// auto generated bindings, don't manually edit #include "lua_generated_bindings.h" #include "lua_boxed_numerics.h" #include #include #include #include #include #include #include #include #include #include #include #if !defined(AP_TERRAIN_AVAILABLE) || (AP_TERRAIN_AVAILABLE != 1) #error Scripting requires terrain to be available #endif // !defined(AP_TERRAIN_AVAILABLE) || (AP_TERRAIN_AVAILABLE != 1) static int binding_argcheck(lua_State *L, int expected_arg_count) { const int args = lua_gettop(L); if (args > expected_arg_count) { return luaL_argerror(L, args, "too many arguments"); } else if (args < expected_arg_count) { return luaL_argerror(L, args, "too few arguments"); } return 0; } int new_Vector2f(lua_State *L) { luaL_checkstack(L, 2, "Out of stack"); void *ud = lua_newuserdata(L, sizeof(Vector2f)); memset(ud, 0, sizeof(Vector2f)); new (ud) Vector2f(); luaL_getmetatable(L, "Vector2f"); lua_setmetatable(L, -2); return 1; } int new_Vector3f(lua_State *L) { luaL_checkstack(L, 2, "Out of stack"); void *ud = lua_newuserdata(L, sizeof(Vector3f)); memset(ud, 0, sizeof(Vector3f)); new (ud) Vector3f(); luaL_getmetatable(L, "Vector3f"); lua_setmetatable(L, -2); return 1; } int new_Location(lua_State *L) { luaL_checkstack(L, 2, "Out of stack"); void *ud = lua_newuserdata(L, sizeof(Location)); memset(ud, 0, sizeof(Location)); new (ud) Location(); luaL_getmetatable(L, "Location"); lua_setmetatable(L, -2); return 1; } Vector2f * check_Vector2f(lua_State *L, int arg) { void *data = luaL_checkudata(L, arg, "Vector2f"); return (Vector2f *)data; } Vector3f * check_Vector3f(lua_State *L, int arg) { void *data = luaL_checkudata(L, arg, "Vector3f"); return (Vector3f *)data; } Location * check_Location(lua_State *L, int arg) { void *data = luaL_checkudata(L, arg, "Location"); return (Location *)data; } static int Vector2f_y(lua_State *L) { Vector2f *ud = check_Vector2f(L, 1); switch(lua_gettop(L)) { case 1: lua_pushnumber(L, ud->y); return 1; case 2: { const float raw_data_2 = luaL_checknumber(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_2 <= MIN(FLT_MAX, INFINITY))), 2, "y out of range"); const float data_2 = raw_data_2; ud->y = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Vector2f_x(lua_State *L) { Vector2f *ud = check_Vector2f(L, 1); switch(lua_gettop(L)) { case 1: lua_pushnumber(L, ud->x); return 1; case 2: { const float raw_data_2 = luaL_checknumber(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_2 <= MIN(FLT_MAX, INFINITY))), 2, "x out of range"); const float data_2 = raw_data_2; ud->x = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Vector3f_z(lua_State *L) { Vector3f *ud = check_Vector3f(L, 1); switch(lua_gettop(L)) { case 1: lua_pushnumber(L, ud->z); return 1; case 2: { const float raw_data_2 = luaL_checknumber(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_2 <= MIN(FLT_MAX, INFINITY))), 2, "z out of range"); const float data_2 = raw_data_2; ud->z = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Vector3f_y(lua_State *L) { Vector3f *ud = check_Vector3f(L, 1); switch(lua_gettop(L)) { case 1: lua_pushnumber(L, ud->y); return 1; case 2: { const float raw_data_2 = luaL_checknumber(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_2 <= MIN(FLT_MAX, INFINITY))), 2, "y out of range"); const float data_2 = raw_data_2; ud->y = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Vector3f_x(lua_State *L) { Vector3f *ud = check_Vector3f(L, 1); switch(lua_gettop(L)) { case 1: lua_pushnumber(L, ud->x); return 1; case 2: { const float raw_data_2 = luaL_checknumber(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_2 <= MIN(FLT_MAX, INFINITY))), 2, "x out of range"); const float data_2 = raw_data_2; ud->x = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Location_loiter_xtrack(lua_State *L) { Location *ud = check_Location(L, 1); switch(lua_gettop(L)) { case 1: lua_pushinteger(L, ud->loiter_xtrack); return 1; case 2: { const bool data_2 = static_cast(lua_toboolean(L, 2)); ud->loiter_xtrack = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Location_origin_alt(lua_State *L) { Location *ud = check_Location(L, 1); switch(lua_gettop(L)) { case 1: lua_pushinteger(L, ud->origin_alt); return 1; case 2: { const bool data_2 = static_cast(lua_toboolean(L, 2)); ud->origin_alt = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Location_terrain_alt(lua_State *L) { Location *ud = check_Location(L, 1); switch(lua_gettop(L)) { case 1: lua_pushinteger(L, ud->terrain_alt); return 1; case 2: { const bool data_2 = static_cast(lua_toboolean(L, 2)); ud->terrain_alt = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Location_relative_alt(lua_State *L) { Location *ud = check_Location(L, 1); switch(lua_gettop(L)) { case 1: lua_pushinteger(L, ud->relative_alt); return 1; case 2: { const bool data_2 = static_cast(lua_toboolean(L, 2)); ud->relative_alt = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Location_lng(lua_State *L) { Location *ud = check_Location(L, 1); switch(lua_gettop(L)) { case 1: lua_pushinteger(L, ud->lng); return 1; case 2: { const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-1800000000, INT32_MIN)) && (raw_data_2 <= MIN(1800000000, INT32_MAX))), 2, "lng out of range"); const int32_t data_2 = raw_data_2; ud->lng = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Location_lat(lua_State *L) { Location *ud = check_Location(L, 1); switch(lua_gettop(L)) { case 1: lua_pushinteger(L, ud->lat); return 1; case 2: { const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-900000000, INT32_MIN)) && (raw_data_2 <= MIN(900000000, INT32_MAX))), 2, "lat out of range"); const int32_t data_2 = raw_data_2; ud->lat = data_2; return 0; } default: return luaL_argerror(L, lua_gettop(L), "too many arguments"); } } static int Vector2f_is_zero(lua_State *L) { binding_argcheck(L, 1); Vector2f * ud = check_Vector2f(L, 1); const bool data = ud->is_zero(); lua_pushboolean(L, data); return 1; } static int Vector2f_is_inf(lua_State *L) { binding_argcheck(L, 1); Vector2f * ud = check_Vector2f(L, 1); const bool data = ud->is_inf(); lua_pushboolean(L, data); return 1; } static int Vector2f_is_nan(lua_State *L) { binding_argcheck(L, 1); Vector2f * ud = check_Vector2f(L, 1); const bool data = ud->is_nan(); lua_pushboolean(L, data); return 1; } static int Vector2f_normalize(lua_State *L) { binding_argcheck(L, 1); Vector2f * ud = check_Vector2f(L, 1); ud->normalize(); return 0; } static int Vector2f_length(lua_State *L) { binding_argcheck(L, 1); Vector2f * ud = check_Vector2f(L, 1); const float data = ud->length(); lua_pushnumber(L, data); return 1; } static int Vector2f___add(lua_State *L) { binding_argcheck(L, 2); Vector2f *ud = check_Vector2f(L, 1); Vector2f *ud2 = check_Vector2f(L, 2); new_Vector2f(L); *check_Vector2f(L, -1) = *ud + *ud2;; return 1; } static int Vector2f___sub(lua_State *L) { binding_argcheck(L, 2); Vector2f *ud = check_Vector2f(L, 1); Vector2f *ud2 = check_Vector2f(L, 2); new_Vector2f(L); *check_Vector2f(L, -1) = *ud - *ud2;; return 1; } static int Vector3f_is_zero(lua_State *L) { binding_argcheck(L, 1); Vector3f * ud = check_Vector3f(L, 1); const bool data = ud->is_zero(); lua_pushboolean(L, data); return 1; } static int Vector3f_is_inf(lua_State *L) { binding_argcheck(L, 1); Vector3f * ud = check_Vector3f(L, 1); const bool data = ud->is_inf(); lua_pushboolean(L, data); return 1; } static int Vector3f_is_nan(lua_State *L) { binding_argcheck(L, 1); Vector3f * ud = check_Vector3f(L, 1); const bool data = ud->is_nan(); lua_pushboolean(L, data); return 1; } static int Vector3f_normalize(lua_State *L) { binding_argcheck(L, 1); Vector3f * ud = check_Vector3f(L, 1); ud->normalize(); return 0; } static int Vector3f_length(lua_State *L) { binding_argcheck(L, 1); Vector3f * ud = check_Vector3f(L, 1); const float data = ud->length(); lua_pushnumber(L, data); return 1; } static int Vector3f___add(lua_State *L) { binding_argcheck(L, 2); Vector3f *ud = check_Vector3f(L, 1); Vector3f *ud2 = check_Vector3f(L, 2); new_Vector3f(L); *check_Vector3f(L, -1) = *ud + *ud2;; return 1; } static int Vector3f___sub(lua_State *L) { binding_argcheck(L, 2); Vector3f *ud = check_Vector3f(L, 1); Vector3f *ud2 = check_Vector3f(L, 2); new_Vector3f(L); *check_Vector3f(L, -1) = *ud - *ud2;; return 1; } static int Location_get_vector_from_origin_NEU(lua_State *L) { binding_argcheck(L, 1); Location * ud = check_Location(L, 1); Vector3f data_5002 = {}; const bool data = ud->get_vector_from_origin_NEU( data_5002); if (data) { new_Vector3f(L); *check_Vector3f(L, -1) = data_5002; } else { lua_pushnil(L); } return 1; } static int Location_offset(lua_State *L) { binding_argcheck(L, 3); Location * ud = check_Location(L, 1); const float raw_data_2 = luaL_checknumber(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_2 <= MIN(FLT_MAX, INFINITY))), 2, "argument out of range"); const float data_2 = raw_data_2; const float raw_data_3 = luaL_checknumber(L, 3); luaL_argcheck(L, ((raw_data_3 >= MAX(-FLT_MAX, -INFINITY)) && (raw_data_3 <= MIN(FLT_MAX, INFINITY))), 3, "argument out of range"); const float data_3 = raw_data_3; ud->offset( data_2, data_3); return 0; } static int Location_get_distance(lua_State *L) { binding_argcheck(L, 2); Location * ud = check_Location(L, 1); Location & data_2 = *check_Location(L, 2); const float data = ud->get_distance( data_2); lua_pushnumber(L, data); return 1; } const luaL_Reg Vector2f_meta[] = { {"y", Vector2f_y}, {"x", Vector2f_x}, {"is_zero", Vector2f_is_zero}, {"is_inf", Vector2f_is_inf}, {"is_nan", Vector2f_is_nan}, {"normalize", Vector2f_normalize}, {"length", Vector2f_length}, {"__add", Vector2f___add}, {"__sub", Vector2f___sub}, {NULL, NULL} }; const luaL_Reg Vector3f_meta[] = { {"z", Vector3f_z}, {"y", Vector3f_y}, {"x", Vector3f_x}, {"is_zero", Vector3f_is_zero}, {"is_inf", Vector3f_is_inf}, {"is_nan", Vector3f_is_nan}, {"normalize", Vector3f_normalize}, {"length", Vector3f_length}, {"__add", Vector3f___add}, {"__sub", Vector3f___sub}, {NULL, NULL} }; const luaL_Reg Location_meta[] = { {"loiter_xtrack", Location_loiter_xtrack}, {"origin_alt", Location_origin_alt}, {"terrain_alt", Location_terrain_alt}, {"relative_alt", Location_relative_alt}, {"lng", Location_lng}, {"lat", Location_lat}, {"get_vector_from_origin_NEU", Location_get_vector_from_origin_NEU}, {"offset", Location_offset}, {"get_distance", Location_get_distance}, {NULL, NULL} }; static int GCS_set_message_interval(lua_State *L) { GCS * ud = GCS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gcs not supported on this firmware"); } binding_argcheck(L, 4); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(MAVLINK_COMM_NUM_BUFFERS, UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint32_t raw_data_3 = *check_uint32_t(L, 3); luaL_argcheck(L, ((raw_data_3 >= MAX(0U, 0U)) && (raw_data_3 <= MIN(UINT32_MAX, UINT32_MAX))), 3, "argument out of range"); const uint32_t data_3 = static_cast(raw_data_3); const lua_Integer raw_data_4 = luaL_checkinteger(L, 4); luaL_argcheck(L, ((raw_data_4 >= MAX(-1, INT32_MIN)) && (raw_data_4 <= MIN(INT32_MAX, INT32_MAX))), 4, "argument out of range"); const int32_t data_4 = raw_data_4; const MAV_RESULT &data = ud->set_message_interval( data_2, data_3, data_4); lua_pushinteger(L, data); return 1; } static int GCS_send_text(lua_State *L) { GCS * ud = GCS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gcs not supported on this firmware"); } binding_argcheck(L, 3); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= static_cast(MAV_SEVERITY_EMERGENCY)) && (raw_data_2 <= static_cast(MAV_SEVERITY_DEBUG))), 2, "argument out of range"); const MAV_SEVERITY data_2 = static_cast(raw_data_2); const char * data_3 = luaL_checkstring(L, 3); ud->send_text( data_2, "%s", data_3); return 0; } static int AP_Relay_toggle(lua_State *L) { AP_Relay * ud = AP_Relay::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "relay not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(AP_RELAY_NUM_RELAYS, UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); ud->toggle( data_2); return 0; } static int AP_Relay_enabled(lua_State *L) { AP_Relay * ud = AP_Relay::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "relay not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(AP_RELAY_NUM_RELAYS, UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const bool data = ud->enabled( data_2); lua_pushboolean(L, data); return 1; } static int AP_Relay_off(lua_State *L) { AP_Relay * ud = AP_Relay::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "relay not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(AP_RELAY_NUM_RELAYS, UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); ud->off( data_2); return 0; } static int AP_Relay_on(lua_State *L) { AP_Relay * ud = AP_Relay::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "relay not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(AP_RELAY_NUM_RELAYS, UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); ud->on( data_2); return 0; } static int AP_Terrain_height_above_terrain(lua_State *L) { AP_Terrain * ud = AP_Terrain::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "terrain not supported on this firmware"); } binding_argcheck(L, 2); float data_5002 = {}; const bool data_3 = static_cast(lua_toboolean(L, 3)); const bool data = ud->height_above_terrain( data_5002, data_3); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_Terrain_height_terrain_difference_home(lua_State *L) { AP_Terrain * ud = AP_Terrain::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "terrain not supported on this firmware"); } binding_argcheck(L, 2); float data_5002 = {}; const bool data_3 = static_cast(lua_toboolean(L, 3)); const bool data = ud->height_terrain_difference_home( data_5002, data_3); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_Terrain_height_amsl(lua_State *L) { AP_Terrain * ud = AP_Terrain::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "terrain not supported on this firmware"); } binding_argcheck(L, 3); Location & data_2 = *check_Location(L, 2); float data_5003 = {}; const bool data_4 = static_cast(lua_toboolean(L, 4)); const bool data = ud->height_amsl( data_2, data_5003, data_4); if (data) { lua_pushnumber(L, data_5003); } else { lua_pushnil(L); } return 1; } static int AP_Terrain_status(lua_State *L) { AP_Terrain * ud = AP_Terrain::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "terrain not supported on this firmware"); } binding_argcheck(L, 1); const uint8_t data = ud->status(); lua_pushinteger(L, data); return 1; } static int AP_Terrain_enabled(lua_State *L) { AP_Terrain * ud = AP_Terrain::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "terrain not supported on this firmware"); } binding_argcheck(L, 1); const bool data = ud->enabled(); lua_pushboolean(L, data); return 1; } static int RangeFinder_num_sensors(lua_State *L) { RangeFinder * ud = RangeFinder::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "rangefinder not supported on this firmware"); } binding_argcheck(L, 1); const uint8_t data = ud->num_sensors(); lua_pushinteger(L, data); return 1; } static int AP_Notify_play_tune(lua_State *L) { AP_Notify * ud = AP_Notify::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "notify not supported on this firmware"); } binding_argcheck(L, 2); const char * data_2 = luaL_checkstring(L, 2); ud->play_tune( data_2); return 0; } static int AP_GPS_first_unconfigured_gps(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 1); uint8_t data_5002 = {}; const bool data = ud->first_unconfigured_gps( data_5002); if (data) { lua_pushinteger(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_GPS_get_antenna_offset(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const Vector3f &data = ud->get_antenna_offset( data_2); new_Vector3f(L); *check_Vector3f(L, -1) = data; return 1; } static int AP_GPS_have_vertical_velocity(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const bool data = ud->have_vertical_velocity( data_2); lua_pushboolean(L, data); return 1; } static int AP_GPS_last_message_time_ms(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint32_t data = ud->last_message_time_ms( data_2); new_uint32_t(L); *static_cast(luaL_checkudata(L, -1, "uint32_t")) = data; return 1; } static int AP_GPS_last_fix_time_ms(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint32_t data = ud->last_fix_time_ms( data_2); new_uint32_t(L); *static_cast(luaL_checkudata(L, -1, "uint32_t")) = data; return 1; } static int AP_GPS_get_vdop(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint16_t data = ud->get_vdop( data_2); lua_pushinteger(L, data); return 1; } static int AP_GPS_get_hdop(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint16_t data = ud->get_hdop( data_2); lua_pushinteger(L, data); return 1; } static int AP_GPS_time_week_ms(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint32_t data = ud->time_week_ms( data_2); new_uint32_t(L); *static_cast(luaL_checkudata(L, -1, "uint32_t")) = data; return 1; } static int AP_GPS_time_week(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint16_t data = ud->time_week( data_2); lua_pushinteger(L, data); return 1; } static int AP_GPS_num_sats(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint8_t data = ud->num_sats( data_2); lua_pushinteger(L, data); return 1; } static int AP_GPS_ground_course(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const float data = ud->ground_course( data_2); lua_pushnumber(L, data); return 1; } static int AP_GPS_ground_speed(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const float data = ud->ground_speed( data_2); lua_pushnumber(L, data); return 1; } static int AP_GPS_velocity(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const Vector3f &data = ud->velocity( data_2); new_Vector3f(L); *check_Vector3f(L, -1) = data; return 1; } static int AP_GPS_vertical_accuracy(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); float data_5003 = {}; const bool data = ud->vertical_accuracy( data_2, data_5003); if (data) { lua_pushnumber(L, data_5003); } else { lua_pushnil(L); } return 1; } static int AP_GPS_horizontal_accuracy(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); float data_5003 = {}; const bool data = ud->horizontal_accuracy( data_2, data_5003); if (data) { lua_pushnumber(L, data_5003); } else { lua_pushnil(L); } return 1; } static int AP_GPS_speed_accuracy(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); float data_5003 = {}; const bool data = ud->speed_accuracy( data_2, data_5003); if (data) { lua_pushnumber(L, data_5003); } else { lua_pushnil(L); } return 1; } static int AP_GPS_location(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const Location &data = ud->location( data_2); new_Location(L); *check_Location(L, -1) = data; return 1; } static int AP_GPS_status(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_sensors(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint8_t data = ud->status( data_2); lua_pushinteger(L, data); return 1; } static int AP_GPS_primary_sensor(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 1); const uint8_t data = ud->primary_sensor(); lua_pushinteger(L, data); return 1; } static int AP_GPS_num_sensors(lua_State *L) { AP_GPS * ud = AP_GPS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "gps not supported on this firmware"); } binding_argcheck(L, 1); const uint8_t data = ud->num_sensors(); lua_pushinteger(L, data); return 1; } static int AP_BattMonitor_get_temperature(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); float data_5002 = {}; const lua_Integer raw_data_3 = luaL_checkinteger(L, 3); luaL_argcheck(L, ((raw_data_3 >= MAX(0, 0)) && (raw_data_3 <= MIN(ud->num_instances(), UINT8_MAX))), 3, "argument out of range"); const uint8_t data_3 = static_cast(raw_data_3); const bool data = ud->get_temperature( data_5002, data_3); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_BattMonitor_overpower_detected(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_instances(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const bool data = ud->overpower_detected( data_2); lua_pushboolean(L, data); return 1; } static int AP_BattMonitor_has_failsafed(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 1); const bool data = ud->has_failsafed(); lua_pushboolean(L, data); return 1; } static int AP_BattMonitor_pack_capacity_mah(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_instances(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const int32_t data = ud->pack_capacity_mah( data_2); lua_pushinteger(L, data); return 1; } static int AP_BattMonitor_capacity_remaining_pct(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_instances(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const uint8_t data = ud->capacity_remaining_pct( data_2); lua_pushinteger(L, data); return 1; } static int AP_BattMonitor_consumed_wh(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); float data_5002 = {}; const lua_Integer raw_data_3 = luaL_checkinteger(L, 3); luaL_argcheck(L, ((raw_data_3 >= MAX(0, 0)) && (raw_data_3 <= MIN(ud->num_instances(), UINT8_MAX))), 3, "argument out of range"); const uint8_t data_3 = static_cast(raw_data_3); const bool data = ud->consumed_wh( data_5002, data_3); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_BattMonitor_consumed_mah(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); float data_5002 = {}; const lua_Integer raw_data_3 = luaL_checkinteger(L, 3); luaL_argcheck(L, ((raw_data_3 >= MAX(0, 0)) && (raw_data_3 <= MIN(ud->num_instances(), UINT8_MAX))), 3, "argument out of range"); const uint8_t data_3 = static_cast(raw_data_3); const bool data = ud->consumed_mah( data_5002, data_3); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_BattMonitor_current_amps(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); float data_5002 = {}; const lua_Integer raw_data_3 = luaL_checkinteger(L, 3); luaL_argcheck(L, ((raw_data_3 >= MAX(0, 0)) && (raw_data_3 <= MIN(ud->num_instances(), UINT8_MAX))), 3, "argument out of range"); const uint8_t data_3 = static_cast(raw_data_3); const bool data = ud->current_amps( data_5002, data_3); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_BattMonitor_voltage_resting_estimate(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_instances(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const float data = ud->voltage_resting_estimate( data_2); lua_pushnumber(L, data); return 1; } static int AP_BattMonitor_voltage(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_instances(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const float data = ud->voltage( data_2); lua_pushnumber(L, data); return 1; } static int AP_BattMonitor_healthy(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 2); const lua_Integer raw_data_2 = luaL_checkinteger(L, 2); luaL_argcheck(L, ((raw_data_2 >= MAX(0, 0)) && (raw_data_2 <= MIN(ud->num_instances(), UINT8_MAX))), 2, "argument out of range"); const uint8_t data_2 = static_cast(raw_data_2); const bool data = ud->healthy( data_2); lua_pushboolean(L, data); return 1; } static int AP_BattMonitor_num_instances(lua_State *L) { AP_BattMonitor * ud = AP_BattMonitor::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "battery not supported on this firmware"); } binding_argcheck(L, 1); const uint8_t data = ud->num_instances(); lua_pushinteger(L, data); return 1; } static int AP_Arming_arm(lua_State *L) { AP_Arming * ud = AP_Arming::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "arming not supported on this firmware"); } binding_argcheck(L, 1); const bool data = ud->arm( AP_Arming::Method::SCRIPTING); lua_pushboolean(L, data); return 1; } static int AP_Arming_is_armed(lua_State *L) { AP_Arming * ud = AP_Arming::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "arming not supported on this firmware"); } binding_argcheck(L, 1); const bool data = ud->is_armed(); lua_pushboolean(L, data); return 1; } static int AP_Arming_disarm(lua_State *L) { AP_Arming * ud = AP_Arming::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "arming not supported on this firmware"); } binding_argcheck(L, 1); const bool data = ud->disarm(); lua_pushboolean(L, data); return 1; } static int AP_AHRS_prearm_healthy(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const bool data = ud->prearm_healthy(); ud->get_semaphore().give(); lua_pushboolean(L, data); return 1; } static int AP_AHRS_home_is_set(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const bool data = ud->home_is_set(); ud->get_semaphore().give(); lua_pushboolean(L, data); return 1; } static int AP_AHRS_get_relative_position_NED_home(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); Vector3f data_5002 = {}; ud->get_semaphore().take_blocking(); const bool data = ud->get_relative_position_NED_home( data_5002); ud->get_semaphore().give(); if (data) { new_Vector3f(L); *check_Vector3f(L, -1) = data_5002; } else { lua_pushnil(L); } return 1; } static int AP_AHRS_get_velocity_NED(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); Vector3f data_5002 = {}; ud->get_semaphore().take_blocking(); const bool data = ud->get_velocity_NED( data_5002); ud->get_semaphore().give(); if (data) { new_Vector3f(L); *check_Vector3f(L, -1) = data_5002; } else { lua_pushnil(L); } return 1; } static int AP_AHRS_groundspeed_vector(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const Vector2f &data = ud->groundspeed_vector(); ud->get_semaphore().give(); new_Vector2f(L); *check_Vector2f(L, -1) = data; return 1; } static int AP_AHRS_wind_estimate(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const Vector3f &data = ud->wind_estimate(); ud->get_semaphore().give(); new_Vector3f(L); *check_Vector3f(L, -1) = data; return 1; } static int AP_AHRS_get_hagl(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); float data_5002 = {}; ud->get_semaphore().take_blocking(); const bool data = ud->get_hagl( data_5002); ud->get_semaphore().give(); if (data) { lua_pushnumber(L, data_5002); } else { lua_pushnil(L); } return 1; } static int AP_AHRS_get_gyro(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const Vector3f &data = ud->get_gyro(); ud->get_semaphore().give(); new_Vector3f(L); *check_Vector3f(L, -1) = data; return 1; } static int AP_AHRS_get_home(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const Location &data = ud->get_home(); ud->get_semaphore().give(); new_Location(L); *check_Location(L, -1) = data; return 1; } static int AP_AHRS_get_position(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); Location data_5002 = {}; ud->get_semaphore().take_blocking(); const bool data = ud->get_position( data_5002); ud->get_semaphore().give(); if (data) { new_Location(L); *check_Location(L, -1) = data_5002; } else { lua_pushnil(L); } return 1; } static int AP_AHRS_get_yaw(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const float data = ud->get_yaw(); ud->get_semaphore().give(); lua_pushnumber(L, data); return 1; } static int AP_AHRS_get_pitch(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const float data = ud->get_pitch(); ud->get_semaphore().give(); lua_pushnumber(L, data); return 1; } static int AP_AHRS_get_roll(lua_State *L) { AP_AHRS * ud = AP_AHRS::get_singleton(); if (ud == nullptr) { return luaL_argerror(L, 1, "ahrs not supported on this firmware"); } binding_argcheck(L, 1); ud->get_semaphore().take_blocking(); const float data = ud->get_roll(); ud->get_semaphore().give(); lua_pushnumber(L, data); return 1; } const luaL_Reg GCS_meta[] = { {"set_message_interval", GCS_set_message_interval}, {"send_text", GCS_send_text}, {NULL, NULL} }; const luaL_Reg AP_Relay_meta[] = { {"toggle", AP_Relay_toggle}, {"enabled", AP_Relay_enabled}, {"off", AP_Relay_off}, {"on", AP_Relay_on}, {NULL, NULL} }; const luaL_Reg AP_Terrain_meta[] = { {"height_above_terrain", AP_Terrain_height_above_terrain}, {"height_terrain_difference_home", AP_Terrain_height_terrain_difference_home}, {"height_amsl", AP_Terrain_height_amsl}, {"status", AP_Terrain_status}, {"enabled", AP_Terrain_enabled}, {NULL, NULL} }; const luaL_Reg RangeFinder_meta[] = { {"num_sensors", RangeFinder_num_sensors}, {NULL, NULL} }; const luaL_Reg AP_Notify_meta[] = { {"play_tune", AP_Notify_play_tune}, {NULL, NULL} }; const luaL_Reg AP_GPS_meta[] = { {"first_unconfigured_gps", AP_GPS_first_unconfigured_gps}, {"get_antenna_offset", AP_GPS_get_antenna_offset}, {"have_vertical_velocity", AP_GPS_have_vertical_velocity}, {"last_message_time_ms", AP_GPS_last_message_time_ms}, {"last_fix_time_ms", AP_GPS_last_fix_time_ms}, {"get_vdop", AP_GPS_get_vdop}, {"get_hdop", AP_GPS_get_hdop}, {"time_week_ms", AP_GPS_time_week_ms}, {"time_week", AP_GPS_time_week}, {"num_sats", AP_GPS_num_sats}, {"ground_course", AP_GPS_ground_course}, {"ground_speed", AP_GPS_ground_speed}, {"velocity", AP_GPS_velocity}, {"vertical_accuracy", AP_GPS_vertical_accuracy}, {"horizontal_accuracy", AP_GPS_horizontal_accuracy}, {"speed_accuracy", AP_GPS_speed_accuracy}, {"location", AP_GPS_location}, {"status", AP_GPS_status}, {"primary_sensor", AP_GPS_primary_sensor}, {"num_sensors", AP_GPS_num_sensors}, {NULL, NULL} }; const luaL_Reg AP_BattMonitor_meta[] = { {"get_temperature", AP_BattMonitor_get_temperature}, {"overpower_detected", AP_BattMonitor_overpower_detected}, {"has_failsafed", AP_BattMonitor_has_failsafed}, {"pack_capacity_mah", AP_BattMonitor_pack_capacity_mah}, {"capacity_remaining_pct", AP_BattMonitor_capacity_remaining_pct}, {"consumed_wh", AP_BattMonitor_consumed_wh}, {"consumed_mah", AP_BattMonitor_consumed_mah}, {"current_amps", AP_BattMonitor_current_amps}, {"voltage_resting_estimate", AP_BattMonitor_voltage_resting_estimate}, {"voltage", AP_BattMonitor_voltage}, {"healthy", AP_BattMonitor_healthy}, {"num_instances", AP_BattMonitor_num_instances}, {NULL, NULL} }; const luaL_Reg AP_Arming_meta[] = { {"arm", AP_Arming_arm}, {"is_armed", AP_Arming_is_armed}, {"disarm", AP_Arming_disarm}, {NULL, NULL} }; const luaL_Reg AP_AHRS_meta[] = { {"prearm_healthy", AP_AHRS_prearm_healthy}, {"home_is_set", AP_AHRS_home_is_set}, {"get_relative_position_NED_home", AP_AHRS_get_relative_position_NED_home}, {"get_velocity_NED", AP_AHRS_get_velocity_NED}, {"groundspeed_vector", AP_AHRS_groundspeed_vector}, {"wind_estimate", AP_AHRS_wind_estimate}, {"get_hagl", AP_AHRS_get_hagl}, {"get_gyro", AP_AHRS_get_gyro}, {"get_home", AP_AHRS_get_home}, {"get_position", AP_AHRS_get_position}, {"get_yaw", AP_AHRS_get_yaw}, {"get_pitch", AP_AHRS_get_pitch}, {"get_roll", AP_AHRS_get_roll}, {NULL, NULL} }; struct userdata_enum { const char *name; int value; }; struct userdata_enum AP_Terrain_enums[] = { {"TerrainStatusOK", AP_Terrain::TerrainStatusOK}, {"TerrainStatusUnhealthy", AP_Terrain::TerrainStatusUnhealthy}, {"TerrainStatusDisabled", AP_Terrain::TerrainStatusDisabled}, {NULL, 0}}; struct userdata_enum AP_GPS_enums[] = { {"GPS_OK_FIX_3D_RTK_FIXED", AP_GPS::GPS_OK_FIX_3D_RTK_FIXED}, {"GPS_OK_FIX_3D_RTK_FLOAT", AP_GPS::GPS_OK_FIX_3D_RTK_FLOAT}, {"GPS_OK_FIX_3D_DGPS", AP_GPS::GPS_OK_FIX_3D_DGPS}, {"GPS_OK_FIX_3D", AP_GPS::GPS_OK_FIX_3D}, {"GPS_OK_FIX_2D", AP_GPS::GPS_OK_FIX_2D}, {"NO_FIX", AP_GPS::NO_FIX}, {"NO_GPS", AP_GPS::NO_GPS}, {NULL, 0}}; struct userdata_meta { const char *name; const luaL_Reg *reg; const struct userdata_enum *enums; }; const struct userdata_meta userdata_fun[] = { {"Vector2f", Vector2f_meta, NULL}, {"Vector3f", Vector3f_meta, NULL}, {"Location", Location_meta, NULL}, }; const struct userdata_meta singleton_fun[] = { {"gcs", GCS_meta, NULL}, {"relay", AP_Relay_meta, NULL}, {"terrain", AP_Terrain_meta, AP_Terrain_enums}, {"rangefinder", RangeFinder_meta, NULL}, {"notify", AP_Notify_meta, NULL}, {"gps", AP_GPS_meta, AP_GPS_enums}, {"battery", AP_BattMonitor_meta, NULL}, {"arming", AP_Arming_meta, NULL}, {"ahrs", AP_AHRS_meta, NULL}, }; void load_generated_bindings(lua_State *L) { luaL_checkstack(L, 5, "Out of stack"); // userdata metatables for (uint32_t i = 0; i < ARRAY_SIZE(userdata_fun); i++) { luaL_newmetatable(L, userdata_fun[i].name); luaL_setfuncs(L, userdata_fun[i].reg, 0); lua_pushstring(L, "__index"); lua_pushvalue(L, -2); lua_settable(L, -3); lua_pop(L, 1); } // singleton metatables for (uint32_t i = 0; i < ARRAY_SIZE(singleton_fun); i++) { luaL_newmetatable(L, singleton_fun[i].name); luaL_setfuncs(L, singleton_fun[i].reg, 0); lua_pushstring(L, "__index"); lua_pushvalue(L, -2); lua_settable(L, -3); if (singleton_fun[i].enums != nullptr) { int j = 0; while (singleton_fun[i].enums[j].name != NULL) { lua_pushstring(L, singleton_fun[i].enums[j].name); lua_pushinteger(L, singleton_fun[i].enums[j].value); lua_settable(L, -3); j++; } } lua_pop(L, 1); lua_newuserdata(L, 0); luaL_getmetatable(L, singleton_fun[i].name); lua_setmetatable(L, -2); lua_setglobal(L, singleton_fun[i].name); } load_boxed_numerics(L); } const char *singletons[] = { "gcs", "relay", "terrain", "rangefinder", "notify", "gps", "battery", "arming", "ahrs", }; const struct userdata { const char *name; const lua_CFunction fun; } new_userdata[] = { {"Vector2f", new_Vector2f}, {"Vector3f", new_Vector3f}, {"Location", new_Location}, }; void load_generated_sandbox(lua_State *L) { for (uint32_t i = 0; i < ARRAY_SIZE(singletons); i++) { lua_pushstring(L, singletons[i]); lua_getglobal(L, singletons[i]); lua_settable(L, -3); } for (uint32_t i = 0; i < ARRAY_SIZE(new_userdata); i++) { lua_pushstring(L, new_userdata[i].name); lua_pushcfunction(L, new_userdata[i].fun); lua_settable(L, -3); } load_boxed_numerics_sandbox(L); }