blob: 0de6ddb8ac6cc16fd63b3f6025149fb8f1a63f14 [file] [log] [blame]
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <fcntl.h>
#include <unistd.h>
#include <sys/stat.h>
#include <sys/mman.h>
#include <openbmc_intf.h>
#include <openbmc.h>
#include <gpio.h>
#include <gpio_configs.h>
/* ------------------------------------------------------------------------- */
static const gchar* dbus_object_path = "/org/openbmc/control";
static const gchar* instance_name = "host0";
static const gchar* dbus_name = "org.openbmc.control.Host";
static GpioConfigs g_gpio_configs;
static GDBusObjectManagerServer *manager = NULL;
static GPIO* fsi_data;
static GPIO* fsi_clk;
static GPIO* fsi_enable;
static GPIO* cronus_sel;
static size_t num_optionals;
static GPIO* optionals;
static gboolean* optional_pols;
/* Bit bang patterns */
//putcfam pu 281c 30000000 -p0 (Primary Side Select)
static const char* primary = "000011111111110101111000111001100111111111111111111111111111101111111111";
//putcfam pu 281c B0000000 -p0
static const char* go = "000011111111110101111000111000100111111111111111111111111111101101111111";
//putcfam pu 0x281c 30900000 (Golden Side Select)
static const char* golden = "000011111111110101111000111001100111101101111111111111111111101001111111";
/* Setup attentions */
//putcfam pu 0x081C 20000000
static const char* attnA = "000011111111111101111110001001101111111111111111111111111111110001111111";
//putcfam pu 0x100D 40000000
static const char* attnB = "000011111111111011111100101001011111111111111111111111111111110001111111";
//putcfam pu 0x100B FFFFFFFF
static const char* attnC = "000011111111111011111101001000000000000000000000000000000000001011111111";
static gboolean
on_init(Control *control,
GDBusMethodInvocation *invocation,
gpointer user_data)
{
control_complete_init(control,invocation);
return TRUE;
}
int
fsi_bitbang(const char* pattern)
{
int rc=GPIO_OK;
int i;
for(i=0;i<strlen(pattern);i++) {
rc = gpio_writec(fsi_data,pattern[i]);
if(rc!=GPIO_OK) { break; }
rc = gpio_clock_cycle(fsi_clk,1);
if(rc!=GPIO_OK) { break; }
}
return rc;
}
int
fsi_standby()
{
int rc=GPIO_OK;
rc = gpio_write(fsi_data,1);
if(rc!=GPIO_OK) { return rc; }
rc = gpio_clock_cycle(fsi_clk,5000);
if(rc!=GPIO_OK) { return rc; }
return rc;
}
static gboolean
on_boot(ControlHost *host,
GDBusMethodInvocation *invocation,
gpointer user_data)
{
int rc = GPIO_OK;
GDBusProxy *proxy;
GError *error = NULL;
GDBusConnection *connection =
g_dbus_object_manager_server_get_connection(manager);
if (!(fsi_data && fsi_clk && fsi_enable && cronus_sel)) {
g_print("ERROR invalid GPIO configuration, will not boot\n");
return FALSE;
}
if(control_host_get_debug_mode(host)==1) {
g_print("Enabling debug mode; not booting host\n");
rc |= gpio_open(fsi_enable);
rc |= gpio_open(cronus_sel);
rc |= gpio_write(fsi_enable,1);
rc |= gpio_write(cronus_sel,0);
if(rc!=GPIO_OK) {
g_print("ERROR enabling debug mode: %d\n",rc);
}
return TRUE;
}
g_print("Booting host\n");
Control* control = object_get_control((Object*)user_data);
control_host_complete_boot(host,invocation);
do {
rc = gpio_open(fsi_clk);
rc |= gpio_open(fsi_data);
rc |= gpio_open(fsi_enable);
rc |= gpio_open(cronus_sel);
for (size_t i = 0; i < num_optionals; ++i) {
rc |= gpio_open(&optionals[i]);
}
if(rc!=GPIO_OK) { break; }
//setup dc pins
rc = gpio_write(cronus_sel,1);
rc |= gpio_write(fsi_enable,1);
rc |= gpio_write(fsi_clk,1);
for (size_t i = 0; i < num_optionals; ++i) {
rc |= gpio_write(&optionals[i], optional_pols[i]);
}
if(rc!=GPIO_OK) { break; }
//data standy state
rc = fsi_standby();
//clear out pipes
rc |= gpio_write(fsi_data,0);
rc |= gpio_clock_cycle(fsi_clk,256);
rc |= gpio_write(fsi_data,1);
rc |= gpio_clock_cycle(fsi_clk,50);
if(rc!=GPIO_OK) { break; }
rc = fsi_bitbang(attnA);
rc |= fsi_standby();
rc |= fsi_bitbang(attnB);
rc |= fsi_standby();
rc |= fsi_bitbang(attnC);
rc |= fsi_standby();
if(rc!=GPIO_OK) { break; }
const gchar* flash_side = control_host_get_flash_side(host);
g_print("Using %s side of the bios flash\n",flash_side);
if(strcmp(flash_side,"primary")==0) {
rc |= fsi_bitbang(primary);
} else if(strcmp(flash_side,"golden") == 0) {
rc |= fsi_bitbang(golden);
} else {
g_print("ERROR: Invalid flash side: %s\n",flash_side);
rc = 0xff;
}
rc |= fsi_standby();
if(rc!=GPIO_OK) { break; }
rc = fsi_bitbang(go);
rc |= gpio_write(fsi_data,1); /* Data standby state */
rc |= gpio_clock_cycle(fsi_clk,2);
rc |= gpio_write(fsi_clk,0); /* hold clk low for clock mux */
rc |= gpio_write(fsi_enable,0);
rc |= gpio_clock_cycle(fsi_clk,16);
rc |= gpio_write(fsi_clk,0); /* Data standby state */
} while(0);
if(rc != GPIO_OK)
{
g_print("ERROR HostControl: GPIO sequence failed (rc=%d)\n",rc);
} else {
control_emit_goto_system_state(control,"HOST_BOOTING");
}
gpio_close(fsi_clk);
gpio_close(fsi_data);
gpio_close(fsi_enable);
gpio_close(cronus_sel);
for (size_t i = 0; i < num_optionals; ++i) {
gpio_close(&optionals[i]);
}
control_host_emit_booted(host);
return TRUE;
}
static void
on_bus_acquired(GDBusConnection *connection,
const gchar *name,
gpointer user_data)
{
ObjectSkeleton *object;
//g_print ("Acquired a message bus connection: %s\n",name);
manager = g_dbus_object_manager_server_new(dbus_object_path);
gchar *s;
s = g_strdup_printf("%s/%s",dbus_object_path,instance_name);
object = object_skeleton_new(s);
g_free(s);
ControlHost* control_host = control_host_skeleton_new();
object_skeleton_set_control_host(object, control_host);
g_object_unref(control_host);
Control* control = control_skeleton_new();
object_skeleton_set_control(object, control);
g_object_unref(control);
//define method callbacks here
g_signal_connect(control_host,
"handle-boot",
G_CALLBACK(on_boot),
object); /* user_data */
g_signal_connect(control,
"handle-init",
G_CALLBACK(on_init),
NULL); /* user_data */
control_host_set_debug_mode(control_host,0);
control_host_set_flash_side(control_host,"primary");
/* Export the object (@manager takes its own reference to @object) */
g_dbus_object_manager_server_set_connection(manager, connection);
g_dbus_object_manager_server_export(manager, G_DBUS_OBJECT_SKELETON(object));
g_object_unref(object);
if(read_gpios(connection, &g_gpio_configs) != TRUE) {
g_print("ERROR Hostctl: could not read GPIO configuration\n");
return;
}
fsi_data = &g_gpio_configs.hostctl_gpio.fsi_data;
fsi_clk = &g_gpio_configs.hostctl_gpio.fsi_clk;
fsi_enable = &g_gpio_configs.hostctl_gpio.fsi_enable;
cronus_sel = &g_gpio_configs.hostctl_gpio.cronus_sel;
num_optionals = g_gpio_configs.hostctl_gpio.num_optionals;
optionals = g_gpio_configs.hostctl_gpio.optionals;
optional_pols = g_gpio_configs.hostctl_gpio.optional_pols;
gpio_init(connection, fsi_data);
gpio_init(connection, fsi_clk);
gpio_init(connection, fsi_enable);
gpio_init(connection, cronus_sel);
for (int i = 0; i < num_optionals; ++i) {
gpio_init(connection, &optionals[i]);
}
}
static void
on_name_acquired(GDBusConnection *connection,
const gchar *name,
gpointer user_data)
{
// g_print ("Acquired the name %s\n", name);
}
static void
on_name_lost(GDBusConnection *connection,
const gchar *name,
gpointer user_data)
{
// g_print ("Lost the name %s\n", name);
free_gpios(&g_gpio_configs);
}
gint
main(gint argc, gchar *argv[])
{
GMainLoop *loop;
cmdline cmd;
cmd.argc = argc;
cmd.argv = argv;
guint id;
loop = g_main_loop_new(NULL, FALSE);
id = g_bus_own_name(DBUS_TYPE,
dbus_name,
G_BUS_NAME_OWNER_FLAGS_ALLOW_REPLACEMENT |
G_BUS_NAME_OWNER_FLAGS_REPLACE,
on_bus_acquired,
on_name_acquired,
on_name_lost,
&cmd,
NULL);
g_main_loop_run(loop);
g_bus_unown_name(id);
g_main_loop_unref(loop);
return 0;
}