mirror of https://github.com/arendst/Tasmota.git
557 lines
18 KiB
C++
557 lines
18 KiB
C++
/*
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xdrv_52_3_berry_native.ino - Berry scripting language, native fucnctions
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Copyright (C) 2021 Stephan Hadinger, Berry language by Guan Wenliang https://github.com/Skiars/berry
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifdef USE_BERRY
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#include <berry.h>
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#include <Wire.h>
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const uint32_t BERRY_MAX_LOGS = 16; // max number of print output recorded when outside of REPL, used to avoid infinite grow of logs
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/*********************************************************************************************\
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* Native functions mapped to Berry functions
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*
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* log(msg:string [,log_level:int]) ->nil
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*
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* import tasmota
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*
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* tasmota.get_free_heap() -> int
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* tasmota.publish(topic:string, payload:string[, retain:bool]) -> nil
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* tasmota.cmd(command:string) -> string
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* tasmota.get_option(index:int) -> int
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* tasmota.millis([delay:int]) -> int
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* tasmota.time_reached(timer:int) -> bool
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* tasmota.yield() -> nil
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*
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* tasmota.get_light([index:int = 0]) -> map
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* tasmota.get_power([index:int = 0]) -> bool
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* tasmota.set_power(idx:int, power:bool) -> bool or nil
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* tasmota.set_light(idx:int, values:map) -> map
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*
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\*********************************************************************************************/
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extern "C" {
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// Berry: `tasmota.publish(topic, payload [,retain]) -> nil``
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//
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int32_t l_publish(struct bvm *vm);
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int32_t l_publish(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top >= 3 && be_isstring(vm, 2) && be_isstring(vm, 3)) { // 2 mandatory string arguments
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if (top == 3 || (top == 4 && be_isbool(vm, 4))) { // 3rd optional argument must be bool
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const char * topic = be_tostring(vm, 2);
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const char * payload = be_tostring(vm, 3);
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bool retain = false;
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if (top == 4) {
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retain = be_tobool(vm, 4);
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}
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strlcpy(TasmotaGlobal.mqtt_data, payload, sizeof(TasmotaGlobal.mqtt_data));
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MqttPublish(topic, retain);
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be_return(vm); // Return
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}
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// Berry: `tasmota.cmd(command:string) -> string`
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//
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int32_t l_cmd(struct bvm *vm);
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int32_t l_cmd(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2 && be_isstring(vm, 2)) { // only 1 argument of type string accepted
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const char * command = be_tostring(vm, 2);
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ExecuteCommand(command, SRC_BERRY);
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be_pushstring(vm, TasmotaGlobal.mqtt_data);
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be_return(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// Berry: tasmota.millis([delay:int]) -> int
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//
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int32_t l_millis(struct bvm *vm);
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int32_t l_millis(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 1 || (top == 2 && be_isint(vm, 2))) { // only 1 argument of type string accepted
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uint32_t delay = 0;
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if (top == 2) {
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delay = be_toint(vm, 2);
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}
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uint32_t ret_millis = millis() + delay;
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be_pushint(vm, ret_millis);
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be_return(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// Berry: tasmota.get_option(index:int) -> int
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//
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int32_t l_getoption(struct bvm *vm);
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int32_t l_getoption(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2 && be_isint(vm, 2)) {
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uint32_t opt = GetOption(be_toint(vm, 2));
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be_pushint(vm, opt);
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be_return(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// Berry: tasmota.time_reached(timer:int) -> bool
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//
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int32_t l_timereached(struct bvm *vm);
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int32_t l_timereached(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2 && be_isint(vm, 2)) { // only 1 argument of type string accepted
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uint32_t timer = be_toint(vm, 2);
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bool reached = TimeReached(timer);
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be_pushbool(vm, reached);
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be_return(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// Berry: tasmota.delay(timer:int) -> nil
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//
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int32_t l_delay(struct bvm *vm);
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int32_t l_delay(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2 && be_isint(vm, 2)) { // only 1 argument of type string accepted
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uint32_t timer = be_toint(vm, 2);
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delay(timer);
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be_return_nil(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// Berry: `yield() -> nil`
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// ESP object
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int32_t l_yield(bvm *vm);
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int32_t l_yield(bvm *vm) {
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optimistic_yield(10);
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be_return_nil(vm);
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}
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// Berry: tasmota.scale_uint(int * 5) -> int
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//
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int32_t l_scaleuint(struct bvm *vm);
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int32_t l_scaleuint(struct bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 6 && be_isint(vm, 2) && be_isint(vm, 3) && be_isint(vm, 4) && be_isint(vm, 5) && be_isint(vm, 6)) { // only 1 argument of type string accepted
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int32_t v = be_toint(vm, 2);
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int32_t from1 = be_toint(vm, 3);
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int32_t from2 = be_toint(vm, 4);
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int32_t to1 = be_toint(vm, 5);
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int32_t to2 = be_toint(vm, 6);
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int32_t ret = changeUIntScale(v, from1, from2, to1, to2);
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be_pushint(vm, ret);
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be_return(vm);
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}
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be_raise(vm, kTypeError, nullptr);
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}
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int32_t l_respCmnd(bvm *vm);
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int32_t l_respCmnd(bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2) {
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const char *msg = be_tostring(vm, 2);
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Response_P("%s", msg);
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be_return_nil(vm); // Return nil when something goes wrong
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}
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be_raise(vm, kTypeError, nullptr);
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}
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int32_t l_respCmndStr(bvm *vm);
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int32_t l_respCmndStr(bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2) {
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const char *msg = be_tostring(vm, 2);
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ResponseCmndChar(msg);
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be_return_nil(vm); // Return nil when something goes wrong
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}
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be_raise(vm, kTypeError, nullptr);
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}
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int32_t l_respCmndDone(bvm *vm);
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int32_t l_respCmndDone(bvm *vm) {
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ResponseCmndDone();
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be_return_nil(vm);
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}
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int32_t l_respCmndError(bvm *vm);
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int32_t l_respCmndError(bvm *vm) {
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ResponseCmndError();
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be_return_nil(vm);
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}
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int32_t l_respCmndFailed(bvm *vm);
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int32_t l_respCmndFailed(bvm *vm) {
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ResponseCmndFailed();
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be_return_nil(vm);
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}
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// update XdrvMailbox.command with actual command
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int32_t l_resolveCmnd(bvm *vm);
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int32_t l_resolveCmnd(bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 2 && be_isstring(vm, 2)) {
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const char *msg = be_tostring(vm, 2);
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strlcpy(XdrvMailbox.command, msg, CMDSZ);
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be_return_nil(vm); // Return nil when something goes wrong
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// push the light status object on the vm stack
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void push_getlight(bvm *vm, uint32_t light_num) {
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bool data_present = false; // do we have relevant data
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be_newobject(vm, "map");
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// check if the light exist
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// TasmotaGlobal.devices_present
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// Light.device
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// Light.subtype
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// Light.pwm_multi_channels
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// light_controller.isCTRGBLinked()
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if (Light.device > 0) {
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// we have a light
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uint8_t channels[LST_MAX];
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char s_rgb[8] = {0}; // RGB raw levels
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light_controller.calcLevels(channels);
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uint8_t bri = light_state.getBri();
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// map_insert_int(vm, "_devices_present", TasmotaGlobal.devices_present);
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// map_insert_int(vm, "_light_device", Light.device);
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// map_insert_int(vm, "_light_subtype", Light.subtype);
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// map_insert_int(vm, "_light_multi", Light.pwm_multi_channels);
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// map_insert_int(vm, "_light_linked", light_controller.isCTRGBLinked());
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if (!Light.pwm_multi_channels) {
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uint32_t subtype = Light.subtype; // virtual sub-type, for SO37 128
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uint32_t chanidx = 0; // channel offset, for SO37 128
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if (light_controller.isCTRGBLinked() && (light_num == 0)) {
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data_present = true; // valid combination
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if (subtype >= LST_RGBW) {
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map_insert_str(vm, "colormode", (light_state.getColorMode() & LCM_RGB ? "rgb" : "ct"));
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}
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}
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if (!light_controller.isCTRGBLinked()) {
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if (light_num == 0) {
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data_present = true; // valid combination
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if (subtype > LST_RGB) { subtype = LST_RGB; } // limit to RGB
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bri = light_state.getBriRGB();
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}
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if ((light_num == 1) && subtype > LST_RGB) {
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data_present = true; // valid combination
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subtype = subtype - LST_RGB;
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chanidx = 3; // skip first 3 channels
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bri = light_state.getBriCT();
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}
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}
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if (data_present) {
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// see ResponseLightState()
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map_insert_bool(vm, "power", bitRead(TasmotaGlobal.power, light_num));
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map_insert_int(vm, "bri", bri);
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if (subtype >= LST_RGB) {
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uint16_t hue;
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uint8_t sat, bri;
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light_state.getHSB(&hue, &sat, &bri);
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map_insert_int(vm, "hue", hue);
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map_insert_int(vm, "sat", sat);
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}
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if ((LST_COLDWARM == subtype) || (LST_RGBW <= subtype)) {
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map_insert_int(vm, "ct", light_state.getCT());
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}
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if (subtype >= LST_RGB) {
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snprintf(s_rgb, sizeof(s_rgb), PSTR("%02X%02X%02X"), channels[0], channels[1], channels[2]);
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map_insert_str(vm, "rgb", s_rgb);
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}
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if (subtype > LST_NONE) {
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map_insert_list_uint8(vm, "channels", &channels[chanidx], subtype);
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}
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}
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} else { // Light.pwm_multi_channels
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if ((light_num >= 0) && (light_num < LST_MAX)) {
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data_present = true;
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map_insert_bool(vm, "power", Light.power & (1 << light_num));
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map_insert_int(vm, "bri", Light.current_color[light_num]);
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map_insert_list_uint8(vm, "channels", &channels[light_num], 1);
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}
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}
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be_pop(vm, 1);
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if (!data_present) {
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be_pop(vm, 1);
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be_pushnil(vm);
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}
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} else {
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be_pop(vm, 1);
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be_pushnil(vm);
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}
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}
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// get light
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int32_t l_getlight(bvm *vm);
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int32_t l_getlight(bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top == 1 || (top == 2 && be_isint(vm, 2))) {
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int32_t light_num = 0;
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if (top > 1) {
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light_num = be_toint(vm, 2);
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}
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push_getlight(vm, light_num);
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be_return(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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}
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// set light
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int32_t l_setlight(bvm *vm);
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int32_t l_setlight(bvm *vm) {
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int32_t top = be_top(vm); // Get the number of arguments
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if (top >= 2 && be_isinstance(vm, 2) && (top != 3 || be_isint(vm, 3))) {
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int32_t idx = 0;
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if (top >= 3) {
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idx = be_toint(vm, 3);
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be_pop(vm, 1); // remove last argument to have the map at the top of stack
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}
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// power
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if (map_find(vm, "power")) {
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bool power = be_tobool(vm, -1);
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bool current_power = bitRead(TasmotaGlobal.power, idx);
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if (power != current_power) { // only send command if needed
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ExecuteCommandPower(Light.device + idx, (power) ? POWER_ON : POWER_OFF, SRC_BERRY);
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}
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}
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be_pop(vm, 1);
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// ct
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if (map_find(vm, "ct")) {
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int32_t ct = be_toint(vm, -1);
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light_controller.changeCTB(ct, light_state.getBriCT());
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}
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be_pop(vm, 1);
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// hue
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if (map_find(vm, "hue")) {
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int32_t hue = be_toint(vm, -1);
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uint8_t sat;
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uint8_t bri;
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light_state.getHSB(nullptr, &sat, &bri);
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light_controller.changeHSB(hue, sat, bri);
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}
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be_pop(vm, 1);
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// sat
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if (map_find(vm, "sat")) {
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int32_t sat = be_toint(vm, -1);
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uint16_t hue;
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uint8_t bri;
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light_state.getHSB(&hue, nullptr, &bri);
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light_controller.changeHSB(hue, sat, bri);
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}
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be_pop(vm, 1);
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// rgb
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if (map_find(vm, "rgb")) {
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const char * rgb_s = be_tostring(vm, -1);
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SBuffer buf = SBuffer::SBufferFromHex(rgb_s, strlen(rgb_s));
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uint8_t channels[LST_MAX] = {};
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memcpy(channels, buf.buf(), buf.len() > LST_MAX ? LST_MAX : buf.len());
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bool on = false; // if all are zero, then only set power off
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for (uint32_t i = 0; i < LST_MAX; i++) {
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if (channels[i] != 0) { on = true; }
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}
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if (on) {
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light_controller.changeChannels(channels);
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} else {
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ExecuteCommandPower(idx + 1, POWER_OFF, SRC_BERRY);
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}
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}
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be_pop(vm, 1);
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// channels
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if (map_find(vm, "channels")) {
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if (be_isinstance(vm, -1)) {
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be_getbuiltin(vm, "list"); // add "list" class
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if (be_isderived(vm, -2)) {
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be_pop(vm, 1); // remove "list" class from top
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int32_t list_size = get_list_size(vm);
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// AddLog(LOG_LEVEL_INFO, "Instance is list size = %d", list_size);
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uint8_t channels[LST_MAX] = {}; // initialized with all zeroes
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if (list_size > LST_MAX) { list_size = LST_MAX; } // no more than 5 channels, no need to test for positive, any negative will be discarded by loop
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for (uint32_t i = 0; i < list_size; i++) {
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// be_dumpstack(vm);
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get_list_item(vm, i);
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// be_dumpstack(vm);
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int32_t val = be_toint(vm, -1);
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be_pop(vm, 1); // remove result from stack
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channels[i] = to_u8(val);
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bool on = false; // if all are zero, then only set power off
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for (uint32_t i = 0; i < LST_MAX; i++) {
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if (channels[i] != 0) { on = true; }
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}
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if (on) {
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light_controller.changeChannels(channels);
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} else {
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ExecuteCommandPower(idx + 1, POWER_OFF, SRC_BERRY);
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}
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}
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} else {
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be_pop(vm, 1); // remove "list" class from top
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}
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}
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}
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be_pop(vm, 1);
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// bri is done after channels and rgb
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// bri
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if (map_find(vm, "bri")) {
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int32_t bri = be_toint(vm, -1);
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light_controller.changeBri(bri);
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}
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be_pop(vm, 1);
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push_getlight(vm, idx);
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be_return(vm); // Return
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}
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be_raise(vm, kTypeError, nullptr);
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} // TODO
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// get power
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int32_t l_getpower(bvm *vm);
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int32_t l_getpower(bvm *vm) {
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be_newobject(vm, "list");
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for (uint32_t i = 0; i < TasmotaGlobal.devices_present; i++) {
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be_pushbool(vm, bitRead(TasmotaGlobal.power, i));
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be_data_push(vm, -2);
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be_pop(vm, 1);
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}
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be_pop(vm, 1);
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be_return(vm); // Return
|
|
}
|
|
|
|
int32_t l_setpower(bvm *vm);
|
|
int32_t l_setpower(bvm *vm) {
|
|
int32_t top = be_top(vm); // Get the number of arguments
|
|
if (top == 3 && be_isint(vm, 2) && be_isbool(vm, 3)) {
|
|
int32_t idx = be_toint(vm, 2);
|
|
bool power = be_tobool(vm, 3);
|
|
if ((idx >= 0) && (idx < TasmotaGlobal.devices_present)) {
|
|
ExecuteCommandPower(idx + 1, (power) ? POWER_ON : POWER_OFF, SRC_BERRY);
|
|
be_pushbool(vm, power);
|
|
be_return(vm); // Return
|
|
} else {
|
|
be_return_nil(vm);
|
|
}
|
|
}
|
|
be_raise(vm, kTypeError, nullptr);
|
|
}
|
|
|
|
#ifdef USE_I2C
|
|
// I2C specific
|
|
// Berry: `i2c_enabled(index:int) -> bool` is I2C device enabled
|
|
int32_t l_i2cenabled(struct bvm *vm);
|
|
int32_t l_i2cenabled(struct bvm *vm) {
|
|
int32_t top = be_top(vm); // Get the number of arguments
|
|
if (top == 2 && be_isint(vm, 2)) {
|
|
int32_t index = be_toint(vm, 2);
|
|
bool enabled = I2cEnabled(index);
|
|
be_pushbool(vm, enabled);
|
|
be_return(vm); // Return
|
|
}
|
|
be_raise(vm, kTypeError, nullptr);
|
|
}
|
|
#else // USE_I2C
|
|
int32_t l_i2cenabled(struct bvm *vm) __attribute__ ((weak, alias ("b_wire_i2cmissing")));
|
|
#endif // USE_I2C
|
|
|
|
}
|
|
|
|
/*********************************************************************************************\
|
|
* Native functions mapped to Berry functions
|
|
*
|
|
* log(msg:string [,log_level:int]) ->nil
|
|
*
|
|
\*********************************************************************************************/
|
|
extern "C" {
|
|
// Berry: `log(msg:string [,log_level:int]) ->nil`
|
|
// Logs the string at LOG_LEVEL_INFO (loglevel=2)
|
|
int32_t l_logInfo(struct bvm *vm);
|
|
int32_t l_logInfo(struct bvm *vm) {
|
|
int32_t top = be_top(vm); // Get the number of arguments
|
|
if (top >= 1 && be_isstring(vm, 1)) { // only 1 argument of type string accepted
|
|
const char * msg = be_tostring(vm, 1);
|
|
uint32_t log_level = LOG_LEVEL_INFO;
|
|
if (top >= 2 && be_isint(vm, 2)) {
|
|
log_level = be_toint(vm, 2);
|
|
if (log_level > LOG_LEVEL_DEBUG_MORE) { log_level = LOG_LEVEL_DEBUG_MORE; }
|
|
}
|
|
AddLog(log_level, PSTR("%s"), msg);
|
|
be_return(vm); // Return
|
|
}
|
|
be_return_nil(vm); // Return nil when something goes wrong
|
|
}
|
|
|
|
// Berry: `getFreeHeap() -> int`
|
|
// ESP object
|
|
int32_t l_getFreeHeap(bvm *vm);
|
|
int32_t l_getFreeHeap(bvm *vm) {
|
|
be_pushint(vm, ESP.getFreeHeap());
|
|
be_return(vm);
|
|
}
|
|
|
|
// Berry: `save(file:string, f:closure) -> bool`
|
|
int32_t l_save(struct bvm *vm);
|
|
int32_t l_save(struct bvm *vm) {
|
|
int32_t top = be_top(vm); // Get the number of arguments
|
|
if (top == 2 && be_isstring(vm, 1) && be_isclosure(vm, 2)) { // only 1 argument of type string accepted
|
|
const char *fname = be_tostring(vm, 1);
|
|
int32_t ret = be_savecode(vm, fname);
|
|
be_pushint(vm, ret);
|
|
be_return(vm); // Return
|
|
}
|
|
be_raise(vm, kTypeError, nullptr);
|
|
}
|
|
}
|
|
|
|
// called as a replacement to Berry `print()`
|
|
void berry_log(const char * berry_buf);
|
|
void berry_log(const char * berry_buf) {
|
|
if (berry.repl_active) {
|
|
if (berry.log.log.length() >= BERRY_MAX_LOGS) {
|
|
berry.log.log.remove(berry.log.log.head());
|
|
}
|
|
}
|
|
// AddLog(LOG_LEVEL_INFO, PSTR("[Add to log] %s"), berry_buf);
|
|
berry.log.addString(berry_buf, nullptr, "\n");
|
|
AddLog(LOG_LEVEL_INFO, PSTR("%s"), berry_buf);
|
|
}
|
|
|
|
|
|
#endif // USE_BERRY
|