[update] new rp2 blocks

This commit is contained in:
ocogeclub 2023-06-25 21:18:33 +09:00
parent f47fc30e93
commit a97a207d55
15 changed files with 1405 additions and 915 deletions

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@ -10,7 +10,7 @@ const ugj_const = {
library_dirname: 'lib', library_dirname: 'lib',
document_root: 'Documents', document_root: 'Documents',
tmp_dir: '.ocogeclub/tmp', //ホームディレクトリからのパス tmp_dir: '.ocogeclub/tmp', //ホームディレクトリからのパス
executable_path: '.ocogeclub/apps/', //ホームディレクトリからのパス executable_path: 'ocogeclub/bin/', //ホームディレクトリからのパス
localStorage_fname: 'ocoge.json', localStorage_fname: 'ocoge.json',
error_ja_all: 'エラーが発生しました。\n『おこげ倶楽部』までお問い合わせください。', error_ja_all: 'エラーが発生しました。\n『おこげ倶楽部』までお問い合わせください。',
pig: 'pigpio', pig: 'pigpio',
@ -315,7 +315,7 @@ class appTool {
class webTool { class webTool {
constructor() { constructor() {
// GPIOブロックは使えません // GPIOブロックは使えません
this.gpio_lib = ugj_const.pig; this.gpio_lib = ugj_const.rg;
this.lang = 'js'; this.lang = 'js';
this.blocks_dir = ugj_const.blocks_dir; this.blocks_dir = ugj_const.blocks_dir;
} }

File diff suppressed because it is too large Load Diff

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@ -29,7 +29,7 @@ registerCategory('sensors', [ // カテゴリディレクトリ名
"amg8833", "amg8833",
"paj7620", "paj7620",
"bme280", "bme280",
"dht11", // "dht11",
"pico_slave", // "pico_slave",
"z-line" // フライアウト下端の不可視ライン。スクリプトにカテゴリ名を含むので注意 "z-line" // フライアウト下端の不可視ライン。スクリプトにカテゴリ名を含むので注意
]); ]);

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@ -12,10 +12,10 @@ exports.init = async (i2c_bus, i2c_addr, wael = null) => {
}); });
} }
if (pi >= 0) { throw new Error(err_msg); return; } if (pi >= 0) { throw new Error(err_msg); return; }
pi = await pig._gpiod_start('', ''); pi = await pig._rgpiod_start('', '');
console.log('pi=' + pi); console.log('pi=' + pi);
if (i2c_hand >= 0) { throw new Error(err_msg); return; } if (i2c_hand >= 0) { throw new Error(err_msg); return; }
i2c_hand = await pig._i2c_open(pi, i2c_bus, i2c_addr); i2c_hand = await pig._i2c_open(pi, i2c_bus, i2c_addr, 0);
console.log('i2c_hand=' + i2c_hand); console.log('i2c_hand=' + i2c_hand);
await pig._i2c_write_byte_data(pi, i2c_hand, 0x00, 0x00); //Normal mode await pig._i2c_write_byte_data(pi, i2c_hand, 0x00, 0x00); //Normal mode
await pig._i2c_write_byte_data(pi, i2c_hand, 0x02, 0x00); //10FPS await pig._i2c_write_byte_data(pi, i2c_hand, 0x02, 0x00); //10FPS
@ -45,7 +45,7 @@ exports.stop = async () => {
i2c_hand = -1; i2c_hand = -1;
} }
if (pi >= 0) { if (pi >= 0) {
await pig._gpiod_stop(pi); await pig._rgpiod_stop(pi);
pi = -1; pi = -1;
} }
} }

View File

@ -43,11 +43,11 @@ this.REGISTER_HUMIDITY_DATA = 0xFD;
exports.init = async (options) => { exports.init = async (options) => {
this.pig = require(`${apptool.gpio_lib}`); this.pig = require(`${apptool.gpio_lib}`);
this.pi = await this.pig._gpiod_start('', ''); this.pi = await this.pig._rgpiod_start('', '');
this.i2cBusNo = (options && options.hasOwnProperty('i2cBusNo')) ? options.i2cBusNo : 1; this.i2cBusNo = (options && options.hasOwnProperty('i2cBusNo')) ? options.i2cBusNo : 1;
this.i2cAddress = (options && options.hasOwnProperty('i2cAddress')) ? options.i2cAddress : this.BME280_DEFAULT_I2C_ADDRESS(); this.i2cAddress = (options && options.hasOwnProperty('i2cAddress')) ? options.i2cAddress : this.BME280_DEFAULT_I2C_ADDRESS();
this.i2cHand = await this.pig._i2c_open(this.pi, this.i2cBusNo, this.i2cAddress); this.i2cHand = await this.pig._i2c_open(this.pi, this.i2cBusNo, this.i2cAddress, 0);
let r; let r;
r = await this.pig._i2c_write_byte_data(this.pi, this.i2cHand, this.REGISTER_CHIPID, 0); r = await this.pig._i2c_write_byte_data(this.pi, this.i2cHand, this.REGISTER_CHIPID, 0);
@ -96,7 +96,7 @@ exports.cancel = async () => {
if (this.i2cHand >= 0) { if (this.i2cHand >= 0) {
await this.pig._i2c_close(this.pi, this.i2cHand); await this.pig._i2c_close(this.pi, this.i2cHand);
this.i2cHand = null; this.i2cHand = null;
await this.pig._gpiod_stop(this.pi); await this.pig._rgpiod_stop(this.pi);
this.pi = null; this.pi = null;
} }
} }

View File

@ -312,8 +312,8 @@ const initRegisterArray = [
const debug = 1; const debug = 1;
const err_msg = 'PAJ7620 is already opened. Please close old connection to use new one.'; const err_msg = 'PAJ7620 is already opened. Please close old connection to use new one.';
let pig = -1; let rg = -1;
let pi = -1; let sbc = -1;
let i2c_hand = -1; let i2c_hand = -1;
//Initialize the sensors //Initialize the sensors
exports.init = async (i2c_bus, i2c_addr, wael = null) => { exports.init = async (i2c_bus, i2c_addr, wael = null) => {
@ -322,13 +322,13 @@ exports.init = async (i2c_bus, i2c_addr, wael = null) => {
await exports.stop(); await exports.stop();
}); });
} }
pig = require(`${apptool.gpio_lib}`); rg = require(`rgpio`);//${apptool.gpio_lib}
if (pi >= 0) { throw new Error(err_msg); return; } if (sbc >= 0) { throw new Error(err_msg); return; }
pi = await pig._gpiod_start('', ''); sbc = await rg._rgpiod_start('', '');
if (i2c_hand >= 0) { throw new Error(err_msg); return; } if (i2c_hand >= 0) { throw new Error(err_msg); return; }
i2c_hand = await pig._i2c_open(pi, i2c_bus, i2c_addr); i2c_hand = await rg._i2c_open(sbc, i2c_bus, i2c_addr, 0);
if (debug) if (debug)
console.log("pi=" + pi + ", i2c_hand=" + i2c_hand); console.log("sbc=" + sbc + ", i2c_hand=" + i2c_hand);
await sleep(.001); await sleep(.001);
await paj7620SelectBank(BANK0); await paj7620SelectBank(BANK0);
@ -355,7 +355,7 @@ exports.init = async (i2c_bus, i2c_addr, wael = null) => {
// Write a byte to a register on the Gesture sensor // Write a byte to a register on the Gesture sensor
const paj7620WriteReg = async (addr, cmd) => const paj7620WriteReg = async (addr, cmd) =>
await pig._i2c_write_word_data(pi, i2c_hand, addr, cmd); await rg._i2c_write_word_data(sbc, i2c_hand, addr, cmd);
//Select a register bank on the Gesture Sensor //Select a register bank on the Gesture Sensor
const paj7620SelectBank = async bank => { const paj7620SelectBank = async bank => {
@ -365,7 +365,7 @@ const paj7620SelectBank = async bank => {
//Read a block of bytes of length "qty" starting at address "addr" from the Gesture sensor //Read a block of bytes of length "qty" starting at address "addr" from the Gesture sensor
const paj7620ReadReg = async (addr, qty) => { const paj7620ReadReg = async (addr, qty) => {
return await pig._i2c_read_i2c_block_data(pi, i2c_hand, addr, qty); return await rg._i2c_read_i2c_block_data(sbc, i2c_hand, addr, qty);
} }
//Return a vlaue from the gestire sensor which can be used in a program //Return a vlaue from the gestire sensor which can be used in a program
@ -457,12 +457,12 @@ exports.return_gesture = async () => {
exports.stop = async () => { exports.stop = async () => {
if (i2c_hand >= 0) { if (i2c_hand >= 0) {
await pig._i2c_close(pi, i2c_hand); await rg._i2c_close(sbc, i2c_hand);
i2c_hand = -1; i2c_hand = -1;
} }
if (pi >= 0) { if (sbc >= 0) {
await pig._gpiod_stop(pi); await rg._rgpiod_stop(sbc);
pi = -1; sbc = -1;
} }
} }

View File

@ -111,7 +111,7 @@
<field name="MODE">WHILE</field> <field name="MODE">WHILE</field>
</block> </block>
<block type="controls_for"> <block type="controls_for">
<field name="VAR" id="oFFZ#D{*XbIVL=!W~X]w">番号</field> <field name="VAR" iid="oFFZ#D{*XbIVL=!W~X]w">番号</field>
<value name="FROM"> <value name="FROM">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">1</field> <field name="NUM">1</field>
@ -129,7 +129,7 @@
</value> </value>
</block> </block>
<block type="controls_forEach"> <block type="controls_forEach">
<field name="VAR" id="k4+0elF%?J]_)8fo((-m">項目</field> <field name="VAR" iid="k4+0elF%?J]_)8fo((-m">項目</field>
</block> </block>
<block type="controls_flow_statements"> <block type="controls_flow_statements">
<field name="FLOW">BREAK</field> <field name="FLOW">BREAK</field>
@ -214,8 +214,15 @@
</shadow> </shadow>
</value> </value>
</block> </block>
<block type="oc_text_to_number">
<value name="text">
<shadow type="text">
<field name="TEXT">0</field>
</shadow>
</value>
</block>
</category> </category>
<category name="文字列" css-icon="customIcon fas fa-font" categorystyle="text_category"> <category name="テキスト" css-icon="customIcon fas fa-font" categorystyle="text_category">
<block type="text"> <block type="text">
<field name="TEXT"></field> <field name="TEXT"></field>
</block> </block>
@ -287,7 +294,7 @@
<field name="END">FIRST</field> <field name="END">FIRST</field>
<value name="VALUE"> <value name="VALUE">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="3kh{pye%.qbQf]}y64q6" variabletype="">list</field> <field name="VAR" iid="3kh{pye%.qbQf]}y64q6" variabletype="">list</field>
</block> </block>
</value> </value>
</block> </block>
@ -297,7 +304,7 @@
<field name="WHERE">FROM_START</field> <field name="WHERE">FROM_START</field>
<value name="VALUE"> <value name="VALUE">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="3kh{pye%.qbQf]}y64q6" variabletype="">list</field> <field name="VAR" iid="3kh{pye%.qbQf]}y64q6" variabletype="">list</field>
</block> </block>
</value> </value>
</block> </block>
@ -307,7 +314,7 @@
<field name="WHERE">FROM_START</field> <field name="WHERE">FROM_START</field>
<value name="LIST"> <value name="LIST">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="3kh{pye%.qbQf]}y64q6" variabletype="">list</field> <field name="VAR" iid="3kh{pye%.qbQf]}y64q6" variabletype="">list</field>
</block> </block>
</value> </value>
</block> </block>
@ -334,8 +341,8 @@
<label text="基本"></label> <label text="基本"></label>
<block type="ugj_gpio_open"></block> <block type="ugj_gpio_open"></block>
<block type="ugj_gpio_close"></block> <block type="ugj_gpio_close"></block>
<block type="ugj_gpio_set_output"> <block type="oc_gpio_set_output">
<value name="gpio"> <value name="ugpio">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">5</field> <field name="NUM">5</field>
</shadow> </shadow>
@ -349,9 +356,9 @@
</value> </value>
<field name="level">1</field> <field name="level">1</field>
</block> </block>
<block type="ugj_gpio_set_input"> <block type="oc_gpio_set_input">
<field name="lflag">PULL_DOWN</field> <field name="lflag">SET_PULL_NONE</field>
<value name="gpio"> <value name="ugpio">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">6</field> <field name="NUM">6</field>
</shadow> </shadow>
@ -364,41 +371,21 @@
</shadow> </shadow>
</value> </value>
</block> </block>
<label text="パルス" web-line="4.0" web-line-width="200"></label>
<block type="ugj_pwm">
<value name="gpio">
<shadow type="math_number">
<field name="NUM">29</field>
</shadow>
</value>
<value name="pwm_frequency">
<shadow type="math_number">
<field name="NUM">50</field>
</shadow>
</value>
</block>
<block type="oc_pwm_duty">
<value name="gpio">
<shadow type="math_number">
<field name="NUM">29</field>
</shadow>
</value>
<value name="duty">
<shadow type="math_number">
<field name="NUM">0</field>
</shadow>
</value>
</block>
<label text="I2C" web-line="4.0" web-line-width="200"></label> <label text="I2C" web-line="4.0" web-line-width="200"></label>
<block type="ugj_i2c_open"> <block type="oc_i2c_open">
<value name="i2c_address"> <field name="i2c_hand">I2Cデバイス</field>
<value name="addr">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">0</field> <field name="NUM">0</field>
</shadow> </shadow>
</value> </value>
</block> </block>
<block type="ugj_i2c_close"></block> <block type="oc_i2c_close">
<field name="i2c_hand">I2Cデバイス</field>
</block>
<!-- <block type="ugj_i2c_close"></block> -->
<block type="oc_i2c_write_byte"> <block type="oc_i2c_write_byte">
<field name="i2c_hand">I2Cデバイス</field>
<value name="byte_val"> <value name="byte_val">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">0</field> <field name="NUM">0</field>
@ -418,6 +405,7 @@
</value> </value>
</block> </block>
<block type="ugj_i2c_read_byte_data"> <block type="ugj_i2c_read_byte_data">
<field name="i2c_hand">I2Cデバイス</field>
<value name="reg"> <value name="reg">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">0</field> <field name="NUM">0</field>
@ -425,6 +413,7 @@
</value> </value>
</block> </block>
<block type="ugj_i2c_read_word_data"> <block type="ugj_i2c_read_word_data">
<field name="i2c_hand">I2Cデバイス</field>
<value name="reg"> <value name="reg">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">0</field> <field name="NUM">0</field>
@ -432,6 +421,7 @@
</value> </value>
</block> </block>
<block type="ugj_i2c_write_i2c_block_data"> <block type="ugj_i2c_write_i2c_block_data">
<field name="i2c_hand">I2Cデバイス</field>
<value name="reg"> <value name="reg">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">0</field> <field name="NUM">0</field>
@ -444,6 +434,7 @@
</value> </value>
</block> </block>
<block type="ugj_i2c_read_device"> <block type="ugj_i2c_read_device">
<field name="i2c_hand">I2Cデバイス</field>
<value name="count"> <value name="count">
<shadow type="math_number"> <shadow type="math_number">
<field name="NUM">1</field> <field name="NUM">1</field>
@ -451,6 +442,7 @@
</value> </value>
</block> </block>
<block type="ugj_i2c_write_device"> <block type="ugj_i2c_write_device">
<field name="i2c_hand">I2Cデバイス</field>
<value name="data"> <value name="data">
<shadow type="text_join"> <shadow type="text_join">
<mutation items="2"></mutation> <mutation items="2"></mutation>
@ -466,7 +458,35 @@
</value> </value>
</block> </block>
<label text="シリアル" web-line="4.0" web-line-width="200"></label> <label text="シリアル" web-line="4.0" web-line-width="200"></label>
<block type="ugj_serial_open"> <block type="oc_serial_open">
<field name="ser_hand">シリアルデバイス</field>
<field name="baud">9600</field>
<value name="port">
<shadow type="text">
<field name="TEXT">/dev/ttyACM0</field>
</shadow>
</value>
</block>
<block type="oc_serial_close">
<field name="ser_hand">シリアルデバイス</field>
</block>
<block type="oc_serial_read">
<field name="ser_hand">シリアルデバイス</field>
<value name="count">
<shadow type="math_number">
<field name="NUM">0</field>
</shadow>
</value>
</block>
<block type="oc_serial_write">
<field name="ser_hand">シリアルデバイス</field>
<value name="data">
<shadow type="text">
<field name="TEXT">hello</field>
</shadow>
</value>
</block>
<!-- <block type="ugj_serial_open">
<field name="baud">9600</field> <field name="baud">9600</field>
</block> </block>
<block type="ugj_serial_close"></block> <block type="ugj_serial_close"></block>
@ -491,7 +511,7 @@
</value> </value>
</shadow> </shadow>
</value> </value>
</block> </block> -->
<label text="Extra" web-line="4.0" web-line-width="200"></label> <label text="Extra" web-line="4.0" web-line-width="200"></label>
<label text="_" web-line="4.0" web-line-width="200"></label> <label text="_" web-line="4.0" web-line-width="200"></label>
</category> </category>
@ -613,7 +633,7 @@
<field name="updown">keydown</field> <field name="updown">keydown</field>
<value name="key"> <value name="key">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="Tf-2_OhUEAcOe;U}wu%I">キー</field> <field name="VAR" iid="Tf-2_OhUEAcOe;U}wu%I">キー</field>
</block> </block>
</value> </value>
</block> </block>
@ -623,7 +643,7 @@
<block type="ugj_face_detect"> <block type="ugj_face_detect">
<value name="preditions"> <value name="preditions">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="TLZRpW`yXuYE3Z31)B=2">検出結果</field> <field name="VAR" iid="TLZRpW`yXuYE3Z31)B=2">検出結果</field>
</block> </block>
</value> </value>
</block> </block>
@ -636,7 +656,7 @@
<field name="WHERE">FROM_START</field> <field name="WHERE">FROM_START</field>
<value name="VALUE"> <value name="VALUE">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="_W]y2e!_~suF]yM;LQ1~">検出結果</field> <field name="VAR" iid="_W]y2e!_~suF]yM;LQ1~">検出結果</field>
</block> </block>
</value> </value>
<value name="AT"> <value name="AT">
@ -656,7 +676,7 @@
<field name="WHERE">FROM_START</field> <field name="WHERE">FROM_START</field>
<value name="VALUE"> <value name="VALUE">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="E-Bsl~,RZG]E)v`k![_p">検出結果</field> <field name="VAR" iid="E-Bsl~,RZG]E)v`k![_p">検出結果</field>
</block> </block>
</value> </value>
<value name="AT"> <value name="AT">
@ -676,7 +696,7 @@
</value> </value>
</block> --> </block> -->
<block type="oc_speechcommands_init"> <block type="oc_speechcommands_init">
<field name="classlabels" id="aV;:;wdjQ;:3+(Bx8Z!$">ラベル</field> <field name="classlabels" iid="aV;:;wdjQ;:3+(Bx8Z!$">ラベル</field>
<value name="custom_model"> <value name="custom_model">
<shadow type="text"> <shadow type="text">
<field name="TEXT"></field> <field name="TEXT"></field>
@ -684,11 +704,11 @@
</value> </value>
</block> </block>
<!-- <block type="oc_speechcommand_listen"> <!-- <block type="oc_speechcommand_listen">
<field name="classlabels" id="-aysulrCq~BT0?GQL|V:">ラベル</field> <field name="classlabels" iid="-aysulrCq~BT0?GQL|V:">ラベル</field>
<field name="scores" id="#?-HvxDFqQ#vb+swl_k:">スコア</field> <field name="scores" iid="#?-HvxDFqQ#vb+swl_k:">スコア</field>
</block> --> </block> -->
<block type="oc_speechcommand_listen"> <block type="oc_speechcommand_listen">
<field name="scores" id="|!AWY]V:il;fu;lRwDC*">スコア</field> <field name="scores" iid="|!AWY]V:il;fu;lRwDC*">スコア</field>
</block> </block>
<label text="_" web-line="4.0" web-line-width="200"></label> <label text="_" web-line="4.0" web-line-width="200"></label>
</category> </category>
@ -723,7 +743,7 @@
<block type="ugj_network_httpserver"> <block type="ugj_network_httpserver">
<value name="url"> <value name="url">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="b`}7sB~6O9+IKJ!vJzA`">URL</field> <field name="VAR" iid="b`}7sB~6O9+IKJ!vJzA`">URL</field>
</block> </block>
</value> </value>
<value name="response"> <value name="response">
@ -743,7 +763,7 @@
<block type="ugj_skyway_newpeer"> <block type="ugj_skyway_newpeer">
<value name="my_id"> <value name="my_id">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="P$},PvZ}j#)8lw++|u7h">自分のID</field> <field name="VAR" iid="P$},PvZ}j#)8lw++|u7h">自分のID</field>
</block> </block>
</value> </value>
<value name="apikey"> <value name="apikey">
@ -756,7 +776,7 @@
<block type="ugj_skyway_events"> <block type="ugj_skyway_events">
<value name="remote_id"> <value name="remote_id">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="lN*;t*HFF;@[)a_m3#F8">相手のID</field> <field name="VAR" iid="lN*;t*HFF;@[)a_m3#F8">相手のID</field>
</block> </block>
</value> </value>
</block> </block>
@ -764,14 +784,14 @@
<block type="ugj_skyway_eventdata"> <block type="ugj_skyway_eventdata">
<value name="data"> <value name="data">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="l[-u+nGf?P~Zu?k(bgP)">発言</field> <field name="VAR" iid="l[-u+nGf?P~Zu?k(bgP)">発言</field>
</block> </block>
</value> </value>
</block> </block>
<block type="ugj_skyway_eventsend"> <block type="ugj_skyway_eventsend">
<value name="data"> <value name="data">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="NbC3[s+Uilk#moos+bn8">内容</field> <field name="VAR" iid="NbC3[s+Uilk#moos+bn8">内容</field>
</block> </block>
</value> </value>
</block> </block>
@ -804,7 +824,7 @@
</value> </value>
<value name="answer"> <value name="answer">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id=":w)sl|yxx4k^W-~-VM#,">答え</field> <field name="VAR" iid=":w)sl|yxx4k^W-~-VM#,">答え</field>
</block> </block>
</value> </value>
</block> </block>
@ -877,14 +897,14 @@
<block type="ugj_spawnsync"> <block type="ugj_spawnsync">
<value name="data"> <value name="data">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id="9z28J37fMu2VaWhbd4*=">実行結果</field> <field name="VAR" iid="9z28J37fMu2VaWhbd4*=">実行結果</field>
</block> </block>
</value> </value>
</block> </block>
<block type="ugj_spawn"> <block type="ugj_spawn">
<value name="data"> <value name="data">
<block type="variables_get"> <block type="variables_get">
<field name="VAR" id=";i*e;NG!%_g}7}wTeaQc">データストリーム</field> <field name="VAR" iid=";i*e;NG!%_g}7}wTeaQc">データストリーム</field>
</block> </block>
</value> </value>
</block> </block>
@ -941,7 +961,7 @@
<block type="ugj_text_cursor"></block> <block type="ugj_text_cursor"></block>
<label text="特殊" web-line="4.0" web-line-width="200"></label> <label text="特殊" web-line="4.0" web-line-width="200"></label>
<block type="ugj_socket"> <block type="ugj_socket">
<field name="data" id="Y^@?sd}wN]H+nmK=[{wL" variabletype="">受信データ</field> <field name="data" iid="Y^@?sd}wN]H+nmK=[{wL" variabletype="">受信データ</field>
<value name="host"> <value name="host">
<shadow type="text"> <shadow type="text">
<field name="TEXT">localhost</field> <field name="TEXT">localhost</field>
@ -971,72 +991,66 @@
<!-- <block type="ugj_dev_run_js"></block> --> <!-- <block type="ugj_dev_run_js"></block> -->
<label text="_" web-line="4.0" web-line-width="200"></label> <label text="_" web-line="4.0" web-line-width="200"></label>
</category> </category>
<category name="スニペット" css-icon="customIcon fas fa-egg" categorystyle="snippets_category"> <category name="RP2 専用" css-icon="customIcon fab fa-python" categorystyle="rp2_category">
<label text="停止ボタンつきループ" web-line="4.0" web-line-width="200"></label> <label text="テキスト" web-line="4.0" web-line-width="200"></label>
<variables> <block type="oc_rp2_print">
<variable id="O-NNhS!sS_oTSB?7JB]$">停止フラグ</variable> <value name="text">
</variables> <shadow type="text">
<block type="variables_set" id="W+CX}t(}EgABVVPGhJ{." x="-250" y="230"> <field name="TEXT"></field>
<field name="VAR" id="O-NNhS!sS_oTSB?7JB]$">停止フラグ</field>
<value name="VALUE">
<block type="logic_boolean" id="3S{lEWhjtB=1Z6E$#vt?">
<field name="BOOL">FALSE</field>
</block>
</value>
<next>
<block type="ugj_control_button" id="#%IHyk19t$l}4$3`z{=x">
<value name="label">
<shadow type="text" id="Gy,;jCb(+@1)7W$*pc9;">
<field name="TEXT">停止</field>
</shadow> </shadow>
</value> </value>
<value name="textcolor"> </block>
<shadow type="colour_picker" id="z$a35:]5)iocrfp6^OsL"> <block type="oc_rp2_input"></block>
<field name="COLOUR">#ffffff</field> <label text="JSON" web-line="4.0" web-line-width="200"></label>
<block type="oc_rp2_ujson_dumps"></block>
<block type="oc_rp2_ujson_loads"></block>
<label text="パルス" web-line="4.0" web-line-width="200"></label>
<block type="ugj_pwm">
<value name="gpio">
<shadow type="math_number">
<field name="NUM">29</field>
</shadow> </shadow>
</value> </value>
<value name="bgcolor"> <value name="pwm_frequency">
<shadow type="colour_picker" id="X)Y}Vo.SaQC2+!_$N:2:"> <shadow type="math_number">
<field name="COLOUR">#ff00ff</field> <field name="NUM">50</field>
</shadow> </shadow>
</value> </value>
<value name="title"> </block>
<shadow type="text" id="]WtKw+8DZm~NnY=j{+8p"> <block type="oc_pwm_duty">
<field name="TEXT">ループを停止します</field> <value name="gpio">
<shadow type="math_number">
<field name="NUM">29</field>
</shadow> </shadow>
</value> </value>
<statement name="do"> <value name="duty">
<block type="variables_set" id="NFM7Mp]ym8)My,+bRgW|"> <shadow type="math_number">
<field name="VAR" id="O-NNhS!sS_oTSB?7JB]$">停止フラグ</field>
<value name="VALUE">
<block type="logic_boolean" id="XE(jO2;SK_c$PtiNgeY[">
<field name="BOOL">TRUE</field>
</block>
</value>
</block>
</statement>
<next>
<block type="controls_whileUntil" id="LMyDUJ02*$bUjwr0c.B]">
<field name="MODE">UNTIL</field>
<value name="BOOL">
<block type="variables_get" id="2Ta/:QEx=nW|A7KOS3{g">
<field name="VAR" id="O-NNhS!sS_oTSB?7JB]$">停止フラグ</field>
</block>
</value>
<statement name="DO">
<block type="ugj_sleep" id="_C=mtOy|HJCo9#m;DS]e">
<value name="sec">
<shadow type="math_number" id="wG#wMyoc]}%!`N~(GH^=">
<field name="NUM">0</field> <field name="NUM">0</field>
</shadow> </shadow>
</value> </value>
</block> </block>
</statement> <block type="oc_rp2_ir_rx">
<value name="gpio">
<shadow type="math_number">
<field name="NUM">26</field>
</shadow>
</value>
</block> </block>
</next> <block type="oc_rp2_ir_record">
<value name="timeout">
<shadow type="math_number">
<field name="NUM">3</field>
</shadow>
</value>
</block> </block>
</next> <block type="oc_rp2_ir_tx">
<value name="gpio">
<shadow type="math_number">
<field name="NUM">27</field>
</shadow>
</value>
</block> </block>
<block type="oc_rp2_ir_transmit"></block>
</category> </category>
</xml> </xml>

View File

@ -15,7 +15,7 @@ var sonsor_color = '20';
var multimedia_color = '240'; var multimedia_color = '240';
var network_color = '340'; var network_color = '340';
var special_color = '40'; var special_color = '40';
var snippets_color = '180'; var rp2_color = '180';
// テーマ // テーマ
var theme = Blockly.Theme.defineTheme('ocoge', { var theme = Blockly.Theme.defineTheme('ocoge', {
'base': Blockly.Themes.Classic, 'base': Blockly.Themes.Classic,
@ -45,8 +45,8 @@ var theme = Blockly.Theme.defineTheme('ocoge', {
'special_blocks': { 'special_blocks': {
"colourPrimary": special_color "colourPrimary": special_color
}, },
'snippets_blocks': { 'rp2_blocks': {
"colourPrimary": snippets_color "colourPrimary": rp2_color
} }
}, },
'categoryStyles': { 'categoryStyles': {
@ -65,8 +65,8 @@ var theme = Blockly.Theme.defineTheme('ocoge', {
"special_category": { "special_category": {
"colour": special_color "colour": special_color
}, },
"snippets_category": { "rp2_category": {
"colour": snippets_color "colour": rp2_color
} }
}, },
}); });
@ -96,10 +96,9 @@ Blockly.Msg["UGJ_FOREACH_ITEM"] = "項目";
Blockly.Msg["UGJ_FOREACH_TOOLTIP"] = "リストの各項目について、その項目を変数「項目」としてステートメントを実行します。"; Blockly.Msg["UGJ_FOREACH_TOOLTIP"] = "リストの各項目について、その項目を変数「項目」としてステートメントを実行します。";
Blockly.Msg["GPIO_OPEN_TITLE"] = "GPIO を使えるようにする"; Blockly.Msg["GPIO_OPEN_TITLE"] = "GPIO を使えるようにする";
Blockly.Msg["GPIO_OPEN_TOOLTIP"] = "GPIOを初期化して接続します。"; Blockly.Msg["GPIO_OPEN_TOOLTIP"] = "rgpiod デーモンに接続します。";
Blockly.Msg["GPIO_CLOSE_TITLE"] = "GPIO の後片付けをする";
Blockly.Msg["GPIO_CLOSE_TOOLTIP"] = "GPIOとの接続を終了します。";
Blockly.Msg["GPIO_CLOSE_TITLE"] = "GPIO の後片付けをする"; Blockly.Msg["GPIO_CLOSE_TITLE"] = "GPIO の後片付けをする";
Blockly.Msg["GPIO_CLOSE_TOOLTIP"] = "rgpiod デーモンから切断します。";
Blockly.Msg["GPIO_SET_INPUT_TITLE"] = "GPIO %1 を入力モードにして %2"; Blockly.Msg["GPIO_SET_INPUT_TITLE"] = "GPIO %1 を入力モードにして %2";
Blockly.Msg["GPIO_SET_INPUT_TOOLTIP"] = "GPIO端子を入力モードにして、プルアップ・プルダウン・無しを設定します。"; Blockly.Msg["GPIO_SET_INPUT_TOOLTIP"] = "GPIO端子を入力モードにして、プルアップ・プルダウン・無しを設定します。";
Blockly.Msg["GPIO_SET_INPUT_PULLUP"] = "プルアップ"; Blockly.Msg["GPIO_SET_INPUT_PULLUP"] = "プルアップ";
@ -114,9 +113,7 @@ Blockly.Msg["GPIO_WRITE_TOOLTIP"] = "GPIO端子の値をデジタル値0ま
Blockly.Msg["SERVO_TITLE"] = "GPIO %1 のサーボモータの回転を %2 にする"; Blockly.Msg["SERVO_TITLE"] = "GPIO %1 のサーボモータの回転を %2 にする";
Blockly.Msg["SERVO_TOOLTIP"] = "サーボモータの回転をパルス幅(10002000μsec)までの数値で指定します。"; Blockly.Msg["SERVO_TOOLTIP"] = "サーボモータの回転をパルス幅(10002000μsec)までの数値で指定します。";
Blockly.Msg["PWM_TITLE"] = "GPIO %1 をパルス周波数 %2 Hzの PWM 出力に設定"; Blockly.Msg["PWM_TITLE"] = "GPIO %1 をパルス周波数 %2 Hzの PWM 出力に設定";
Blockly.Msg["PWM_TOOLTIP"] = "パルス周波数をセットして、GPIO端子がPWM出力できるようにします。(MicorPython 専用)"; Blockly.Msg["PWM_TOOLTIP"] = "[RP2] パルス周波数をセットして、GPIO端子がPWM出力できるようにします。";
Blockly.Msg["I2C_OPEN_TITLE"] = "アドレス %1 の I2C デバイスを開く";
Blockly.Msg["I2C_OPEN_TOOLTIP"] = "I2C接続されたデバイスとの通信を開始します。一度にオープンできるI2Cデバイスはひとつだけです。";
Blockly.Msg["SERIAL_OPEN_TITLE"] = "シリアルポートを速度 %1 bpsで開く"; Blockly.Msg["SERIAL_OPEN_TITLE"] = "シリアルポートを速度 %1 bpsで開く";
Blockly.Msg["SERIAL_OPEN_TOOLTIP"] = "シリアルデバイスとの接続を開きます。"; Blockly.Msg["SERIAL_OPEN_TOOLTIP"] = "シリアルデバイスとの接続を開きます。";
Blockly.Msg["SERIAL_CLOSE_TITLE"] = "シリアルポートを閉じる"; Blockly.Msg["SERIAL_CLOSE_TITLE"] = "シリアルポートを閉じる";
@ -125,22 +122,16 @@ Blockly.Msg["SERIAL_WRITE_TITLE"] = "シリアルポートに %1 を送信する
Blockly.Msg["SERIAL_WRITE_TOOLTIP"] = "シリアル接続されたデバイスにデータを送信します。シリアルポートは開かれていなくてはいけません。"; Blockly.Msg["SERIAL_WRITE_TOOLTIP"] = "シリアル接続されたデバイスにデータを送信します。シリアルポートは開かれていなくてはいけません。";
Blockly.Msg["SERIAL_READ_TITLE"] = "シリアルポートから %1 文字読み込む"; Blockly.Msg["SERIAL_READ_TITLE"] = "シリアルポートから %1 文字読み込む";
Blockly.Msg["SERIAL_READ_TOOLTIP"] = "オープン済みシリアルポートから、指定のバイト数だけデータを読み込みます。"; Blockly.Msg["SERIAL_READ_TOOLTIP"] = "オープン済みシリアルポートから、指定のバイト数だけデータを読み込みます。";
Blockly.Msg["I2C_CLOSE_TITLE"] = "I2C デバイスを閉じる";
Blockly.Msg["I2C_CLOSE_TOOLTIP"] = "I2C接続されたデバイスと通信を切断します。";
Blockly.Msg["I2C_WRITE_BYTE_TITLE"] = "デバイスに1バイトデータ %1 を送信"; Blockly.Msg["I2C_WRITE_BYTE_TITLE"] = "デバイスに1バイトデータ %1 を送信";
Blockly.Msg["I2C_WRITE_BYTE_TOOLTIP"] = "i2cデバイスにバイトデータを送信します。0-0xFFの範囲の数字で入力してください。"; Blockly.Msg["I2C_WRITE_BYTE_TOOLTIP"] = "i2cデバイスにバイトデータを送信します。0-0xFFの範囲の数字で入力してください。";
Blockly.Msg["I2C_READ_BYTE_TITLE"] = "I2C デバイスから 1 バイト受け取る"; Blockly.Msg["I2C_READ_BYTE_TITLE"] = "I2C デバイスから 1 バイト受け取る";
Blockly.Msg["I2C_READ_BYTE_TOOLTIP"] = "オープン済み I2C デバイスからデータを 1 バイト受け取ります。"; Blockly.Msg["I2C_READ_BYTE_TOOLTIP"] = "オープン済み I2C デバイスからデータを 1 バイト受け取ります。";
Blockly.Msg["I2C_WRITE_BYTE_DATA_TITLE"] = "レジスタ %1 に %2 を書き込む"; Blockly.Msg["I2C_WRITE_I2C_BLOCK_DATA_TITLE"] = "";
Blockly.Msg["I2C_WRITE_BYTE_DATA_TOOLTIP"] = "デバイスの指定されたレジスタに1バイトを書き込みます。"; Blockly.Msg["I2C_WRITE_I2C_BLOCK_DATA_TOOLTIP"] = "";
Blockly.Msg["I2C_READ_BYTE_DATA_TITLE"] = "レジスタ %1 の値"; Blockly.Msg["I2C_READ_DEVICE_TITLE"] = "";
Blockly.Msg["I2C_READ_BYTE_DATA_TOOLTIP"] = "デバイスの指定されたレジスタから1バイトを読み込みます。"; Blockly.Msg["I2C_READ_DEVICE_TOOLTIP"] = "";
Blockly.Msg["I2C_WRITE_I2C_BLOCK_DATA_TITLE"] = "レジスタ %1 に %2 を書き込む"; Blockly.Msg["I2C_WRITE_DEVICE_TITLE"] = "";
Blockly.Msg["I2C_WRITE_I2C_BLOCK_DATA_TOOLTIP"] = "デバイスの指定されたレジスタに最大32バイトのテキストデータを書き込みます。"; Blockly.Msg["I2C_WRITE_DEVICE_TOOLTIP"] = "";
Blockly.Msg["I2C_READ_DEVICE_TITLE"] = "i2cデバイスから %1 バイト受け取る";
Blockly.Msg["I2C_READ_DEVICE_TOOLTIP"] = "デバイスから指定したバイト数のデータを受け取ります。データが指定の長さより短いこともあります。";
Blockly.Msg["I2C_WRITE_DEVICE_TITLE"] = "i2c デバイスに %1 を送信";
Blockly.Msg["I2C_WRITE_DEVICE_TOOLTIP"] = "i2c デバイスにデータを送信します。";
Blockly.Msg["UGJ_CODECHAR_TITLE"] = "コード %1 の文字"; Blockly.Msg["UGJ_CODECHAR_TITLE"] = "コード %1 の文字";
Blockly.Msg["UGJ_CODECHAR_TOOLTIP"] = "文字コードを文字に変換します。"; Blockly.Msg["UGJ_CODECHAR_TOOLTIP"] = "文字コードを文字に変換します。";

View File

@ -1,107 +1,115 @@
module.exports = require('bindings')('rgpio'); module.exports = require('bindings')('rgpio');
// module.exports.SET_ACTIVE_LOW = 4; module.exports.SET_ACTIVE_LOW = 4;
// module.exports.SET_OPEN_DRAIN = 8; module.exports.SET_OPEN_DRAIN = 8;
// module.exports.SET_OPEN_SOURCE = 16; module.exports.SET_OPEN_SOURCE = 16;
// module.exports.SET_PULL_UP = 32; module.exports.SET_PULL_UP = 32;
// module.exports.SET_PULL_DOWN = 64; module.exports.SET_PULL_DOWN = 64;
// module.exports.SET_PULL_NONE = 128; module.exports.SET_PULL_NONE = 128;
module.exports.PULL_UP = 32;
module.exports.PULL_DOWN = 64;
module.exports.PULL_NONE = 128;
const CHIP_COUNT = 5;
const port = '';
// Properties
let sbc = -1; let sbc = -1;
let gpiochip_hand = []; let chip_hand = [];
let ser_hand = -1;
let i2c_hand = -1; module.exports.rgpio_sbc = async (host = 'localhost', port = 8889, show_errors = true) => {
module.exports.gpio_open = async () => { if (sbc < 0) {
sbc = await module.exports._gpiod_start('', ''); sbc = await module.exports._rgpiod_start(host, port.toString());
if (sbc < 0) return sbc; if (sbc < 0) {
for (let i = 0; i < CHIP_COUNT; i++) { if (show_errors) console.log(sbc);
gpiochip_hand.push(await module.exports._gpiochip_open(sbc, i));
} }
return gpiochip_hand;
} }
module.exports.gpio_close = async () => { return sbc;
if (sbc >= 0) {
for (let i = 0; i < CHIP_COUNT; i++) {
if (gpiochip_hand[i] >= 0)
await module.exports._gpiochip_close(sbc, gpiochip_hand[i]);
} }
gpiochip_hand = []; module.exports.sbc_stop = async () => {
await module.exports._gpiod_stop(sbc); await module.exports._rgpiod_stop(sbc);
chip_hand = [];
sbc = -1; sbc = -1;
} }
module.exports.gpiochip_open = async gpiochip => {
if (!chip_hand[gpiochip] || chip_hand[gpiochip] < 0) {
chip_hand[gpiochip] = await module.exports._gpiochip_open(sbc, gpiochip);
} }
module.exports.gpio_set_output = async gpio => { return chip_hand[gpiochip];
let chip = Math.floor(gpio / 32); // return await module.exports._gpiochip_open(sbc, gpiochip);
let pin = Math.floor(gpio % 32);
if (gpiochip_hand[chip] >= 0) return await module.exports._gpio_claim_output(sbc, gpiochip_hand[chip], pin);
} }
module.exports.gpio_write = async (gpio, value) => { module.exports.gpio_set_input = async (ugpio, lFlags = 0) => {
let chip = Math.floor(gpio / 32); let chip = Math.trunc(ugpio / 32);
let pin = Math.floor(gpio % 32); let gpio = ugpio % 32;
if (gpiochip_hand[chip] >= 0) return await module.exports._gpio_write(sbc, gpiochip_hand[chip], pin, value); let handle = await module.exports.gpiochip_open(chip);
return await module.exports._gpio_claim_input(sbc, handle, lFlags, gpio);
} }
module.exports.serial_open = async (tty, baud) => { module.exports.gpio_set_output = async (ugpio, level = 0, lFlags = 0) => {
if (ser_hand >= 0) await module.exports._serial_close(sbc, ser_hand); // 勝手に閉じる let chip = Math.trunc(ugpio / 32);
ser_hand = await module.exports._serial_open(sbc, tty, baud); let gpio = ugpio % 32;
return ser_hand; let handle = await module.exports.gpiochip_open(chip);
return await module.exports._gpio_claim_output(sbc, handle, lFlags, gpio, level);
} }
module.exports.serial_close = async () => { module.exports.gpio_read = async (ugpio) => {
if (ser_hand >= 0) await module.exports._serial_close(sbc, ser_hand); let chip = Math.trunc(ugpio / 32);
ser_hand = -1; let gpio = ugpio % 32;
let handle = await module.exports.gpiochip_open(chip);
return await module.exports._gpio_read(sbc, handle, gpio);
} }
module.exports.serial_write = async data => { module.exports.gpio_write = async (ugpio, level) => {
if (ser_hand >= 0) return await module.exports._serial_write(sbc, ser_hand, Buffer.from(data)); let chip = Math.trunc(ugpio / 32);
let gpio = ugpio % 32;
let handle = await module.exports.gpiochip_open(chip);
return await module.exports._gpio_write(sbc, handle, gpio, level);
} }
module.exports.serial_read = async count => { module.exports.serial_open = async (tty, baud, ser_flags = 0) => {
if (ser_hand >= 0) return new TextDecoder().decode(await module.exports._serial_read(sbc, ser_hand, count)); return await module.exports._serial_open(sbc, tty, baud, ser_flags);
// if (ser_hand >= 0) return await module.exports._serial_read(pi, ser_hand, count);//.toString('utf8');
} }
module.exports.i2c_open = async (i2c_bus, i2c_address) => { module.exports.serial_close = async handle => {
if (i2c_hand >= 0) await module.exports._i2c_close(i2c_hand); // 勝手に閉じる await module.exports._serial_close(sbc, handle);
i2c_hand = await module.exports._i2c_open(sbc, i2c_bus, i2c_address);
return i2c_hand;
} }
module.exports.i2c_close = async () => { module.exports.serial_read = async (handle, count = 0) => {
if (i2c_hand >= 0) await module.exports._i2c_close(sbc, i2c_hand); if (count === 0) {
i2c_hand = -1; count = await module.exports._serial_data_available(sbc, handle);
if (count === 0) return '';
}
return new TextDecoder().decode(await module.exports._serial_read(sbc, handle, count));
}
module.exports.serial_write = async (handle, data) => {
return await module.exports._serial_write(sbc, handle, Buffer.from(data), -1);
}
module.exports.serial_data_available = async handle => {
await module.exports._serial_data_available(sbc, handle);
}
module.exports.i2c_open = async (i2c_bus, i2c_address, i2c_flags = 0) => {
return await module.exports._i2c_open(sbc, i2c_bus, i2c_address, i2c_flags);
}
module.exports.i2c_close = async handle => {
await module.exports._i2c_close(sbc, handle);
} }
module.exports.i2c_write_byte = async (byte_val) => { module.exports.i2c_write_byte = async (handle, byte_val) => {
if (i2c_hand >= 0) return await module.exports._i2c_write_byte(sbc, i2c_hand, byte_val); return await module.exports._i2c_write_byte(sbc, handle, byte_val);
} }
module.exports.i2c_read_byte = async () => { module.exports.i2c_read_byte = async handle => {
if (i2c_hand >= 0) return await module.exports._i2c_read_byte(sbc, i2c_hand); return await module.exports._i2c_read_byte(sbc, handle);
} }
module.exports.i2c_write_byte_data = async (handle, reg, byte_val) => {
return await module.exports._i2c_write_byte_data(sbc, handle, reg, byte_val);
module.exports.i2c_write_byte_data = async (reg, byte_val) => {
if (i2c_hand >= 0) return await module.exports._i2c_write_byte_data(sbc, i2c_hand, reg, byte_val);
} }
module.exports.i2c_read_byte_data = async reg => { module.exports.i2c_read_byte_data = async (handle, reg) => {
if (i2c_hand >= 0) return await module.exports._i2c_read_byte_data(sbc, i2c_hand, reg); return await module.exports._i2c_read_byte_data(sbc, handle, reg);
} }
module.exports.i2c_write_i2c_block_data = async (reg, data) => { module.exports.i2c_write_i2c_block_data = async (handle, reg, data) => {
if (i2c_hand >= 0) return await module.exports._i2c_write_i2c_block_data(sbc, i2c_hand, reg, Buffer.from(data)); return await module.exports._i2c_write_i2c_block_data(sbc, handle, reg, Buffer.from(data), -1);
} }
module.exports.i2c_read_word_data = async reg => { module.exports.i2c_read_word_data = async (handle, reg) => {
if (i2c_hand >= 0) return await module.exports._i2c_read_word_data(sbc, i2c_hand, reg); return await module.exports._i2c_read_word_data(sbc, handle, reg);
} }
module.exports.i2c_read_device = async count => { module.exports.i2c_read_device = async (handle, count) => {
if (i2c_hand >= 0) return new TextDecoder().decode(await module.exports._i2c_read_device(sbc, i2c_hand, count)); return new TextDecoder().decode(await module.exports._i2c_read_device(sbc, handle, count));
} }
module.exports.i2c_write_device = async data => { module.exports.i2c_write_device = async (handle, data) => {
if (i2c_hand >= 0) return await module.exports._i2c_write_device(sbc, i2c_hand, Buffer.from(data)); return await module.exports._i2c_write_device(sbc, handle, Buffer.from(data), -1);
} }
// 終了処理 // 終了処理
module.exports.close_all_handle = async () => { module.exports.close_all_handle = async () => {
await module.exports.gpio_close(); await module.exports.sbc_stop();
await module.exports.serial_close(); // await module.exports.serial_close();
await module.exports.i2c_close(); // await module.exports.i2c_close();
} }

View File

@ -16,12 +16,12 @@ Promise _rgpiodStart(const CallbackInfo &info)
if (info.Length() != 2) if (info.Length() != 2)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _rgpiodStart").Value());
} }
if (!info[0].IsString() || !info[1].IsString()) if (!info[0].IsString() || !info[1].IsString())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _rgpiodStart").Value());
} }
else else
{ {
@ -39,12 +39,12 @@ Promise _rgpiodStop(const CallbackInfo &info)
if (info.Length() != 1) if (info.Length() != 1)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _rgpiodStop").Value());
} }
if (!info[0].IsNumber()) if (!info[0].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _rgpiodStop").Value());
} }
else else
{ {
@ -63,12 +63,12 @@ Promise _gpiochipOpen(const CallbackInfo &info)
if (info.Length() != 2) if (info.Length() != 2)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _gpiochipOpen").Value());
} }
if (!info[0].IsNumber() || !info[1].IsNumber()) if (!info[0].IsNumber() || !info[1].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _gpiochipOpen").Value());
} }
else else
{ {
@ -87,12 +87,12 @@ Promise _gpiochipClose(const CallbackInfo &info)
if (info.Length() != 2) if (info.Length() != 2)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _gpiochipClose").Value());
} }
if (!info[0].IsNumber() || !info[1].IsNumber()) if (!info[0].IsNumber() || !info[1].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _gpiochipClose").Value());
} }
else else
{ {
@ -105,18 +105,73 @@ Promise _gpiochipClose(const CallbackInfo &info)
// GPIO のモードを出力にする(ことを要求?) // GPIO のモードを出力にする(ことを要求?)
Promise _gpioClaimOutput(const CallbackInfo &info) Promise _gpioClaimOutput(const CallbackInfo &info)
{
Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 5)
{
deferred.Reject(
TypeError::New(env, "Invalid argument count: _gpioClaimOutput").Value());
}
if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber() || !info[4].IsNumber())
{
deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types: _gpioClaimOutput").Value());
}
else
{
int sbc = info[0].As<Number>().Int32Value();
int handle = info[1].As<Number>().Int32Value();
int lFlags = info[2].As<Number>().Int32Value();
int gpio = info[3].As<Number>().Int32Value();
int value = info[4].As<Number>().Int32Value();
deferred.Resolve(Number::New(env, gpio_claim_output(sbc, handle, lFlags, gpio, value)));
}
return deferred.Promise();
}
// GPIO のモードを入力にする(ことを要求?)
Promise _gpioClaimInput(const CallbackInfo &info)
{
Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 4)
{
deferred.Reject(
TypeError::New(env, "Invalid argument count: _gpioClaimInput").Value());
}
if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber())
{
deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types: _gpioClaimInput").Value());
}
else
{
int sbc = info[0].As<Number>().Int32Value();
int handle = info[1].As<Number>().Int32Value();
int lFlags = info[2].As<Number>().Int32Value();
int gpio = info[3].As<Number>().Int32Value();
deferred.Resolve(Number::New(env, gpio_claim_input(sbc, handle, lFlags, gpio)));
}
return deferred.Promise();
}
// GPIOの電圧を読む
Promise _gpioRead(const CallbackInfo &info)
{ {
Env env = info.Env(); Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env); auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 3) if (info.Length() != 3)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _gpioRead").Value());
} }
if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _gpioRead").Value());
} }
else else
{ {
@ -124,14 +179,11 @@ Promise _gpioClaimOutput(const CallbackInfo &info)
int handle = info[1].As<Number>().Int32Value(); int handle = info[1].As<Number>().Int32Value();
int gpio = info[2].As<Number>().Int32Value(); int gpio = info[2].As<Number>().Int32Value();
deferred.Resolve(Number::New(env, gpio_claim_output(sbc, handle, 0, gpio, 0))); deferred.Resolve(Number::New(env, gpio_read(sbc, handle, gpio)));
} }
return deferred.Promise(); return deferred.Promise();
} }
// GPIO のモードを入力にする(ことを要求?)
// GPIOの電圧を読む
// GPIO の電圧をセットする // GPIO の電圧をセットする
Promise _gpioWrite(const CallbackInfo &info) Promise _gpioWrite(const CallbackInfo &info)
{ {
@ -140,12 +192,12 @@ Promise _gpioWrite(const CallbackInfo &info)
if (info.Length() != 4) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _gpioWrite").Value());
} }
if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber()) if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _gpioWrite").Value());
} }
else else
{ {
@ -164,12 +216,12 @@ Promise _serialOpen(const CallbackInfo &info)
{ {
Env env = info.Env(); Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env); auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 3) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count: _serialOpen").Value()); TypeError::New(env, "Invalid argument count: _serialOpen").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsString() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsString() || !info[2].IsNumber() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types: _serialOpen").Value()); Napi::TypeError::New(env, "Invalid argument types: _serialOpen").Value());
@ -179,7 +231,8 @@ Promise _serialOpen(const CallbackInfo &info)
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
std::string ser_tty = info[1].As<String>().Utf8Value(); std::string ser_tty = info[1].As<String>().Utf8Value();
int baud = info[2].As<Number>().Uint32Value(); int baud = info[2].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, serial_open(sbc, (char *)ser_tty.c_str(), baud, 0))); int ser_flags = info[3].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, serial_open(sbc, (char *)ser_tty.c_str(), baud, ser_flags)));
} }
return deferred.Promise(); return deferred.Promise();
} }
@ -192,12 +245,12 @@ Promise _serialClose(const CallbackInfo &info)
if (info.Length() != 2) if (info.Length() != 2)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _serialClose").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _serialClose").Value());
} }
else else
{ {
@ -216,12 +269,12 @@ Promise _serialRead(const CallbackInfo &info)
if (info.Length() != 3) if (info.Length() != 3)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _serialRead").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _serialRead").Value());
} }
else else
{ {
@ -242,49 +295,76 @@ Promise _serialWrite(const CallbackInfo &info)
{ {
Env env = info.Env(); Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env); auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 3) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _serialWrite").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsBuffer()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsBuffer() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _serialWrite").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
auto buf = info[2].As<Buffer<char>>(); auto buf = info[2].As<Buffer<char>>();
int count = info[3].As<Number>().Uint32Value();
int count = buf.Length(); if (count < 0)
count = buf.Length();
deferred.Resolve(Number::New(env, serial_write(sbc, handle, buf.Data(), count))); deferred.Resolve(Number::New(env, serial_write(sbc, handle, buf.Data(), count)));
} }
return deferred.Promise(); return deferred.Promise();
} }
// シリアルデバイスから読み出し可能なバイト数を返す
Promise _serialDataAvailable(const CallbackInfo &info)
{
Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 2)
{
deferred.Reject(
TypeError::New(env, "Invalid argument count: _serialDataAvailable").Value());
}
else if (!info[0].IsNumber() || !info[1].IsNumber())
{
deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types: _serialDataAvailable").Value());
}
else
{
int sbc = info[0].As<Number>().Int32Value();
int handle = info[1].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, serial_data_available(sbc, handle)));
}
return deferred.Promise();
}
// I2Cバスアドレスのデバイスのハンドルを返す // I2Cバスアドレスのデバイスのハンドルを返す
Promise _i2cOpen(const CallbackInfo &info) Promise _i2cOpen(const CallbackInfo &info)
{ {
Env env = info.Env(); Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env); auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 3) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cOpen").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cOpen").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int i2c_bus = info[1].As<Number>().Uint32Value(); int i2c_bus = info[1].As<Number>().Uint32Value();
unsigned int i2c_addr = info[2].As<Number>().Uint32Value(); int i2c_addr = info[2].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_open(sbc, i2c_bus, i2c_addr, 0))); int i2c_flags = info[3].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_open(sbc, i2c_bus, i2c_addr, i2c_flags)));
} }
return deferred.Promise(); return deferred.Promise();
} }
@ -296,17 +376,17 @@ Promise _i2cClose(const CallbackInfo &info)
if (info.Length() != 2) if (info.Length() != 2)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cClose").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cClose").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_close(sbc, handle))); deferred.Resolve(Number::New(env, i2c_close(sbc, handle)));
} }
return deferred.Promise(); return deferred.Promise();
@ -320,18 +400,18 @@ Promise _i2cWriteByte(const CallbackInfo &info)
if (info.Length() != 3) if (info.Length() != 3)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cWriteByte").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cWriteByte").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int bVal = info[2].As<Number>().Uint32Value(); int bVal = info[2].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_write_byte(sbc, handle, bVal))); deferred.Resolve(Number::New(env, i2c_write_byte(sbc, handle, bVal)));
} }
return deferred.Promise(); return deferred.Promise();
@ -344,17 +424,17 @@ Promise _i2cReadByte(const CallbackInfo &info)
if (info.Length() != 2) if (info.Length() != 2)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cReadByte").Value());
} }
else if (!info[0].IsNumber() || !info[0].IsNumber()) else if (!info[0].IsNumber() || !info[0].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cReadByte").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_read_byte(sbc, handle))); deferred.Resolve(Number::New(env, i2c_read_byte(sbc, handle)));
} }
return deferred.Promise(); return deferred.Promise();
@ -368,19 +448,19 @@ Promise _i2cWriteByteData(const CallbackInfo &info)
if (info.Length() != 4) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cWriteByteData").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cWriteByteData").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int i2c_reg = info[2].As<Number>().Uint32Value(); int i2c_reg = info[2].As<Number>().Uint32Value();
unsigned int bVal = info[3].As<Number>().Uint32Value(); int bVal = info[3].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_write_byte_data(sbc, handle, i2c_reg, bVal))); deferred.Resolve(Number::New(env, i2c_write_byte_data(sbc, handle, i2c_reg, bVal)));
} }
return deferred.Promise(); return deferred.Promise();
@ -393,18 +473,18 @@ Promise _i2cReadByteData(const CallbackInfo &info)
if (info.Length() != 3) if (info.Length() != 3)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cReadByteData").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cReadByteData").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int i2c_reg = info[2].As<Number>().Uint32Value(); int i2c_reg = info[2].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_read_byte_data(sbc, handle, i2c_reg))); deferred.Resolve(Number::New(env, i2c_read_byte_data(sbc, handle, i2c_reg)));
} }
return deferred.Promise(); return deferred.Promise();
@ -418,21 +498,21 @@ Promise _i2cReadI2cBlockData(const CallbackInfo &info)
if (info.Length() != 4) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cReadI2cBlockData").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cReadI2cBlockData").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int i2cReg = info[2].As<Number>().Uint32Value(); int i2c_reg = info[2].As<Number>().Uint32Value();
unsigned int count = info[3].As<Number>().Uint32Value(); int count = info[3].As<Number>().Uint32Value();
char buf[count]; char buf[count];
int rxCount = i2c_read_i2c_block_data(sbc, handle, i2cReg, buf, count); int rxCount = i2c_read_i2c_block_data(sbc, handle, i2c_reg, buf, count);
auto outBuf = Buffer<char>::Copy(env, buf, rxCount); auto outBuf = Buffer<char>::Copy(env, buf, rxCount);
deferred.Resolve(outBuf); deferred.Resolve(outBuf);
} }
@ -444,24 +524,26 @@ Promise _i2cWriteI2cBlockData(const CallbackInfo &info)
{ {
Env env = info.Env(); Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env); auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 4) if (info.Length() != 5)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cWriteI2cBlockData").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsBuffer()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsBuffer() || !info[4].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cWriteI2cBlockData").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int i2c_reg = info[2].As<Number>().Uint32Value(); int i2c_reg = info[2].As<Number>().Uint32Value();
auto buf = info[3].As<Buffer<char>>(); auto buf = info[3].As<Buffer<char>>();
int count = info[4].As<Number>().Uint32Value();
unsigned int count = buf.Length(); if (count < 0)
count = buf.Length();
deferred.Resolve(Number::New(env, i2c_write_i2c_block_data(sbc, handle, i2c_reg, buf.Data(), count))); deferred.Resolve(Number::New(env, i2c_write_i2c_block_data(sbc, handle, i2c_reg, buf.Data(), count)));
} }
return deferred.Promise(); return deferred.Promise();
@ -475,18 +557,18 @@ Promise _i2cReadWordData(const CallbackInfo &info)
if (info.Length() != 3) if (info.Length() != 3)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cReadWordData").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cReadWordData").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int i2c_reg = info[2].As<Number>().Uint32Value(); int i2c_reg = info[2].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_read_word_data(sbc, handle, i2c_reg))); deferred.Resolve(Number::New(env, i2c_read_word_data(sbc, handle, i2c_reg)));
} }
return deferred.Promise(); return deferred.Promise();
@ -499,19 +581,19 @@ Promise _i2cWriteWordData(const CallbackInfo &info)
if (info.Length() != 4) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cWriteWordData").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cWriteWordData").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int i2c_reg = info[2].As<Number>().Uint32Value(); int i2c_reg = info[2].As<Number>().Uint32Value();
unsigned int wVal = info[3].As<Number>().Uint32Value(); int wVal = info[3].As<Number>().Uint32Value();
deferred.Resolve(Number::New(env, i2c_write_word_data(sbc, handle, i2c_reg, wVal))); deferred.Resolve(Number::New(env, i2c_write_word_data(sbc, handle, i2c_reg, wVal)));
} }
@ -526,18 +608,18 @@ Promise _i2cReadDevice(const CallbackInfo &info)
if (info.Length() != 3) if (info.Length() != 3)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cReadDevice").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cReadDevice").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
unsigned int count = info[2].As<Number>().Uint32Value(); int count = info[2].As<Number>().Uint32Value();
char buf[count]; char buf[count];
int rxCount = i2c_read_device(sbc, handle, buf, count); int rxCount = i2c_read_device(sbc, handle, buf, count);
@ -552,23 +634,25 @@ Promise _i2cWriteDevice(const CallbackInfo &info)
{ {
Env env = info.Env(); Env env = info.Env();
auto deferred = Napi::Promise::Deferred::New(env); auto deferred = Napi::Promise::Deferred::New(env);
if (info.Length() != 3) if (info.Length() != 4)
{ {
deferred.Reject( deferred.Reject(
TypeError::New(env, "Invalid argument count").Value()); TypeError::New(env, "Invalid argument count: _i2cWriteDevice").Value());
} }
else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsBuffer()) else if (!info[0].IsNumber() || !info[1].IsNumber() || !info[2].IsBuffer() || !info[3].IsNumber())
{ {
deferred.Reject( deferred.Reject(
Napi::TypeError::New(env, "Invalid argument types").Value()); Napi::TypeError::New(env, "Invalid argument types: _i2cWriteDevice").Value());
} }
else else
{ {
int sbc = info[0].As<Number>().Int32Value(); int sbc = info[0].As<Number>().Int32Value();
unsigned int handle = info[1].As<Number>().Uint32Value(); int handle = info[1].As<Number>().Uint32Value();
auto buf = info[2].As<Buffer<char>>(); auto buf = info[2].As<Buffer<char>>();
int count = info[3].As<Number>().Uint32Value();
unsigned int count = buf.Length(); if (count < 0)
int count = buf.Length();
deferred.Resolve(Number::New(env, i2c_write_device(sbc, handle, buf.Data(), count))); deferred.Resolve(Number::New(env, i2c_write_device(sbc, handle, buf.Data(), count)));
} }
return deferred.Promise(); return deferred.Promise();
@ -577,16 +661,19 @@ Promise _i2cWriteDevice(const CallbackInfo &info)
Object Object
Init(Env env, Object exports) Init(Env env, Object exports)
{ {
exports.Set(String::New(env, "_gpiod_start"), Function::New(env, _rgpiodStart)); exports.Set(String::New(env, "_rgpiod_start"), Function::New(env, _rgpiodStart));
exports.Set(String::New(env, "_gpiod_stop"), Function::New(env, _rgpiodStop)); exports.Set(String::New(env, "_rgpiod_stop"), Function::New(env, _rgpiodStop));
exports.Set(String::New(env, "_gpiochip_open"), Function::New(env, _gpiochipOpen)); exports.Set(String::New(env, "_gpiochip_open"), Function::New(env, _gpiochipOpen));
exports.Set(String::New(env, "_gpiochip_close"), Function::New(env, _gpiochipClose)); exports.Set(String::New(env, "_gpiochip_close"), Function::New(env, _gpiochipClose));
exports.Set(String::New(env, "_gpio_claim_input"), Function::New(env, _gpioClaimInput));
exports.Set(String::New(env, "_gpio_claim_output"), Function::New(env, _gpioClaimOutput)); exports.Set(String::New(env, "_gpio_claim_output"), Function::New(env, _gpioClaimOutput));
exports.Set(String::New(env, "_gpio_read"), Function::New(env, _gpioRead));
exports.Set(String::New(env, "_gpio_write"), Function::New(env, _gpioWrite)); exports.Set(String::New(env, "_gpio_write"), Function::New(env, _gpioWrite));
exports.Set(String::New(env, "_serial_open"), Function::New(env, _serialOpen)); exports.Set(String::New(env, "_serial_open"), Function::New(env, _serialOpen));
exports.Set(String::New(env, "_serial_close"), Function::New(env, _serialClose)); exports.Set(String::New(env, "_serial_close"), Function::New(env, _serialClose));
exports.Set(String::New(env, "_serial_read"), Function::New(env, _serialRead)); exports.Set(String::New(env, "_serial_read"), Function::New(env, _serialRead));
exports.Set(String::New(env, "_serial_write"), Function::New(env, _serialWrite)); exports.Set(String::New(env, "_serial_write"), Function::New(env, _serialWrite));
exports.Set(String::New(env, "_serial_data_available"), Function::New(env, _serialDataAvailable));
exports.Set(String::New(env, "_i2c_open"), Function::New(env, _i2cOpen)); exports.Set(String::New(env, "_i2c_open"), Function::New(env, _i2cOpen));
exports.Set(String::New(env, "_i2c_close"), Function::New(env, _i2cClose)); exports.Set(String::New(env, "_i2c_close"), Function::New(env, _i2cClose));
exports.Set(String::New(env, "_i2c_write_byte"), Function::New(env, _i2cWriteByte)); exports.Set(String::New(env, "_i2c_write_byte"), Function::New(env, _i2cWriteByte));

View File

@ -172,7 +172,7 @@ let template = [
} }
}, },
{ {
label: "MicroPython (Test phase)", label: "MicroPython (RP2)",
id: "py", id: "py",
type: 'checkbox', type: 'checkbox',
click: (item, focusedWindow) => { click: (item, focusedWindow) => {

548
package-lock.json generated

File diff suppressed because it is too large Load Diff

View File

@ -22,24 +22,24 @@
}, },
"homepage": "https://git.ocoge.club/ocoge.club/ocoge#readme", "homepage": "https://git.ocoge.club/ocoge.club/ocoge#readme",
"devDependencies": { "devDependencies": {
"@electron-forge/cli": "^6.1.1", "@electron-forge/cli": "^6.2.1",
"@electron-forge/maker-deb": "^6.1.1", "@electron-forge/maker-deb": "^6.2.1",
"@electron/rebuild": "^3.2.13", "@electron/rebuild": "^3.2.13",
"electron": "^24.3.0" "electron": "^25.2.0"
}, },
"dependencies": { "dependencies": {
"@blockly/field-slider": "^4.0.16", "@blockly/field-slider": "^4.0.18",
"@tensorflow-models/blazeface": "^0.0.7", "@tensorflow-models/blazeface": "^0.0.7",
"@tensorflow-models/knn-classifier": "^1.2.4", "@tensorflow-models/knn-classifier": "^1.2.4",
"@tensorflow-models/mobilenet": "^2.1.0", "@tensorflow-models/mobilenet": "^2.1.0",
"@tensorflow-models/speech-commands": "^0.5.4", "@tensorflow-models/speech-commands": "^0.5.4",
"@tensorflow/tfjs-node": "^4.5.0", "@tensorflow/tfjs-node": "^4.8.0",
"axios": "^1.4.0", "axios": "^1.4.0",
"blockly": "^9.3.3", "blockly": "^9.3.3",
"dracula-prism": "^2.1.13", "dracula-prism": "^2.1.13",
"js-beautify": "^1.14.7", "js-beautify": "^1.14.8",
"node-abi": "^3.40.0", "node-abi": "^3.45.0",
"nodemailer": "^6.9.2", "nodemailer": "^6.9.3",
"prismjs": "^1.29.0" "prismjs": "^1.29.0"
}, },
"optionalDependencies": { "optionalDependencies": {