segatools/board/led15070.c

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C
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2024-06-23 19:21:57 +00:00
/*
SEGA 837-15070-0X LED Controller Board Emulator
Credits:
837-15070-04 LED Controller Board Emulator (emihiok)
837-15093-06 LED Controller Board Emulator (somewhatlurker, skogaby)
(a/o June 2023)
*/
#include <windows.h>
#include <assert.h>
#include <process.h>
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include "board/led15070-cmd.h"
#include "board/led15070-frame.h"
#include "board/led15070.h"
#include "hook/iobuf.h"
#include "hook/iohook.h"
#include "hooklib/uart.h"
#include "util/dprintf.h"
#include "util/dump.h"
static HRESULT led15070_handle_irp(struct irp *irp);
static HRESULT led15070_handle_irp_locked(int board, struct irp *irp);
static HRESULT led15070_req_dispatch(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_reset(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_input(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_normal_12bit(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_normal_8bit(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_multi_flash_8bit(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_multi_fade_8bit(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_palette_7_normal_led(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_palette_6_flash_led(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_15dc_out(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_15gs_out(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_psc_max(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_fet_output(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_gs_palette(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_dc_update(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_gs_update(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_rotate(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_set_dc_data(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_eeprom_write(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_eeprom_read(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_ack_on(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_ack_off(int board, const struct led15070_req_any *req);
static HRESULT led15070_req_board_info(int board);
static HRESULT led15070_req_board_status(int board);
static HRESULT led15070_req_fw_sum(int board);
static HRESULT led15070_req_protocol_ver(int board);
static HRESULT led15070_req_to_boot_mode(int board);
static HRESULT led15070_req_fw_update(int board, const struct led15070_req_any *req);
static HRESULT led15070_eeprom_open(int board, wchar_t *path, HANDLE *handle);
static HRESULT led15070_eeprom_close(int board, wchar_t *path, HANDLE *handle);
static char led15070_board_num[8];
static uint8_t led15070_fw_ver;
static uint16_t led15070_fw_sum;
static uint8_t led15070_host_adr = 0x01;
#define led15070_nboards 2
typedef struct {
CRITICAL_SECTION lock;
bool started;
HRESULT start_hr;
struct uart boarduart;
uint8_t written_bytes[520];
uint8_t readable_bytes[520];
uint8_t gs[32][4];
uint8_t dc[32][3];
uint8_t fet[3];
uint8_t gs_palette[8][3];
wchar_t eeprom_path[MAX_PATH];
HANDLE eeprom_handle;
uint8_t boardadr;
bool enable_bootloader;
bool enable_response;
} _led15070_per_board_vars;
_led15070_per_board_vars led15070_per_board_vars[led15070_nboards];
static io_led_init_t led_init;
static io_led_set_fet_output_t led_set_fet_output;
static io_led_dc_update_t led_dc_update;
static io_led_gs_update_t led_gs_update;
HRESULT led15070_hook_init(
const struct led15070_config *cfg,
io_led_init_t _led_init,
io_led_set_fet_output_t _led_set_fet_output,
io_led_dc_update_t _led_dc_update,
io_led_gs_update_t _led_gs_update,
unsigned int first_port,
unsigned int num_boards)
{
assert(cfg != NULL);
if (!cfg->enable) {
return S_FALSE;
}
if (cfg->port_no != 0) {
first_port = cfg->port_no;
}
led_init = _led_init;
led_set_fet_output = _led_set_fet_output;
led_dc_update = _led_dc_update;
led_gs_update = _led_gs_update;
memcpy(led15070_board_num, cfg->board_number, sizeof(led15070_board_num));
led15070_fw_ver = cfg->fw_ver;
led15070_fw_sum = cfg->fw_sum;
for (int i = 0; i < num_boards; i++)
{
_led15070_per_board_vars *v = &led15070_per_board_vars[i];
InitializeCriticalSection(&v->lock);
// TODO: IMPROVE!
first_port = i == 1 ? first_port + 2 : first_port;
uart_init(&v->boarduart, first_port);
v->boarduart.baud.BaudRate = 115200;
v->boarduart.written.bytes = v->written_bytes;
v->boarduart.written.nbytes = sizeof(v->written_bytes);
v->boarduart.readable.bytes = v->readable_bytes;
v->boarduart.readable.nbytes = sizeof(v->readable_bytes);
memset(v->gs, 0, sizeof(v->gs));
memset(v->dc, 0, sizeof(v->dc));
memset(v->fet, 0, sizeof(v->fet));
memset(v->gs_palette, 0, sizeof(v->gs_palette));
memset(v->eeprom_path, 0, sizeof(v->eeprom_path));
v->eeprom_handle = NULL;
swprintf_s
(
v->eeprom_path, MAX_PATH,
L"%s\\led15070_eeprom_%d.bin",
cfg->eeprom_path, i
);
/* Generate board EEPROM file if it doesn't already exist */
led15070_eeprom_open(i, v->eeprom_path, &(v->eeprom_handle));
led15070_eeprom_close(i, v->eeprom_path, &(v->eeprom_handle));
v->boardadr = 0x11;
v->enable_bootloader = false;
v->enable_response = false;
}
dprintf("LED 15070: hook enabled.\n");
return iohook_push_handler(led15070_handle_irp);
}
static HRESULT led15070_handle_irp(struct irp *irp)
{
HRESULT hr;
assert(irp != NULL);
for (int i = 0; i < led15070_nboards; i++)
{
_led15070_per_board_vars *v = &led15070_per_board_vars[i];
struct uart *boarduart = &v->boarduart;
if (uart_match_irp(boarduart, irp))
{
CRITICAL_SECTION lock = v->lock;
EnterCriticalSection(&lock);
hr = led15070_handle_irp_locked(i, irp);
LeaveCriticalSection(&lock);
return hr;
}
}
return iohook_invoke_next(irp);
}
static HRESULT led15070_handle_irp_locked(int board, struct irp *irp)
{
struct led15070_req_any req;
struct iobuf req_iobuf;
HRESULT hr;
_led15070_per_board_vars *v = &led15070_per_board_vars[board];
struct uart *boarduart = &led15070_per_board_vars[board].boarduart;
if (irp->op == IRP_OP_OPEN) {
// Unfortunately the LED board UART gets opened and closed
// repeatedly
if (!v->started) {
dprintf("LED 15070: Starting LED backend\n");
hr = led_init();
v->started = true;
v->start_hr = hr;
if (FAILED(hr)) {
dprintf("LED 15070: Backend error, LED controller "
"disconnected: %x\n",
(int) hr);
return hr;
}
} else {
hr = v->start_hr;
if (FAILED(hr)) {
return hr;
}
}
}
hr = uart_handle_irp(boarduart, irp);
if (FAILED(hr) || irp->op != IRP_OP_WRITE) {
return hr;
}
for (;;) {
#if 0
dprintf("TX Buffer:\n");
dump_iobuf(&boarduart->written);
#endif
req_iobuf.bytes = (byte*)&req;
req_iobuf.nbytes = sizeof(req.hdr) + sizeof(req.cmd) + sizeof(req.payload);
req_iobuf.pos = 0;
hr = led15070_frame_decode(&req_iobuf, &boarduart->written);
if (hr != S_OK) {
if (FAILED(hr)) {
dprintf("LED 15070: Deframe error: %x\n", (int) hr);
}
return hr;
}
#if 0
dprintf("Deframe Buffer:\n");
dump_iobuf(&req_iobuf);
#endif
hr = led15070_req_dispatch(board, &req);
if (FAILED(hr)) {
dprintf("LED 15070: Processing error: %x\n", (int) hr);
}
}
}
static HRESULT led15070_req_dispatch(int board, const struct led15070_req_any *req)
{
switch (req->cmd) {
case LED_15070_CMD_RESET:
return led15070_req_reset(board, req);
case LED_15070_CMD_SET_INPUT:
return led15070_req_set_input(board, req);
case LED_15070_CMD_SET_NORMAL_12BIT:
return led15070_req_set_normal_12bit(board, req);
case LED_15070_CMD_SET_NORMAL_8BIT:
return led15070_req_set_normal_8bit(board, req);
case LED_15070_CMD_SET_MULTI_FLASH_8BIT:
return led15070_req_set_multi_flash_8bit(board, req);
case LED_15070_CMD_SET_MULTI_FADE_8BIT:
return led15070_req_set_multi_fade_8bit(board, req);
case LED_15070_CMD_SET_PALETTE_7_NORMAL_LED:
return led15070_req_set_palette_7_normal_led(board, req);
case LED_15070_CMD_SET_PALETTE_6_FLASH_LED:
return led15070_req_set_palette_6_flash_led(board, req);
case LED_15070_CMD_SET_15DC_OUT:
return led15070_req_set_15dc_out(board, req);
case LED_15070_CMD_SET_15GS_OUT:
return led15070_req_set_15gs_out(board, req);
case LED_15070_CMD_SET_PSC_MAX:
return led15070_req_set_psc_max(board, req);
case LED_15070_CMD_SET_FET_OUTPUT:
return led15070_req_set_fet_output(board, req);
case LED_15070_CMD_SET_GS_PALETTE:
return led15070_req_set_gs_palette(board, req);
case LED_15070_CMD_DC_UPDATE:
return led15070_req_dc_update(board, req);
case LED_15070_CMD_GS_UPDATE:
return led15070_req_gs_update(board, req);
case LED_15070_CMD_ROTATE:
return led15070_req_rotate(board, req);
case LED_15070_CMD_SET_DC_DATA:
return led15070_req_set_dc_data(board, req);
case LED_15070_CMD_EEPROM_WRITE:
return led15070_req_eeprom_write(board, req);
case LED_15070_CMD_EEPROM_READ:
return led15070_req_eeprom_read(board, req);
case LED_15070_CMD_ACK_ON:
return led15070_req_ack_on(board, req);
case LED_15070_CMD_ACK_OFF:
return led15070_req_ack_off(board, req);
case LED_15070_CMD_BOARD_INFO:
return led15070_req_board_info(board);
case LED_15070_CMD_BOARD_STATUS:
return led15070_req_board_status(board);
case LED_15070_CMD_FW_SUM:
return led15070_req_fw_sum(board);
case LED_15070_CMD_PROTOCOL_VER:
return led15070_req_protocol_ver(board);
case LED_15070_CMD_TO_BOOT_MODE:
return led15070_req_to_boot_mode(board);
case LED_15070_CMD_FW_UPDATE:
return led15070_req_fw_update(board, req);
default:
dprintf("LED 15070: Unhandled command %02x\n", req->cmd);
return S_OK;
}
}
static HRESULT led15070_req_reset(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Reset (board %u)\n", board);
led15070_per_board_vars[board].enable_bootloader = false;
led15070_per_board_vars[board].enable_response = true;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_RESET;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_input(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set input (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_INPUT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_normal_12bit(int board, const struct led15070_req_any *req)
{
uint8_t idx = req->payload[0];
dprintf("LED 15070: Set LED - Normal 12bit (board %u, index %u)\n",
board, idx);
// TODO: Data for this command. Seen with Carol
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_NORMAL_12BIT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_normal_8bit(int board, const struct led15070_req_any *req)
{
uint8_t idx = req->payload[0];
// dprintf("LED 15070: Set LED - Normal 8bit (board %u, index %u)\n",
// board, idx);
led15070_per_board_vars[board].gs[idx][0] = req->payload[1]; // R
led15070_per_board_vars[board].gs[idx][1] = req->payload[2]; // G
led15070_per_board_vars[board].gs[idx][2] = req->payload[3]; // B
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_NORMAL_8BIT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_multi_flash_8bit(int board, const struct led15070_req_any *req)
{
uint8_t idx_start = req->payload[0];
uint8_t idx_end = req->payload[1];
uint8_t idx_skip = req->payload[2];
// TODO: useful?
// dprintf("LED 15070: Set LED - Multi flash 8bit (board %u, start %u, end %u, skip %u)\n",
// board, idx_start, idx_end, idx_skip);
if (idx_skip > 0 && idx_skip <= (idx_end - idx_start + 1)) {
idx_start += idx_skip;
}
int i = idx_start;
do {
led15070_per_board_vars[board].gs[i][0] = req->payload[3]; // R
led15070_per_board_vars[board].gs[i][1] = req->payload[4]; // G
led15070_per_board_vars[board].gs[i][2] = req->payload[5]; // B
/* Always 0, tells the controller to immediately change to this color */
led15070_per_board_vars[board].gs[i][3] = req->payload[6]; // Speed
i++;
} while (i < idx_end);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_MULTI_FLASH_8BIT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_multi_fade_8bit(int board, const struct led15070_req_any *req)
{
uint8_t idx_start = req->payload[0];
uint8_t idx_end = req->payload[1];
uint8_t idx_skip = req->payload[2];
// dprintf("LED 15070: Set LED - Multi fade 8bit (board %u, start %u, end %u, skip %u)\n",
// board, idx_start, idx_end, idx_skip);
if (idx_skip > 0 && idx_skip <= (idx_end - idx_start + 1)) {
idx_start += idx_skip;
}
int i = idx_start;
do {
led15070_per_board_vars[board].gs[i][0] = req->payload[3]; // R
led15070_per_board_vars[board].gs[i][1] = req->payload[4]; // G
led15070_per_board_vars[board].gs[i][2] = req->payload[5]; // B
led15070_per_board_vars[board].gs[i][3] = req->payload[6]; // Speed
i++;
} while (i < idx_end);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_MULTI_FADE_8BIT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_palette_7_normal_led(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set palette - 7 Normal LED (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_PALETTE_7_NORMAL_LED;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_palette_6_flash_led(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set palette - 6 Flash LED (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_PALETTE_6_FLASH_LED;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_15dc_out(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set 15DC out (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_15DC_OUT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_15gs_out(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set 15GS out (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_15GS_OUT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_psc_max(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set PSC max (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_PSC_MAX;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_fet_output(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Set FET output (board %u)\n", board);
led15070_per_board_vars[board].fet[0] = req->payload[0]; // R or FET0 intensity
led15070_per_board_vars[board].fet[1] = req->payload[1]; // G or FET1 intensity
led15070_per_board_vars[board].fet[2] = req->payload[2]; // B or FET2 intensity
if (led_set_fet_output)
led_set_fet_output((const uint8_t*)led15070_per_board_vars[board].fet);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_FET_OUTPUT;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_gs_palette(int board, const struct led15070_req_any *req)
{
uint8_t idx = req->payload[0];
dprintf("LED 15070: Set GS palette (board %u, index %u)\n", board, idx);
led15070_per_board_vars[board].gs_palette[idx][0] = req->payload[1]; // R
led15070_per_board_vars[board].gs_palette[idx][1] = req->payload[2]; // G
led15070_per_board_vars[board].gs_palette[idx][2] = req->payload[3]; // B
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_GS_PALETTE;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_dc_update(int board, const struct led15070_req_any *req)
{
// dprintf("LED 15070: DC update (board %u)\n", board);
if (led_dc_update)
led_dc_update((const uint8_t*)led15070_per_board_vars[board].dc);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_DC_UPDATE;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_gs_update(int board, const struct led15070_req_any *req)
{
// dprintf("LED 15070: GS update (board %u)\n", board);
if (led_gs_update)
led_gs_update((const uint8_t*)led15070_per_board_vars[board].gs);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_GS_UPDATE;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_rotate(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Rotate (board %u)\n", board);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_ROTATE;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_set_dc_data(int board, const struct led15070_req_any *req)
{
uint8_t idx_start = req->payload[0];
uint8_t idx_end = req->payload[1];
uint8_t idx_skip = req->payload[2];
// dprintf("LED 15070: Set DC data (board %u, start %u, end %u, skip %u)\n",
// board, idx_start, idx_end, idx_skip);
if (idx_skip > 0 && idx_skip <= (idx_end - idx_start + 1)) {
idx_start += idx_skip;
}
int i = idx_start;
do {
led15070_per_board_vars[board].dc[i][0] = req->payload[3]; // R
led15070_per_board_vars[board].dc[i][1] = req->payload[4]; // G
led15070_per_board_vars[board].dc[i][2] = req->payload[5]; // B
i++;
} while (i < idx_end);
if (!led15070_per_board_vars[board].enable_response)
return S_OK;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_SET_DC_DATA;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_eeprom_write(int board, const struct led15070_req_any *req)
{
DWORD eeprom_bytes_written = 0;
HRESULT hr;
BOOL ok;
uint8_t addr = req->payload[0];
uint8_t data = req->payload[1];
dprintf("LED 15070: EEPROM write (board %u, address %02x, data %02x)\n",
board, addr, data);
if (addr > 0x07) {
dprintf("LED 15070: Error -- Invalid EEPROM write address %02x\n",
addr);
return E_INVALIDARG;
}
hr = led15070_eeprom_open(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
if (FAILED(hr)) {
return hr;
}
hr = SetFilePointer(
led15070_per_board_vars[board].eeprom_handle,
addr,
NULL,
FILE_BEGIN);
if (hr == INVALID_SET_FILE_POINTER) {
dprintf("LED 10570: Error -- Failed to set pointer to EEPROM file "
"(board %u)\n", board);
led15070_eeprom_close(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
return hr;
}
ok = WriteFile(
led15070_per_board_vars[board].eeprom_handle,
&data,
sizeof(data),
&eeprom_bytes_written, NULL);
if (!ok || eeprom_bytes_written == 0) {
hr = HRESULT_FROM_WIN32(GetLastError());
dprintf("LED 15070: Error -- Failed to write to EEPROM file: %x "
"(board %u)\n", (int) hr, board);
led15070_eeprom_close(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
return hr;
}
hr = led15070_eeprom_close(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
if (FAILED(hr)) {
return hr;
}
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 2 + 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_EEPROM_WRITE;
resp.report = LED_15070_REPORT_OK;
resp.data[0] = addr;
resp.data[1] = data;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_eeprom_read(int board, const struct led15070_req_any *req)
{
DWORD eeprom_bytes_read = 0;
HRESULT hr;
BOOL ok;
uint8_t addr = req->payload[0];
uint8_t data = 0;
dprintf("LED 15070: EEPROM read (board %u, address %02x)\n", board, addr);
if (addr > 0x07) {
dprintf("LED 15070: Error -- Invalid EEPROM read address %02x\n",
addr);
return E_INVALIDARG;
}
hr = led15070_eeprom_open(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
if (FAILED(hr)) {
return hr;
}
hr = SetFilePointer(
led15070_per_board_vars[board].eeprom_handle,
addr,
NULL,
FILE_BEGIN);
if (hr == INVALID_SET_FILE_POINTER) {
dprintf("LED 10570: Error -- Failed to set pointer to EEPROM file "
"(board %u)\n", board);
led15070_eeprom_close(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
return hr;
}
ok = ReadFile(
led15070_per_board_vars[board].eeprom_handle,
&data,
sizeof(data),
&eeprom_bytes_read,
NULL);
if (!ok || eeprom_bytes_read == 0) {
hr = HRESULT_FROM_WIN32(GetLastError());
dprintf("LED 15070: Error -- Failed to read from EEPROM file: %x "
"(board %u)\n", (int) hr, board);
led15070_eeprom_close(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
return hr;
}
hr = led15070_eeprom_close(
board,
led15070_per_board_vars[board].eeprom_path,
&(led15070_per_board_vars[board].eeprom_handle));
if (FAILED(hr)) {
return hr;
}
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 1 + 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_EEPROM_READ;
resp.report = LED_15070_REPORT_OK;
resp.data[0] = data;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_ack_on(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Acknowledge commands ON (board %u)\n", board);
led15070_per_board_vars[board].enable_response = true;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_ACK_ON;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_ack_off(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Acknowledge commands OFF (board %u)\n", board);
led15070_per_board_vars[board].enable_response = false;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_ACK_OFF;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_board_info(int board)
{
dprintf("LED 15070: Get board info (board %u)\n", board);
struct led15070_resp_board_info resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 10 + 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_BOARD_INFO;
resp.report = LED_15070_REPORT_OK;
memcpy(resp.board_num, led15070_board_num, sizeof(resp.board_num));
resp.endcode = 0xff;
resp.fw_ver = led15070_fw_ver;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_board_status(int board)
{
dprintf("LED 15070: Get board status (board %u)\n", board);
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 4 + 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_BOARD_STATUS;
resp.report = LED_15070_REPORT_OK;
resp.data[0] = 0; // Timeout status
resp.data[1] = 0; // Timeout sec
resp.data[2] = 0; // PWM IO
resp.data[3] = 0; // FET timeout
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_fw_sum(int board)
{
dprintf("LED 15070: Get firmware checksum (board %u)\n", board);
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 2 + 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_FW_SUM;
resp.report = LED_15070_REPORT_OK;
resp.data[0] = (led15070_fw_sum >> 8) & 0xff;
resp.data[1] = led15070_fw_sum & 0xff;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_protocol_ver(int board)
{
dprintf("LED 15070: Get protocol version (board %u)\n", board);
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3 + 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_PROTOCOL_VER;
resp.report = LED_15070_REPORT_OK;
if (led15070_per_board_vars[board].enable_bootloader) {
resp.data[0] = 0; // BOOT mode
resp.data[1] = 1; // Version major
resp.data[2] = 1; // Version minor
} else {
resp.data[0] = 1; // APPLI mode
resp.data[1] = 1; // Version major
resp.data[2] = 4; // Version minor
}
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_to_boot_mode(int board)
{
dprintf("LED 15070: To boot mode (board %u)\n", board);
led15070_per_board_vars[board].enable_bootloader = true;
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_TO_BOOT_MODE;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_req_fw_update(int board, const struct led15070_req_any *req)
{
dprintf("LED 15070: Firmware update (UNIMPLEMENTED) (board %u)\n", board);
struct led15070_resp_any resp;
memset(&resp, 0, sizeof(resp));
resp.hdr.sync = LED_15070_FRAME_SYNC;
resp.hdr.dest_adr = led15070_host_adr;
resp.hdr.src_adr = led15070_per_board_vars[board].boardadr;
resp.hdr.nbytes = 3;
resp.status = LED_15070_STATUS_OK;
resp.cmd = LED_15070_CMD_FW_UPDATE;
resp.report = LED_15070_REPORT_OK;
return led15070_frame_encode(&led15070_per_board_vars[board].boarduart.readable, &resp, sizeof(resp.hdr) + resp.hdr.nbytes);
}
static HRESULT led15070_eeprom_open(int board, wchar_t *path, HANDLE *handle)
{
DWORD eeprom_bytes_written;
BYTE null_bytes[8] = { 0x00 };
HRESULT hr;
BOOL ok;
#if 0
dprintf("LED 15070: Opening EEPROM file '%S' handle (board %u)\n", path, board);
#endif
*handle = CreateFileW(
path,
GENERIC_READ | GENERIC_WRITE,
FILE_SHARE_READ,
NULL,
OPEN_ALWAYS,
FILE_ATTRIBUTE_NORMAL,
NULL);
if (*handle == INVALID_HANDLE_VALUE) {
hr = HRESULT_FROM_WIN32(GetLastError());
dprintf("LED 15070: Failed to open EEPROM file '%S' handle: %x "
"(board %u)\n", path, (int) hr, board);
return hr;
}
if (GetLastError() == ERROR_ALREADY_EXISTS) return S_OK;
ok = WriteFile(
*handle,
null_bytes,
sizeof(null_bytes),
&eeprom_bytes_written,
NULL);
if (!ok || eeprom_bytes_written != sizeof(null_bytes)) {
hr = HRESULT_FROM_WIN32(GetLastError());
dprintf("LED 15070: Failed to initialize empty EEPROM file '%S': %x "
"(board %u)\n", path, (int) hr, board);
return hr;
}
return S_OK;
}
static HRESULT led15070_eeprom_close(int board, wchar_t *path, HANDLE *handle)
{
HRESULT hr;
BOOL ok;
#if 0
dprintf("LED 15070: Closing EEPROM file '%S' handle (board %u)\n", path, board);
#endif
ok = CloseHandle(*handle);
if (!ok) {
hr = HRESULT_FROM_WIN32(GetLastError());
dprintf("LED 15070: Failed to close EEPROM file '%S' handle: %x "
"(board %u)\n", path, (int) hr, board);
return hr;
}
return S_OK;
}