include "m0_state.h"
#include "usb_api_cpld.h" // Remove when CPLD update is handled elsewhere
#include <max2837.h>
#include <rf_path.h>
#include <tuning.h>
#include <streaming.h>
#include <usb.h>
#include <usb_queue.h>
#include <stddef.h>
#include <string.h>
#include "usb_endpoint.h"
#include "usb_api_sweep.h"
typedef struct {
uint32_t freq_mhz;
uint32_t freq_hz;
} set_freq_params_t;
set_freq_params_t set_freq_params;
struct set_freq_explicit_params {
uint64_t if_freq_hz; /* intermediate frequency */
uint64_t lo_freq_hz; /* front-end local oscillator frequency */
uint8_t path; /* image rejection filter path */
};
struct set_freq_explicit_params explicit_params;
typedef struct {
uint32_t freq_hz;
uint32_t divider;
} set_sample_r_params_t;
set_sample_r_params_t set_sample_r_params;
usb_request_status_t usb_vendor_request_set_baseband_filter_bandwidth(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage
) {
if( stage == USB_TRANSFER_STAGE_SETUP ) {
const uint32_t bandwidth = (endpoint->setup.index << 16) | endpoint->setup.value;
if( baseband_filter_bandwidth_set(bandwidth) ) {
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_STALL;
} else {
return USB_REQUEST_STATUS_OK;
}
}
usb_request_status_t usb_vendor_request_set_freq(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage)
{
if (stage == USB_TRANSFER_STAGE_SETUP)
{
usb_transfer_schedule_block(endpoint->out, &set_freq_params, sizeof(set_freq_params_t),
NULL, NULL);
return USB_REQUEST_STATUS_OK;
} else if (stage == USB_TRANSFER_STAGE_DATA)
{
const uint64_t freq = set_freq_params.freq_mhz * 1000000ULL + set_freq_params.freq_hz;
if( set_freq(freq) )
{
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_STALL;
} else
{
return USB_REQUEST_STATUS_OK;
}
}
usb_request_status_t usb_vendor_request_set_sample_rate_frac(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage)
{
if (stage == USB_TRANSFER_STAGE_SETUP)
{
usb_transfer_schedule_block(endpoint->out, &set_sample_r_params, sizeof(set_sample_r_params_t),
NULL, NULL);
return USB_REQUEST_STATUS_OK;
} else if (stage == USB_TRANSFER_STAGE_DATA)
{
if( sample_rate_frac_set(set_sample_r_params.freq_hz * 2, set_sample_r_params.divider ) )
{
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_STALL;
} else
{
return USB_REQUEST_STATUS_OK;
}
}
usb_request_status_t usb_vendor_request_set_amp_enable(
usb_endpoint_t* const endpoint, const usb_transfer_stage_t stage)
{
if (stage == USB_TRANSFER_STAGE_SETUP) {
switch (endpoint->setup.value) {
case 0:
rf_path_set_lna(&rf_path, 0);
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
case 1:
rf_path_set_lna(&rf_path, 1);
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
default:
return USB_REQUEST_STATUS_STALL;
}
} else {
return USB_REQUEST_STATUS_OK;
}
}
usb_request_status_t usb_vendor_request_set_lna_gain(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage)
{
if( stage == USB_TRANSFER_STAGE_SETUP ) {
const uint8_t value = max2837_set_lna_gain(&max2837, endpoint->setup.index);
endpoint->buffer[0] = value;
if(value) hackrf_ui()->set_bb_lna_gain(endpoint->setup.index);
usb_transfer_schedule_block(endpoint->in, &endpoint->buffer, 1,
NULL, NULL);
usb_transfer_schedule_ack(endpoint->out);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_OK;
}
usb_request_status_t usb_vendor_request_set_vga_gain(
usb_endpoint_t* const endpoint, const usb_transfer_stage_t stage)
{
if( stage == USB_TRANSFER_STAGE_SETUP ) {
const uint8_t value = max2837_set_vga_gain(&max2837, endpoint->setup.index);
endpoint->buffer[0] = value;
if(value) hackrf_ui()->set_bb_vga_gain(endpoint->setup.index);
usb_transfer_schedule_block(endpoint->in, &endpoint->buffer, 1,
NULL, NULL);
usb_transfer_schedule_ack(endpoint->out);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_OK;
}
usb_request_status_t usb_vendor_request_set_txvga_gain(
usb_endpoint_t* const endpoint, const usb_transfer_stage_t stage)
{
if( stage == USB_TRANSFER_STAGE_SETUP ) {
const uint8_t value = max2837_set_txvga_gain(&max2837, endpoint->setup.index);
endpoint->buffer[0] = value;
if(value) hackrf_ui()->set_bb_tx_vga_gain(endpoint->setup.index);
usb_transfer_schedule_block(endpoint->in, &endpoint->buffer, 1,
NULL, NULL);
usb_transfer_schedule_ack(endpoint->out);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_OK;
}
usb_request_status_t usb_vendor_request_set_antenna_enable(
usb_endpoint_t* const endpoint, const usb_transfer_stage_t stage)
{
if (stage == USB_TRANSFER_STAGE_SETUP) {
switch (endpoint->setup.value) {
case 0:
rf_path_set_antenna(&rf_path, 0);
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
case 1:
rf_path_set_antenna(&rf_path, 1);
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
default:
return USB_REQUEST_STATUS_STALL;
}
} else {
return USB_REQUEST_STATUS_OK;
}
}
usb_request_status_t usb_vendor_request_set_freq_explicit(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage)
{
if (stage == USB_TRANSFER_STAGE_SETUP) {
usb_transfer_schedule_block(endpoint->out, &explicit_params,
sizeof(struct set_freq_explicit_params), NULL, NULL);
return USB_REQUEST_STATUS_OK;
} else if (stage == USB_TRANSFER_STAGE_DATA) {
if (set_freq_explicit(explicit_params.if_freq_hz,
explicit_params.lo_freq_hz, explicit_params.path)) {
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
}
return USB_REQUEST_STATUS_STALL;
} else {
return USB_REQUEST_STATUS_OK;
}
}
static volatile transceiver_mode_t _transceiver_mode = TRANSCEIVER_MODE_OFF;
static volatile uint32_t _transceiver_mode_seq = 0;
static volatile hw_sync_mode_t _hw_sync_mode = HW_SYNC_MODE_OFF;
void set_hw_sync_mode(const hw_sync_mode_t new_hw_sync_mode) {
_hw_sync_mode = new_hw_sync_mode;
}
transceiver_mode_t transceiver_mode(void) {
return _transceiver_mode;
}
uint32_t transceiver_mode_seq(void) {
return _transceiver_mode_seq;
}
void set_transceiver_mode(const transceiver_mode_t new_transceiver_mode) {
baseband_streaming_disable(&sgpio_config);
operacake_sctimer_reset_state();
usb_endpoint_flush(&usb_endpoint_bulk_in);
usb_endpoint_flush(&usb_endpoint_bulk_out);
_transceiver_mode = new_transceiver_mode;
switch (_transceiver_mode) {
case TRANSCEIVER_MODE_RX_SWEEP:
case TRANSCEIVER_MODE_RX:
led_off(LED3);
led_on(LED2);
rf_path_set_direction(&rf_path, RF_PATH_DIRECTION_RX);
m0_state.tx = false;
break;
case TRANSCEIVER_MODE_TX:
led_off(LED2);
led_on(LED3);
rf_path_set_direction(&rf_path, RF_PATH_DIRECTION_TX);
m0_state.tx = true;
break;
case TRANSCEIVER_MODE_OFF:
default:
led_off(LED2);
led_off(LED3);
rf_path_set_direction(&rf_path, RF_PATH_DIRECTION_OFF);
m0_state.tx = false;
}
if( _transceiver_mode != TRANSCEIVER_MODE_OFF ) {
activate_best_clock_source();
hw_sync_enable(_hw_sync_mode);
m0_state.offset = 0;
}
_transceiver_mode_seq++;
}
usb_request_status_t usb_vendor_request_set_transceiver_mode(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage)
{
if( stage == USB_TRANSFER_STAGE_SETUP ) {
switch( endpoint->setup.value ) {
case TRANSCEIVER_MODE_OFF:
case TRANSCEIVER_MODE_RX:
case TRANSCEIVER_MODE_TX:
case TRANSCEIVER_MODE_RX_SWEEP:
case TRANSCEIVER_MODE_CPLD_UPDATE:
set_transceiver_mode(endpoint->setup.value);
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
default:
return USB_REQUEST_STATUS_STALL;
}
} else {
return USB_REQUEST_STATUS_OK;
}
}
usb_request_status_t usb_vendor_request_set_hw_sync_mode(
usb_endpoint_t* const endpoint,
const usb_transfer_stage_t stage)
{
if( stage == USB_TRANSFER_STAGE_SETUP ) {
set_hw_sync_mode(endpoint->setup.value);
usb_transfer_schedule_ack(endpoint->in);
return USB_REQUEST_STATUS_OK;
} else {
return USB_REQUEST_STATUS_OK;
}
}
void rx_mode(uint32_t seq) {
unsigned int phase = 1;
baseband_streaming_enable(&sgpio_config);
while (_transceiver_mode_seq == seq) {
// Set up IN transfer of buffer 0.
if (16384 <= m0_state.offset && 1 == phase) {
usb_transfer_schedule_block(
&usb_endpoint_bulk_in,
&usb_bulk_buffer[0x0000],
0x4000,
NULL, NULL
);
phase = 0;
}
// Set up IN transfer of buffer 1.
if (16384 > m0_state.offset && 0 == phase) {
usb_transfer_schedule_block(
&usb_endpoint_bulk_in,
&usb_bulk_buffer[0x4000],
0x4000,
NULL, NULL
);
phase = 1;
}
}
}
void tx_mode(uint32_t seq) {
unsigned int phase = 1;
memset(&usb_bulk_buffer[0x0000], 0, 0x8000);
// Set up OUT transfer of buffer 1.
usb_transfer_schedule_block(
&usb_endpoint_bulk_out,
&usb_bulk_buffer[0x4000],
0x4000,
NULL, NULL
);
// Start transmitting zeros while the host fills buffer 1.
baseband_streaming_enable(&sgpio_config);
while (_transceiver_mode_seq == seq) {
// Set up OUT transfer of buffer 0.
if (16384 <= m0_state.offset && 1 == phase) {
usb_transfer_schedule_block(
&usb_endpoint_bulk_out,
&usb_bulk_buffer[0x0000],
0x4000,
NULL, NULL
);
phase = 0;
}
// Set up OUT transfer of buffer 1.
if (16384 > m0_state.offset && 0 == phase) {
usb_transfer_schedule_block(
&usb_endpoint_bulk_out,
&usb_bulk_buffer[0x4000],
0x4000,
NULL, NULL
);
phase = 1;
}
}
}
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