uniapp微信小程序实现连接低功耗蓝牙打印功能
uniapp连接低功耗蓝牙实现打印
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微信小程序项目中有使用到蓝牙连接打印,参考官方文档做了一个参考笔记,这样使用的时候就按着步骤查看。
uni-app蓝牙连接
蓝牙:
1、初始化蓝牙
uni.openBluetoothAdapter(OBJECT)
uni.openBluetoothAdapter({
success(res) {
console.log(res)
// 接口调用成功的回调函数
},
fail:(res)=>{
// 接口调用失败的回调函数
},
complete:()=>{
// 接口调用结束的回调函数(调用成功、失败都会执行)
}
})
错误 :res.errCode
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
注意
- 其他蓝牙相关 API 必须在
uni.openBluetoothAdapter调用之后使用。否则 API 会返回错误(errCode=10000)。 - 在用户蓝牙开关未开启或者手机不支持蓝牙功能的情况下,调用
uni.openBluetoothAdapter会返回错误(errCode=10001),表示手机蓝牙功能不可用。此时APP蓝牙模块已经初始化完成,可通过uni.onBluetoothAdapterStateChange监听手机蓝牙状态的改变,也可以调用蓝牙模块的所有API。
2、监听蓝牙适配器状态变化事件
uni.onBluetoothAdapterStateChange(CALLBACK)
CALLBACK 返回参数
| 属性 | 类型 | 说明 |
|---|---|---|
| available | boolean | 蓝牙适配器是否可用 |
| discovering | boolean | 蓝牙适配器是否处于搜索状态 |
示例代码
uni.onBluetoothAdapterStateChange((res) => {
console.log('onBluetoothAdapterStateChange', res)
// available:蓝牙适配器是否可用
if (res.available) {
// 取消监听,否则stopBluetoothDevicesDiscovery后仍会继续触发onBluetoothAdapterStateChange,
// 导致再次调用startBluetoothDevicesDiscovery
uni.onBluetoothAdapterStateChange(() => {});
// 开始搜寻附近的蓝牙外围设备
uni.startBluetoothDevicesDiscovery(OBJECT)
}
})
3、开始搜寻附近的蓝牙外围设备
uni.startBluetoothDevicesDiscovery(OBJECT)
此操作比较耗费系统资源,请在搜索并连接到设备后调用 uni.stopBluetoothDevicesDiscovery 方法停止搜索。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| services | Array | 否 | 要搜索但蓝牙设备主 service 的 uuid 列表。某些蓝牙设备会广播自己的主 service 的 uuid。如果设置此参数,则只搜索广播包有对应 uuid 的主服务的蓝牙设备。建议主要通过该参数过滤掉周边不需要处理的其他蓝牙设备。 | |
| allowDuplicatesKey | boolean | false | 否 | 是否允许重复上报同一设备。如果允许重复上报,则 uni.onBlueToothDeviceFound 方法会多次上报同一设备,但是 RSSI 值会有不同。 |
| interval | number | 0 | 否 | 上报设备的间隔。0 表示找到新设备立即上报,其他数值根据传入的间隔上报。 |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
注意:
- App 端目前仅支持发现ble蓝牙设备,更多蓝牙设备发现,可以使用 Native.js,参考:https://ask.dcloud.net.cn/article/114。也可以在插件市场获取原生插件
示例代码
// 以微信硬件平台的蓝牙智能灯为例,主服务的 UUID 是 FEE7。传入这个参数,只搜索主服务 UUID 为 FEE7 的设备
uni.startBluetoothDevicesDiscovery({
services: ['FEE7'],
success(res) {
console.log(res)
// 监听寻找到新设备的事件
uni.onBluetoothDeviceFound(OBJECT)
}
})
4、监听寻找到新设备的事件
uni.onBluetoothDeviceFound(CALLBACK)
CALLBACK 返回参数
| 属性 | 类型 | 说明 |
|---|---|---|
| devices | Array | 新搜索到的设备列表 |
devices 的结构
| 属性 | 类型 | 说明 |
|---|---|---|
| name | string | 蓝牙设备名称,某些设备可能没有 |
| deviceId | string | 用于区分设备的 id |
| RSSI | number | 当前蓝牙设备的信号强度 |
| advertisData | ArrayBuffer | 当前蓝牙设备的广播数据段中的 ManufacturerData 数据段。 |
| advertisServiceUUIDs | Array | 当前蓝牙设备的广播数据段中的 ServiceUUIDs 数据段 |
| localName | string | 当前蓝牙设备的广播数据段中的 LocalName 数据段 |
| serviceData | Object | 当前蓝牙设备的广播数据段中的 ServiceData 数据段 |
注意
- 若在
uni.onBluetoothDeviceFound回调了某个设备,则此设备会添加到uni.getBluetoothDevices接口获取到的数组中。
示例代码
// ArrayBuffer转16进度字符串示例
function ab2hex(buffer) {
const hexArr = Array.prototype.map.call(
new Uint8Array(buffer),
function (bit) {
return ('00' + bit.toString(16)).slice(-2)
}
)
return hexArr.join('')
}
uni.onBluetoothDeviceFound(function (devices) {
console.log('new device list has founded')
console.dir(devices)
console.log(ab2hex(devices[0].advertisData))
})
5、停止搜寻附近的蓝牙外围设备
uni.stopBluetoothDevicesDiscovery(OBJECT)
若已经找到需要的蓝牙设备并不需要继续搜索时,建议调用该接口停止蓝牙搜索。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
示例代码
uni.stopBluetoothDevicesDiscovery({
success(res) {
console.log(res)
}
})
6、根据 uuid 获取处于已连接状态的设备
uni.getConnectedBluetoothDevices(OBJECT)
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| services | Array | 是 | 蓝牙设备主 service 的 uuid 列表 | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
success 返回参数说明:
| 属性 | 类型 | 说明 |
|---|---|---|
| devices | Array | 搜索到的设备列表 |
res.devices 的结构
| 属性 | 类型 | 说明 |
|---|---|---|
| name | string | 蓝牙设备名称,某些设备可能没有 |
| deviceId | string | 用于区分设备的 id |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
示例代码
uni.getConnectedBluetoothDevices({
success(res) {
console.log(res)
}
})
7、获取在蓝牙模块生效期间所有已发现的蓝牙设备
uni.getBluetoothDevices(OBJECT)
包括已经和本机处于连接状态的设备。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
success 返回参数说明:
| 属性 | 类型 | 说明 |
|---|---|---|
| devices | Array | uuid 对应的的已连接设备列表 |
res.devices 的结构
| 属性 | 类型 | 说明 |
|---|---|---|
| name | string | 蓝牙设备名称,某些设备可能没有 |
| deviceId | string | 用于区分设备的 id |
| RSSI | number | 当前蓝牙设备的信号强度 |
| advertisData | ArrayBuffer | 当前蓝牙设备的广播数据段中的 ManufacturerData 数据段。 |
| advertisServiceUUIDs | Array | 当前蓝牙设备的广播数据段中的 ServiceUUIDs 数据段 |
| localName | string | 当前蓝牙设备的广播数据段中的 LocalName 数据段 |
| serviceData | Object | 当前蓝牙设备的广播数据段中的 ServiceData 数据段 |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
示例代码
// ArrayBuffer转16进度字符串示例
function ab2hex(buffer) {
const hexArr = Array.prototype.map.call(
new Uint8Array(buffer),
function (bit) {
return ('00' + bit.toString(16)).slice(-2)
}
)
return hexArr.join('')
}
uni.getBluetoothDevices({
success(res) {
console.log(res)
if (res.devices[0]) {
console.log(ab2hex(res.devices[0].advertisData))
}
}
})
注意
- 该接口获取到的设备列表为蓝牙模块生效期间所有搜索到的蓝牙设备,若在蓝牙模块使用流程结束后未及时调用
uni.closeBluetoothAdapter释放资源,会存在调用该接口会返回之前的蓝牙使用流程中搜索到的蓝牙设备,可能设备已经不在用户身边,无法连接。 - 蓝牙设备在被搜索到时,系统返回的 name 字段一般为广播包中的 LocalName 字段中的设备名称,而如果与蓝牙设备建立连接,系统返回的 name 字段会改为从蓝牙设备上获取到的
GattName。若需要动态改变设备名称并展示,建议使用localName字段。
8、获取本机蓝牙适配器状态
uni.getBluetoothAdapterState(OBJECT)
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
success 返回参数说明:
| 属性 | 类型 | 说明 |
|---|---|---|
| discovering | boolean | 是否正在搜索设备 |
| available | boolean | 蓝牙适配器是否可用 |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
示例代码
uni.getBluetoothAdapterState({
success(res) {
console.log(res)
}
})
9、关闭蓝牙模块
uni.closeBluetoothAdapter(OBJECT)
调用该方法将断开所有已建立的连接并释放系统资源。建议在使用蓝牙流程后,与 uni.openBluetoothAdapter 成对调用。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
示例代码
uni.closeBluetoothAdapter({
success(res) {
console.log(res)
}
})
低功耗蓝牙:
1、设置蓝牙最大传输单元
[uni.setBLEMTU(OBJECT)
需在 uni.createBLEConnection调用成功后调用,mtu 设置范围 (22,512)。安卓5.1以上有效。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 用于区分设备的 id | |
| mtu | number | 是 | 最大传输单元(22,512) 区间内,单位 bytes | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
2、向低功耗蓝牙设备特征值中写入二进制数据
uni.writeBLECharacteristicValue(OBJECT)
注意:必须设备的特征值支持 write 才可以成功调用。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 蓝牙设备 id | |
| serviceId | string | 是 | 蓝牙特征值对应服务的 uuid | |
| characteristicId | string | 是 | 蓝牙特征值的 uuid | |
| value | ArrayBuffer | 是 | 蓝牙设备特征值对应的二进制值 | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
- 并行调用多次会存在写失败的可能性。
- APP不会对写入数据包大小做限制,但系统与蓝牙设备会限制蓝牙4.0单次传输的数据大小,超过最大字节数后会发生写入错误,建议每次写入不超过20字节。
- 若单次写入数据过长,iOS 上存在系统不会有任何回调的情况(包括错误回调)。
- 安卓平台上,在调用
notifyBLECharacteristicValueChange成功后立即调用writeBLECharacteristicValue接口,在部分机型上会发生 10008 系统错误
// 向蓝牙设备发送一个0x00的16进制数据
const buffer = new ArrayBuffer(1)
const dataView = new DataView(buffer)
dataView.setUint8(0, 0)
uni.writeBLECharacteristicValue({
// 这里的 deviceId 需要在 getBluetoothDevices 或 onBluetoothDeviceFound 接口中获取
deviceId,
// 这里的 serviceId 需要在 getBLEDeviceServices 接口中获取
serviceId,
// 这里的 characteristicId 需要在 getBLEDeviceCharacteristics 接口中获取
characteristicId,
// 这里的value是ArrayBuffer类型
value: buffer,
success(res) {
console.log('writeBLECharacteristicValue success', res.errMsg)
}
})
3、读取低功耗蓝牙设备的特征值的二进制数据值
uni.readBLECharacteristicValue(OBJECT)
注意:必须设备的特征值支持 read 才可以成功调用。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 蓝牙设备 id | |
| serviceId | string | 是 | 蓝牙特征值对应服务的 uuid | |
| characteristicId | string | 是 | 蓝牙特征值的 uuid | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
- 并行调用多次会存在读失败的可能性。
- 接口读取到的信息需要在
onBLECharacteristicValueChange方法注册的回调中获取。
// 必须在这里的回调才能获取
uni.onBLECharacteristicValueChange(function (characteristic) {
console.log('characteristic value comed:', characteristic)
})
uni.readBLECharacteristicValue({
// 这里的 deviceId 需要已经通过 createBLEConnection 与对应设备建立链接
deviceId,
// 这里的 serviceId 需要在 getBLEDeviceServices 接口中获取
serviceId,
// 这里的 characteristicId 需要在 getBLEDeviceCharacteristics 接口中获取
characteristicId,
success(res) {
console.log('readBLECharacteristicValue:', res.errCode)
}
})
4、监听低功耗蓝牙连接状态的改变事件
uni.onBLEConnectionStateChange(CALLBACK)
包括开发者主动连接或断开连接,设备丢失,连接异常断开等等
CALLBACK 返回参数
| 属性 | 类型 | 说明 |
|---|---|---|
| deviceId | string | 蓝牙设备ID |
| connected | boolean | 是否处于已连接状态 |
uni.onBLEConnectionStateChange(function (res) {
// 该方法回调中可以用于处理连接意外断开等异常情况
console.log(`device ${res.deviceId} state has changed, connected: ${res.connected}`)
})
5、监听低功耗蓝牙设备的特征值变化事件
uni.onBLECharacteristicValueChange(CALLBACK)
必须先启用 notifyBLECharacteristicValueChange 接口才能接收到设备推送的 notification。
CALLBACK 返回参数
| 属性 | 类型 | 说明 |
|---|---|---|
| deviceId | string | 蓝牙设备 id |
| serviceId | string | 蓝牙特征值对应服务的 uuid |
| characteristicId | string | 蓝牙特征值的 uuid |
| value | ArrayBuffer | 特征值最新的值 |
// ArrayBuffer转16进度字符串示例
function ab2hex(buffer) {
const hexArr = Array.prototype.map.call(
new Uint8Array(buffer),
function (bit) {
return ('00' + bit.toString(16)).slice(-2)
}
)
return hexArr.join('')
}
uni.onBLECharacteristicValueChange(function (res) {
console.log(`characteristic ${res.characteristicId} has changed, now is ${res.value}`)
console.log(ab2hex(res.value))
})
6、订阅特征值
uni.notifyBLECharacteristicValueChange(OBJECT)
启用低功耗蓝牙设备特征值变化时的 notify 功能,订阅特征值。注意:必须设备的特征值支持 notify 或者 indicate 才可以成功调用。 另外,必须先启用 notifyBLECharacteristicValueChange 才能监听到设备 characteristicValueChange 事件
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 蓝牙设备 id | |
| serviceId | string | 是 | 蓝牙特征值对应服务的 uuid | |
| characteristicId | string | 是 | 蓝牙特征值的 uuid | |
| state | boolean | 是 | 是否启用 notify | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
- 订阅操作成功后需要设备主动更新特征值的 value,才会触发
uni.onBLECharacteristicValueChange回调。 - 安卓平台上,在调用
notifyBLECharacteristicValueChange成功后立即调用writeBLECharacteristicValue接口,在部分机型上会发生 10008 系统错误
uni.notifyBLECharacteristicValueChange({
state: true, // 启用 notify 功能
// 这里的 deviceId 需要已经通过 createBLEConnection 与对应设备建立链接
deviceId,
// 这里的 serviceId 需要在 getBLEDeviceServices 接口中获取
serviceId,
// 这里的 characteristicId 需要在 getBLEDeviceCharacteristics 接口中获取
characteristicId,
success(res) {
console.log('notifyBLECharacteristicValueChange success', res.errMsg)
}
})
7、获取蓝牙设备所有服务(service)
uni.getBLEDeviceServices(OBJECT)
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 蓝牙设备 id | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
success 返回参数说明:
| 属性 | 类型 | 说明 |
|---|---|---|
| services | Array | 设备服务列表 |
res.services 的结构
| 属性 | 类型 | 说明 |
|---|---|---|
| uuid | string | 蓝牙设备服务的 uuid |
| isPrimary | boolean | 该服务是否为主服务 |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
uni.getBLEDeviceServices({
// 这里的 deviceId 需要已经通过 createBLEConnection 与对应设备建立链接
deviceId,
success(res) {
console.log('device services:', res.services)
}
})
8、获取蓝牙设备的信号强度
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 蓝牙设备 id | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
9、获取蓝牙设备某个服务中所有特征值(characteristic)。
uni.getBLEDeviceCharacteristics(OBJECT)
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 蓝牙设备 id | |
| serviceId | string | 是 | 蓝牙服务 uuid,需要使用 getBLEDeviceServices 获取 | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
success 返回参数说明:
| 属性 | 类型 | 说明 |
|---|---|---|
| characteristics | Array | 设备服务列表 |
res.characteristics 的结构
| 属性 | 类型 | 说明 |
|---|---|---|
| uuid | string | 蓝牙设备特征值的 uuid |
| properties | Object | 该特征值支持的操作类型 |
properties 的结构
| 属性 | 类型 | 说明 |
|---|---|---|
| read | boolean | 该特征值是否支持 read 操作 |
| write | boolean | 该特征值是否支持 write 操作 |
| notify | boolean | 该特征值是否支持 notify 操作 |
| indicate | boolean | 该特征值是否支持 indicate 操作 |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
uni.getBLEDeviceCharacteristics({
// 这里的 deviceId 需要已经通过 createBLEConnection 与对应设备建立链接
deviceId,
// 这里的 serviceId 需要在 getBLEDeviceServices 接口中获取
serviceId,
success(res) {
console.log('device getBLEDeviceCharacteristics:', res.characteristics)
}
})
10、连接低功耗蓝牙设备
uni.createBLEConnection(OBJECT)
若APP在之前已有搜索过某个蓝牙设备,并成功建立连接,可直接传入之前搜索获取的 deviceId 直接尝试连接该设备,无需进行搜索操作。
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 用于区分设备的 id | |
| timeout | number | 否 | 超时时间,单位ms,不填表示不会超时 | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
- 请保证尽量成对的调用
createBLEConnection和closeBLEConnection接口。安卓如果多次调用createBLEConnection创建连接,有可能导致系统持有同一设备多个连接的实例,导致调用closeBLEConnection的时候并不能真正的断开与设备的连接。 - 蓝牙连接随时可能断开,建议监听
uni.onBLEConnectionStateChange回调事件,当蓝牙设备断开时按需执行重连操作 - 若对未连接的设备或已断开连接的设备调用数据读写操作的接口,会返回 10006 错误,建议进行重连操作。
uni.createBLEConnection({
// 这里的 deviceId 需要已经通过 createBLEConnection 与对应设备建立链接
deviceId,
success(res) {
console.log(res)
}
})
11、断开与低功耗蓝牙设备的连接。
uni.closeBLEConnection(OBJECT)
OBJECT 参数说明
| 属性 | 类型 | 默认值 | 必填 | 说明 |
|---|---|---|---|---|
| deviceId | string | 是 | 用于区分设备的 id | |
| success | function | 否 | 接口调用成功的回调函数 | |
| fail | function | 否 | 接口调用失败的回调函数 | |
| complete | function | 否 | 接口调用结束的回调函数(调用成功、失败都会执行) |
| 错误码 | 错误信息 | 说明 |
|---|---|---|
| 0 | ok | 正常 |
| 10000 | not init | 未初始化蓝牙适配器 |
| 10001 | not available | 当前蓝牙适配器不可用 |
| 10002 | no device | 没有找到指定设备 |
| 10003 | connection fail | 连接失败 |
| 10004 | no service | 没有找到指定服务 |
| 10005 | no characteristic | 没有找到指定特征值 |
| 10006 | no connection | 当前连接已断开 |
| 10007 | property not support | 当前特征值不支持此操作 |
| 10008 | system error | 其余所有系统上报的异常 |
| 10009 | system not support | Android 系统特有,系统版本低于 4.3 不支持 BLE |
uni.closeBLEConnection({
deviceId,
success(res) {
console.log(res)
}
})
实现代码:
<template>
<!-- 蓝牙打印页面 -->
<view class="page">
<button @click="openBluetoothAdapter">重新查询</button>
<view class="title">
可连接的蓝牙设备列表:
<text style="color: red;font-size:22rpx;">(部分机型需要打开GPS定位服务)</text>
</view>
<view class="list">
<view class="item" v-for="(item, i) in devices" :key="i">
<!-- 设备名称 -->
<text>{{ item.name }}</text>
<!-- 连接状态 -->
<view class="right">
<view class="font-color-3" @click="createBLEConnection(item)" v-show="!item.isShowConnect">连接设备</view>
<view class="font-color-3" v-show="item.isShowConnect">已连接</view>
</view>
</view>
<!-- v-if="devices.length" -->
<button :class="isDisabled || isConnected ? 'submit disabled' : 'submit'" @click="writeBLECharacteristicValue" :disabled="isDisabled || isConnected">开始打印</button>
<view class="no-devices" v-if="!devices.length">未搜索到蓝牙设备</view>
</view>
</view>
</template>
<script>
const LAST_CONNECTED_DEVICE = 'last_connected_device';
import PrinterJobs from '../../common/printer/printerjobs';
import printerUtil from '../../common/printer/printerutil';
function inArray(arr, key, val) {
for (let i = 0; i < arr.length; i++) {
if (arr[i][key] === val) {
return i;
}
}
return -1;
}
// ArrayBuffer转16进度字符串示例
function ab2hex(buffer) {
const hexArr = Array.prototype.map.call(new Uint8Array(buffer), function(bit) {
return ('00' + bit.toString(16)).slice(-2);
});
return hexArr.join(',');
}
function str2ab(str) {
// Convert str to ArrayBuff and write to printer
let buffer = new ArrayBuffer(str.length);
let dataView = new DataView(buffer);
for (let i = 0; i < str.length; i++) {
dataView.setUint8(i, str.charAt(i).charCodeAt(0));
}
return buffer;
}
export default {
name: 'print',
components: {},
props: {},
data() {
return {
devices: [],
connected: false,
isConnected: true,
name: '',
deviceId: null
};
},
onLoad() {},
onShow() {},
created() {},
mounted() {
this.openBluetoothAdapter();
},
methods: {
// 初始化蓝牙
openBluetoothAdapter() {
console.log('初始化蓝牙模块 openBluetoothAdapter');
if (!uni.openBluetoothAdapter) {
console.log('微信版本过低');
uni.showModal({
title: '提示',
content: '当前微信版本过低,无法使用该功能,请升级到最新微信版本后重试。'
});
return;
}
uni.showLoading({
title: '开始搜索蓝牙设备'
});
// uni.hideLoading();
uni.openBluetoothAdapter({
success: res => {
console.log('初始化成功openBluetoothAdapter success', res);
uni.hideLoading();
// 搜寻附近的蓝牙
this.startBluetoothDevicesDiscovery();
},
fail: res => {
console.log('初始化失败openBluetoothAdapter fail', res);
// uni.showModal({
// content: res.errMsg,
// showCancel: false
// });
uni.hideLoading();
if (res.errCode === 10001) {
// 当前蓝牙适配器不可用
uni.showModal({
title: '错误',
content: '未找到蓝牙设备, 请打开蓝牙后重试。',
showCancel: false
});
// 监听蓝牙适配器状态变化事件
uni.onBluetoothAdapterStateChange(res => {
console.log('监听蓝牙适配器状态 onBluetoothAdapterStateChange', res);
// available:蓝牙适配器是否可用
if (res.available) {
// 取消监听,否则stopBluetoothDevicesDiscovery后仍会继续触发onBluetoothAdapterStateChange,
// 导致再次调用startBluetoothDevicesDiscovery
// uni.onBluetoothAdapterStateChange(() => {});
// 开始搜寻附近的蓝牙外围设备
this.startBluetoothDevicesDiscovery();
}
});
}
}
});
},
// 开始搜寻附近的蓝牙外围设备
startBluetoothDevicesDiscovery() {
console.log('开始搜寻附近的蓝牙设备');
uni.startBluetoothDevicesDiscovery({
allowDuplicatesKey: false,
interval: 0,
success: res => {
console.log('搜寻附近的蓝牙外围设备 startBluetoothDevicesDiscovery success111', res);
// 监听寻找到新设备的事件
this.onBluetoothDeviceFound();
},
fail: res => {
console.log('搜寻附近的蓝牙外围设备 startBluetoothDevicesDiscovery fail', res);
uni.hideLoading();
}
});
},
// 监听寻找到新设备的事件
onBluetoothDeviceFound() {
console.log('进入查询设备');
uni.onBluetoothDeviceFound(res => {
console.log('寻找设备', res.devices);
res.devices.forEach(device => {
if (!device.name && !device.localName) {
return;
}
const foundDevices = this.devices;
// 在数组中查找指定值,并返回它的索引值(如果没有找到,则返回-1)
const idx = inArray(foundDevices, 'deviceId', device.deviceId);
const data = {};
if (idx === -1) {
this.$set(this.devices, `${foundDevices.length}`, device);
} else {
this.$set(this.devices, `${idx}`, device);
}
console.log('搜索结果', this.devices);
uni.hideLoading();
});
});
},
// this.devices是蓝牙设备列表,渲染到页面显示点击执行蓝牙连接
// 点击链接蓝牙
createBLEConnection(e) {
console.log('点击连接蓝牙', e);
const deviceId = e.deviceId;
const name = e.name;
this._createBLEConnection(deviceId, name);
},
_createBLEConnection(deviceId, name) {
this.$myToast('连接设备中', 'loading');
// 连接低功耗蓝牙设备
uni.createBLEConnection({
deviceId, // 用于区分设备的 id
success: () => {
console.log('连接蓝牙接口调用成功 createBLEConnection success', this.devices);
this.devices.forEach((item, index) => {
this.$set(this.devices[index], 'isShowConnect', false);
if (item.deviceId === deviceId) {
this.$set(this.devices[index], 'isShowConnect', true);
}
});
this.$myToast('设备连接成功', 'success');
this.connected = true;
this.isConnected = false;
this.name = name;
this.deviceId = deviceId;
// 获取蓝牙设备所有服务(service)
this.getBLEDeviceServices(deviceId);
// 最后连接设备
uni.setStorage({
key: LAST_CONNECTED_DEVICE,
data: name + ':' + deviceId
});
},
complete() {
uni.hideLoading();
},
fail: res => {
// 连接蓝牙接口调用失败
console.log('连接蓝牙接口调用失败 createBLEConnection fail', res);
uni.showModal({
title: this.$t('wechat.w227'),
content: '蓝牙连接失败',
showCancel: false
});
}
});
// 已经找到需要的蓝牙设备,停止搜寻附近的蓝牙外围设备
this.stopBluetoothDevicesDiscovery();
},
// 获取蓝牙设备所有服务(service)
getBLEDeviceServices(deviceId) {
uni.getBLEDeviceServices({
deviceId,
success: res => {
console.log('获取蓝牙设备所有服务 getBLEDeviceServices', res);
for (let i = 0; i < res.services.length; i++) {
if (res.services[i].isPrimary) {
this.getBLEDeviceCharacteristics(deviceId, res.services[i].uuid);
return;
}
}
}
});
},
stopBluetoothDevicesDiscovery() {
uni.stopBluetoothDevicesDiscovery({
complete: () => {
// console.log('stopBluetoothDevicesDiscovery')
this._discoveryStarted = false;
}
});
},
/*
获取蓝牙设备某个服务中所有特征值(characteristic)
characteristic:
uuid:蓝牙设备特征值的 uuid
properties:该特征值支持的操作类型
*/
getBLEDeviceCharacteristics(deviceId, serviceId) {
uni.getBLEDeviceCharacteristics({
// 这里的 deviceId 需要已经通过 createBLEConnection 与对应设备建立链接
deviceId,
// 这里的 serviceId(蓝牙服务 uuid) 需要在 getBLEDeviceServices 接口中获取
serviceId,
success: res => {
console.log('特征值变化 getBLEDeviceCharacteristics success', res.characteristics);
// 这里会存在特征值是支持write,写入成功但是没有任何反应的情况
// 只能一个个去试
// characteristics:设备服务列表
for (let i = 0; i < res.characteristics.length; i++) {
const item = res.characteristics[i];
// if (item.properties.read) {
// uni.readBLECharacteristicValue({
// deviceId,
// serviceId,
// characteristicId: item.uuid
// })
// }
if (item.properties.write) {
this.canWrite = true;
this._deviceId = deviceId;
this._serviceId = serviceId;
this._characteristicId = item.uuid;
}
if (item.properties.notify || item.properties.indicate) {
uni.notifyBLECharacteristicValueChange({
deviceId,
serviceId,
characteristicId: item.uuid,
state: true
});
}
if (item.properties.write) {
this.canWrite = true;
this._deviceId = deviceId;
this._serviceId = serviceId;
this._characteristicId = item.uuid;
}
if (item.properties.notify || item.properties.indicate) {
uni.notifyBLECharacteristicValueChange({
deviceId,
serviceId,
characteristicId: item.uuid,
state: true
});
}
}
},
fail(res) {
console.error('特征值变化 getBLEDeviceCharacteristics', res);
}
});
},
// 蓝牙连接成功后点击打印,打印数据
// 点击打印:写入数据(根据项目需要打印内容来实现)
writeBLECharacteristicValue() {
console.log('写数据');
let printerJobs = new PrinterJobs();
// 要打印的信息
printerJobs
.setAlign('ct')
.setSize(2, 2)
.print('记录报告')
.setSize(0, 0)
.print()
.setAlign('lt');
// 打印
printerJobs.print(printerUtil.fillLine());
// 结尾
printerJobs
.println()
.print('签名')
.println()
.println();
let buffer = printerJobs.buffer();
// console.log('ArrayBuffer', 'length: ' + buffer.byteLength, ' hex: ' + ab2hex(buffer));
// 1.并行调用多次会存在写失败的可能性
// 2.建议每次写入不超过20字节
// 分包处理,延时调用
const maxChunk = 20;
const delay = 40;
console.log(111111);
for (let i = 0, j = 0, length = buffer.byteLength; i < length; i += maxChunk, j++) {
let subPackage = buffer.slice(i, i + maxChunk <= length ? i + maxChunk : length);
// subPackage:参数
setTimeout(this._writeBLECharacteristicValue, j * delay, subPackage);
}
console.log(22222);
},
// 向低功耗蓝牙设备特征值中写入二进制数据。注意:必须设备的特征值支持 write 才可以成功调用。
_writeBLECharacteristicValue(buffer) {
console.log('写入数据');
uni.writeBLECharacteristicValue({
deviceId: this._deviceId, // 蓝牙设备 id
serviceId: this._serviceId, // 蓝牙特征值对应服务的 uuid
characteristicId: this._characteristicId, // 蓝牙特征值的 uuid
value: buffer, // 蓝牙设备特征值对应的二进制值
success(res) {
console.log('writeBLECharacteristicValue success', res);
},
fail(res) {
console.log('writeBLECharacteristicValue fail', res);
}
});
}
}
};
</script>
<style scoped lang="scss">
.page {
margin: 20rpx;
color: #323232;
background-color: #f5f9ff;
height: 100vh;
}
.title {
font-weight: 600;
margin: 20rpx 0rpx;
}
.list {
.item {
display: flex;
justify-content: space-between;
padding: 10rpx 20rpx;
height: 60rpx;
line-height: 60rpx;
background-color: #ffffff;
margin-bottom: 4rpx;
}
.right {
}
.no-devices {
height: 400rpx;
font-size: 32rpx;
line-height: 400rpx;
text-align: center;
color: #969696;
}
}
.font-color-3 {
color: #1a8cff;
}
.submit {
background-color: #4d88ff !important;
color: #f5f9ff !important;
}
.disabled {
background-color: #66b1ff !important;
}
</style>
页面布局效果:
可根据项目具体需求对打印数据做处理,打印效果:
其他文件:
printerutil.js
// 打印机纸宽58mm,页的宽度384,字符宽度为1,每行最多盛放32个字符
const PAGE_WIDTH = 384;
const MAX_CHAR_COUNT_EACH_LINE = 32;
/**
* @param str
* @returns {boolean} str是否全是中文
*/
function isChinese(str) {
return /^[\u4e00-\u9fa5]$/.test(str);
}
/**
* 返回字符串宽度(1个中文=2个英文字符)
* @param str
* @returns {number}
*/
function getStringWidth(str) {
let width = 0;
for (let i = 0, len = str.length; i < len; i++) {
width += isChinese(str.charAt(i)) ? 2 : 1;
}
return width;
}
/**
* 同一行输出str1, str2,str1居左, str2居右
* @param {string} str1 内容1
* @param {string} str2 内容2
* @param {number} fontWidth 字符宽度 1/2
* @param {string} fillWith str1 str2之间的填充字符
*
*/
function inline(str1, str2, fillWith = ' ', fontWidth = 1) {
const lineWidth = MAX_CHAR_COUNT_EACH_LINE / fontWidth;
// 需要填充的字符数量
let fillCount = lineWidth - (getStringWidth(str1) + getStringWidth(str2)) % lineWidth;
let fillStr = new Array(fillCount).fill(fillWith.charAt(0)).join('');
return str1 + fillStr + str2;
}
/**
* 用字符填充一整行
* @param {string} fillWith 填充字符
* @param {number} fontWidth 字符宽度 1/2
*/
function fillLine(fillWith = '-', fontWidth = 1) {
const lineWidth = MAX_CHAR_COUNT_EACH_LINE / fontWidth;
return new Array(lineWidth).fill(fillWith.charAt(0)).join('');
}
/**
* 文字内容居中,左右用字符填充
* @param {string} str 文字内容
* @param {number} fontWidth 字符宽度 1/2
* @param {string} fillWith str1 str2之间的填充字符
*/
function fillAround(str, fillWith = '-', fontWidth = 1) {
const lineWidth = MAX_CHAR_COUNT_EACH_LINE / fontWidth;
let strWidth = getStringWidth(str);
// 内容已经超过一行了,没必要填充
if (strWidth >= lineWidth) {
return str;
}
// 需要填充的字符数量
let fillCount = lineWidth - strWidth;
// 左侧填充的字符数量
let leftCount = Math.round(fillCount / 2);
// 两侧的填充字符,需要考虑左边需要填充,右边不需要填充的情况
let fillStr = new Array(leftCount).fill(fillWith.charAt(0)).join('');
return fillStr + str + fillStr.substr(0, fillCount - leftCount);
}
module.exports = {
inline: inline,
fillLine: fillLine,
fillAround: fillAround,
};
printerjobs.js
const commands = require('./commands.js');
const TextEncoder = require('../text-encoding/index').TextEncoder;
const printerJobs = function () {
this._queue = Array.from(commands.HARDWARE.HW_INIT);
this._encoder = new TextEncoder("gb2312", {NONSTANDARD_allowLegacyEncoding: true});
this._enqueue = function (cmd) {
this._queue.push.apply(this._queue, cmd);
}
};
/**
* 增加打印内容
* @param {string} content 文字内容
*/
printerJobs.prototype.text = function (content) {
if (content) {
let uint8Array = this._encoder.encode(content);
let encoded = Array.from(uint8Array);
this._enqueue(encoded);
}
return this;
};
/**
* 打印文字
* @param {string} content 文字内容
*/
printerJobs.prototype.print = function (content) {
this.text(content);
this._enqueue(commands.LF);
return this;
};
/**
* 打印文字并换行
* @param {string} content 文字内容
*/
printerJobs.prototype.println = function (content = '') {
return this.print(content + commands.EOL);
};
/**
* 设置对齐方式
* @param {string} align 对齐方式 LT/CT/RT
*/
printerJobs.prototype.setAlign = function (align) {
this._enqueue(commands.TEXT_FORMAT['TXT_ALIGN_' + align.toUpperCase()]);
return this;
};
/**
* 设置字体
* @param {string} family A/B/C
*/
printerJobs.prototype.setFont = function (family) {
this._enqueue(commands.TEXT_FORMAT['TXT_FONT_' + family.toUpperCase()]);
return this;
};
/**
* 设定字体尺寸
* @param {number} width 字体宽度 1~2
* @param {number} height 字体高度 1~2
*/
printerJobs.prototype.setSize = function (width, height) {
if (2 >= width && 2 >= height) {
this._enqueue(commands.TEXT_FORMAT.TXT_NORMAL);
if (2 === width && 2 === height) {
this._enqueue(commands.TEXT_FORMAT.TXT_4SQUARE);
} else if (1 === width && 2 === height) {
this._enqueue(commands.TEXT_FORMAT.TXT_2HEIGHT);
} else if (2 === width && 1 === height) {
this._enqueue(commands.TEXT_FORMAT.TXT_2WIDTH);
}
}
return this;
};
/**
* 设定字体是否加粗
* @param {boolean} bold
*/
printerJobs.prototype.setBold = function (bold) {
if (typeof bold !== 'boolean') {
bold = true;
}
this._enqueue(bold ? commands.TEXT_FORMAT.TXT_BOLD_ON : commands.TEXT_FORMAT.TXT_BOLD_OFF);
return this;
};
/**
* 设定是否开启下划线
* @param {boolean} underline
*/
printerJobs.prototype.setUnderline = function (underline) {
if (typeof underline !== 'boolean') {
underline = true;
}
this._enqueue(underline ? commands.TEXT_FORMAT.TXT_UNDERL_ON : commands.TEXT_FORMAT.TXT_UNDERL_OFF);
return this;
};
/**
* 设置行间距为 n 点行,默认值行间距是 30 点
* @param {number} n 0≤n≤255
*/
printerJobs.prototype.setLineSpacing = function (n) {
if (n === undefined || n === null) {
this._enqueue(commands.LINE_SPACING.LS_DEFAULT);
} else {
this._enqueue(commands.LINE_SPACING.LS_SET);
this._enqueue([n]);
}
return this;
};
/**
* 打印空行
* @param {number} n
*/
printerJobs.prototype.lineFeed = function (n = 1) {
return this.print(new Array(n).fill(commands.EOL).join(''));
};
/**
* 设置字体颜色,需要打印机支持
* @param {number} color - 0 默认颜色黑色 1 红色
*/
printerJobs.prototype.setColor = function (color) {
this._enqueue(commands.COLOR[color === 1 ? 1 : 0]);
return this;
};
/**
* https://support.loyverse.com/hardware/printers/use-the-beeper-in-a-escpos-printers
* 蜂鸣警报,需要打印机支持
* @param {number} n 蜂鸣次数,1-9
* @param {number} t 蜂鸣长短,1-9
*/
printerJobs.prototype.beep = function (n, t) {
this._enqueue(commands.BEEP);
this._enqueue([n, t]);
return this;
};
/**
* 清空任务
*/
printerJobs.prototype.clear = function () {
this._queue = Array.from(commands.HARDWARE.HW_INIT);
return this;
};
/**
* 返回ArrayBuffer
*/
printerJobs.prototype.buffer = function () {
return new Uint8Array(this._queue).buffer;
};
module.exports = printerJobs;
commands.js
/**
* 修改自https://github.com/song940/node-escpos/blob/master/commands.js
* ESC/POS _ (Constants)
*/
var _ = {
LF: [0x0a],
FS: [0x1c],
FF: [0x0c],
GS: [0x1d],
DLE: [0x10],
EOT: [0x04],
NUL: [0x00],
ESC: [0x1b],
EOL: '\n',
};
/**
* [FEED_CONTROL_SEQUENCES Feed control sequences]
* @type {Object}
*/
_.FEED_CONTROL_SEQUENCES = {
CTL_LF: [0x0a], // Print and line feed 打印换行
CTL_GLF: [0x4a, 0x00], // Print and feed paper (without spaces between lines) 打印和送纸(行间无空格)
CTL_FF: [0x0c], // Form feed 换页
CTL_CR: [0x0d], // Carriage return
CTL_HT: [0x09], // Horizontal tab 回车
CTL_VT: [0x0b], // Vertical tab 垂直制表符
};
_.CHARACTER_SPACING = {
CS_DEFAULT: [0x1b, 0x20, 0x00],
CS_SET: [0x1b, 0x20]
};
_.LINE_SPACING = {
LS_DEFAULT: [0x1b, 0x32],
LS_SET: [0x1b, 0x33]
};
/**
* [HARDWARE Printer hardware]
* @type {Object}
*/
_.HARDWARE = {
HW_INIT: [0x1b, 0x40], // Clear data in buffer and reset modes
HW_SELECT: [0x1b, 0x3d, 0x01], // Printer select
HW_RESET: [0x1b, 0x3f, 0x0a, 0x00], // Reset printer hardware
};
/**
* [CASH_DRAWER Cash Drawer]
* @type {Object}
*/
_.CASH_DRAWER = {
CD_KICK_2: [0x1b, 0x70, 0x00], // Sends a pulse to pin 2 []
CD_KICK_5: [0x1b, 0x70, 0x01], // Sends a pulse to pin 5 []
};
/**
* [MARGINS Margins sizes]
* @type {Object}
*/
_.MARGINS = {
BOTTOM: [0x1b, 0x4f], // Fix bottom size
LEFT: [0x1b, 0x6c], // Fix left size
RIGHT: [0x1b, 0x51], // Fix right size
};
/**
* [PAPER Paper]
* @type {Object}
*/
_.PAPER = {
PAPER_FULL_CUT: [0x1d, 0x56, 0x00], // Full cut paper
PAPER_PART_CUT: [0x1d, 0x56, 0x01], // Partial cut paper
PAPER_CUT_A: [0x1d, 0x56, 0x41], // Partial cut paper
PAPER_CUT_B: [0x1d, 0x56, 0x42], // Partial cut paper
};
/**
* [TEXT_FORMAT Text format]
* @type {Object}
*/
_.TEXT_FORMAT = {
TXT_NORMAL: [0x1b, 0x21, 0x00], // Normal text
TXT_2HEIGHT: [0x1b, 0x21, 0x10], // Double height text 两倍高度的文本
TXT_2WIDTH: [0x1b, 0x21, 0x20], // Double width text 双宽度的文本
TXT_4SQUARE: [0x1b, 0x21, 0x30], // Double width & height text 双宽度和高度文本
TXT_UNDERL_OFF: [0x1b, 0x2d, 0x00], // Underline font OFF
TXT_UNDERL_ON: [0x1b, 0x2d, 0x01], // Underline font 1-dot ON
TXT_UNDERL2_ON: [0x1b, 0x2d, 0x02], // Underline font 2-dot ON
TXT_BOLD_OFF: [0x1b, 0x45, 0x00], // Bold font OFF
TXT_BOLD_ON: [0x1b, 0x45, 0x01], // Bold font ON
TXT_ITALIC_OFF: [0x1b, 0x35], // Italic font ON
TXT_ITALIC_ON: [0x1b, 0x34], // Italic font ON
TXT_FONT_A: [0x1b, 0x4d, 0x00], // Font type A
TXT_FONT_B: [0x1b, 0x4d, 0x01], // Font type B
TXT_FONT_C: [0x1b, 0x4d, 0x02], // Font type C
TXT_ALIGN_LT: [0x1b, 0x61, 0x00], // Left justification
TXT_ALIGN_CT: [0x1b, 0x61, 0x01], // Centering
TXT_ALIGN_RT: [0x1b, 0x61, 0x02], // Right justification
};
/**
* [BARCODE_FORMAT Barcode format]
* @type {Object}
*/
_.BARCODE_FORMAT = {
BARCODE_TXT_OFF: [0x1d, 0x48, 0x00], // HRI barcode chars OFF
BARCODE_TXT_ABV: [0x1d, 0x48, 0x01], // HRI barcode chars above
BARCODE_TXT_BLW: [0x1d, 0x48, 0x02], // HRI barcode chars below
BARCODE_TXT_BTH: [0x1d, 0x48, 0x03], // HRI barcode chars both above and below
BARCODE_FONT_A: [0x1d, 0x66, 0x00], // Font type A for HRI barcode chars
BARCODE_FONT_B: [0x1d, 0x66, 0x01], // Font type B for HRI barcode chars
BARCODE_HEIGHT: function (height) { // Barcode Height [1-255]
return [0x1d, 0x68, height];
},
BARCODE_WIDTH: function (width) { // Barcode Width [2-6]
return [0x1d, 0x77, width];
},
BARCODE_HEIGHT_DEFAULT: [0x1d, 0x68, 0x64], // Barcode height default:100
BARCODE_WIDTH_DEFAULT: [0x1d, 0x77, 0x01], // Barcode width default:1
BARCODE_UPC_A: [0x1d, 0x6b, 0x00], // Barcode type UPC-A
BARCODE_UPC_E: [0x1d, 0x6b, 0x01], // Barcode type UPC-E
BARCODE_EAN13: [0x1d, 0x6b, 0x02], // Barcode type EAN13
BARCODE_EAN8: [0x1d, 0x6b, 0x03], // Barcode type EAN8
BARCODE_CODE39: [0x1d, 0x6b, 0x04], // Barcode type CODE39
BARCODE_ITF: [0x1d, 0x6b, 0x05], // Barcode type ITF
BARCODE_NW7: [0x1d, 0x6b, 0x06], // Barcode type NW7
BARCODE_CODE93: [0x1d, 0x6b, 0x48], // Barcode type CODE93
BARCODE_CODE128: [0x1d, 0x6b, 0x49], // Barcode type CODE128
};
/**
* [IMAGE_FORMAT Image format]
* @type {Object}
*/
_.IMAGE_FORMAT = {
S_RASTER_N: [0x1d, 0x76, 0x30, 0x00], // Set raster image normal size
S_RASTER_2W: [0x1d, 0x76, 0x30, 0x01], // Set raster image double width
S_RASTER_2H: [0x1d, 0x76, 0x30, 0x02], // Set raster image double height
S_RASTER_Q: [0x1d, 0x76, 0x30, 0x03], // Set raster image quadruple
};
/**
* [BITMAP_FORMAT description]
* @type {Object}
*/
_.BITMAP_FORMAT = {
BITMAP_S8: [0x1b, 0x2a, 0x00],
BITMAP_D8: [0x1b, 0x2a, 0x01],
BITMAP_S24: [0x1b, 0x2a, 0x20],
BITMAP_D24: [0x1b, 0x2a, 0x21]
};
/**
* [GSV0_FORMAT description]
* @type {Object}
*/
_.GSV0_FORMAT = {
GSV0_NORMAL: [0x1d, 0x76, 0x30, 0x00],
GSV0_DW: [0x1d, 0x76, 0x30, 0x01],
GSV0_DH: [0x1d, 0x76, 0x30, 0x02],
GSV0_DWDH: [0x1d, 0x76, 0x30, 0x03]
};
/**
* [BEEP description]
* @type {string}
*/
_.BEEP = [0x1b, 0x42]; // Printer Buzzer pre hex
/**
* [COLOR description]
* @type {Object}
*/
_.COLOR = {
0: [0x1b, 0x72, 0x00], // black
1: [0x1b, 0x72, 0x01] // red
};
/**
* [exports description]
* @type {[type]}
*/
module.exports = _;
text-encoding/index
// This is free and unencumbered software released into the public domain.
// See LICENSE.md for more information.
/**
* @fileoverview Global |this| required for resolving indexes in node.
* @suppress {globalThis}
*/
(function(global) {
'use strict';
// If we're in node require encoding-indexes and attach it to the global.
if (typeof module !== "undefined" && module.exports &&
!global["encoding-indexes"]) {
global["encoding-indexes"] =
require("./encoding-indexes.js")["encoding-indexes"];
}
//
// Utilities
//
/**
* @param {number} a The number to test.
* @param {number} min The minimum value in the range, inclusive.
* @param {number} max The maximum value in the range, inclusive.
* @return {boolean} True if a >= min and a <= max.
*/
function inRange(a, min, max) {
return min <= a && a <= max;
}
/**
* @param {!Array.<*>} array The array to check.
* @param {*} item The item to look for in the array.
* @return {boolean} True if the item appears in the array.
*/
function includes(array, item) {
return array.indexOf(item) !== -1;
}
var floor = Math.floor;
/**
* @param {*} o
* @return {Object}
*/
function ToDictionary(o) {
if (o === undefined) return {};
if (o === Object(o)) return o;
throw TypeError('Could not convert argument to dictionary');
}
/**
* @param {string} string Input string of UTF-16 code units.
* @return {!Array.<number>} Code points.
*/
function stringToCodePoints(string) {
// https://heycam.github.io/webidl/#dfn-obtain-unicode
// 1. Let S be the DOMString value.
var s = String(string);
// 2. Let n be the length of S.
var n = s.length;
// 3. Initialize i to 0.
var i = 0;
// 4. Initialize U to be an empty sequence of Unicode characters.
var u = [];
// 5. While i < n:
while (i < n) {
// 1. Let c be the code unit in S at index i.
var c = s.charCodeAt(i);
// 2. Depending on the value of c:
// c < 0xD800 or c > 0xDFFF
if (c < 0xD800 || c > 0xDFFF) {
// Append to U the Unicode character with code point c.
u.push(c);
}
// 0xDC00 ≤ c ≤ 0xDFFF
else if (0xDC00 <= c && c <= 0xDFFF) {
// Append to U a U+FFFD REPLACEMENT CHARACTER.
u.push(0xFFFD);
}
// 0xD800 ≤ c ≤ 0xDBFF
else if (0xD800 <= c && c <= 0xDBFF) {
// 1. If i = n−1, then append to U a U+FFFD REPLACEMENT
// CHARACTER.
if (i === n - 1) {
u.push(0xFFFD);
}
// 2. Otherwise, i < n−1:
else {
// 1. Let d be the code unit in S at index i+1.
var d = s.charCodeAt(i + 1);
// 2. If 0xDC00 ≤ d ≤ 0xDFFF, then:
if (0xDC00 <= d && d <= 0xDFFF) {
// 1. Let a be c & 0x3FF.
var a = c & 0x3FF;
// 2. Let b be d & 0x3FF.
var b = d & 0x3FF;
// 3. Append to U the Unicode character with code point
// 2^16+2^10*a+b.
u.push(0x10000 + (a << 10) + b);
// 4. Set i to i+1.
i += 1;
}
// 3. Otherwise, d < 0xDC00 or d > 0xDFFF. Append to U a
// U+FFFD REPLACEMENT CHARACTER.
else {
u.push(0xFFFD);
}
}
}
// 3. Set i to i+1.
i += 1;
}
// 6. Return U.
return u;
}
/**
* @param {!Array.<number>} code_points Array of code points.
* @return {string} string String of UTF-16 code units.
*/
function codePointsToString(code_points) {
var s = '';
for (var i = 0; i < code_points.length; ++i) {
var cp = code_points[i];
if (cp <= 0xFFFF) {
s += String.fromCharCode(cp);
} else {
cp -= 0x10000;
s += String.fromCharCode((cp >> 10) + 0xD800,
(cp & 0x3FF) + 0xDC00);
}
}
return s;
}
//
// Implementation of Encoding specification
// https://encoding.spec.whatwg.org/
//
//
// 4. Terminology
//
/**
* An ASCII byte is a byte in the range 0x00 to 0x7F, inclusive.
* @param {number} a The number to test.
* @return {boolean} True if a is in the range 0x00 to 0x7F, inclusive.
*/
function isASCIIByte(a) {
return 0x00 <= a && a <= 0x7F;
}
/**
* An ASCII code point is a code point in the range U+0000 to
* U+007F, inclusive.
*/
var isASCIICodePoint = isASCIIByte;
/**
* End-of-stream is a special token that signifies no more tokens
* are in the stream.
* @const
*/ var end_of_stream = -1;
/**
* A stream represents an ordered sequence of tokens.
*
* @constructor
* @param {!(Array.<number>|Uint8Array)} tokens Array of tokens that provide
* the stream.
*/
function Stream(tokens) {
/** @type {!Array.<number>} */
this.tokens = [].slice.call(tokens);
// Reversed as push/pop is more efficient than shift/unshift.
this.tokens.reverse();
}
Stream.prototype = {
/**
* @return {boolean} True if end-of-stream has been hit.
*/
endOfStream: function() {
return !this.tokens.length;
},
/**
* When a token is read from a stream, the first token in the
* stream must be returned and subsequently removed, and
* end-of-stream must be returned otherwise.
*
* @return {number} Get the next token from the stream, or
* end_of_stream.
*/
read: function() {
if (!this.tokens.length)
return end_of_stream;
return this.tokens.pop();
},
/**
* When one or more tokens are prepended to a stream, those tokens
* must be inserted, in given order, before the first token in the
* stream.
*
* @param {(number|!Array.<number>)} token The token(s) to prepend to the
* stream.
*/
prepend: function(token) {
if (Array.isArray(token)) {
var tokens = /**@type {!Array.<number>}*/(token);
while (tokens.length)
this.tokens.push(tokens.pop());
} else {
this.tokens.push(token);
}
},
/**
* When one or more tokens are pushed to a stream, those tokens
* must be inserted, in given order, after the last token in the
* stream.
*
* @param {(number|!Array.<number>)} token The tokens(s) to push to the
* stream.
*/
push: function(token) {
if (Array.isArray(token)) {
var tokens = /**@type {!Array.<number>}*/(token);
while (tokens.length)
this.tokens.unshift(tokens.shift());
} else {
this.tokens.unshift(token);
}
}
};
//
// 5. Encodings
//
// 5.1 Encoders and decoders
/** @const */
var finished = -1;
/**
* @param {boolean} fatal If true, decoding errors raise an exception.
* @param {number=} opt_code_point Override the standard fallback code point.
* @return {number} The code point to insert on a decoding error.
*/
function decoderError(fatal, opt_code_point) {
if (fatal)
throw TypeError('Decoder error');
return opt_code_point || 0xFFFD;
}
/**
* @param {number} code_point The code point that could not be encoded.
* @return {number} Always throws, no value is actually returned.
*/
function encoderError(code_point) {
throw TypeError('The code point ' + code_point + ' could not be encoded.');
}
/** @interface */
function Decoder() {}
Decoder.prototype = {
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point, or |finished|.
*/
handler: function(stream, bite) {}
};
/** @interface */
function Encoder() {}
Encoder.prototype = {
/**
* @param {Stream} stream The stream of code points being encoded.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit, or |finished|.
*/
handler: function(stream, code_point) {}
};
// 5.2 Names and labels
// TODO: Define @typedef for Encoding: {name:string,labels:Array.<string>}
// https://github.com/google/closure-compiler/issues/247
/**
* @param {string} label The encoding label.
* @return {?{name:string,labels:Array.<string>}}
*/
function getEncoding(label) {
// 1. Remove any leading and trailing ASCII whitespace from label.
label = String(label).trim().toLowerCase();
// 2. If label is an ASCII case-insensitive match for any of the
// labels listed in the table below, return the corresponding
// encoding, and failure otherwise.
if (Object.prototype.hasOwnProperty.call(label_to_encoding, label)) {
return label_to_encoding[label];
}
return null;
}
/**
* Encodings table: https://encoding.spec.whatwg.org/encodings.json
* @const
* @type {!Array.<{
* heading: string,
* encodings: Array.<{name:string,labels:Array.<string>}>
* }>}
*/
var encodings = [
{
"encodings": [
{
"labels": [
"unicode-1-1-utf-8",
"utf-8",
"utf8"
],
"name": "UTF-8"
}
],
"heading": "The Encoding"
},
{
"encodings": [
{
"labels": [
"866",
"cp866",
"csibm866",
"ibm866"
],
"name": "IBM866"
},
{
"labels": [
"csisolatin2",
"iso-8859-2",
"iso-ir-101",
"iso8859-2",
"iso88592",
"iso_8859-2",
"iso_8859-2:1987",
"l2",
"latin2"
],
"name": "ISO-8859-2"
},
{
"labels": [
"csisolatin3",
"iso-8859-3",
"iso-ir-109",
"iso8859-3",
"iso88593",
"iso_8859-3",
"iso_8859-3:1988",
"l3",
"latin3"
],
"name": "ISO-8859-3"
},
{
"labels": [
"csisolatin4",
"iso-8859-4",
"iso-ir-110",
"iso8859-4",
"iso88594",
"iso_8859-4",
"iso_8859-4:1988",
"l4",
"latin4"
],
"name": "ISO-8859-4"
},
{
"labels": [
"csisolatincyrillic",
"cyrillic",
"iso-8859-5",
"iso-ir-144",
"iso8859-5",
"iso88595",
"iso_8859-5",
"iso_8859-5:1988"
],
"name": "ISO-8859-5"
},
{
"labels": [
"arabic",
"asmo-708",
"csiso88596e",
"csiso88596i",
"csisolatinarabic",
"ecma-114",
"iso-8859-6",
"iso-8859-6-e",
"iso-8859-6-i",
"iso-ir-127",
"iso8859-6",
"iso88596",
"iso_8859-6",
"iso_8859-6:1987"
],
"name": "ISO-8859-6"
},
{
"labels": [
"csisolatingreek",
"ecma-118",
"elot_928",
"greek",
"greek8",
"iso-8859-7",
"iso-ir-126",
"iso8859-7",
"iso88597",
"iso_8859-7",
"iso_8859-7:1987",
"sun_eu_greek"
],
"name": "ISO-8859-7"
},
{
"labels": [
"csiso88598e",
"csisolatinhebrew",
"hebrew",
"iso-8859-8",
"iso-8859-8-e",
"iso-ir-138",
"iso8859-8",
"iso88598",
"iso_8859-8",
"iso_8859-8:1988",
"visual"
],
"name": "ISO-8859-8"
},
{
"labels": [
"csiso88598i",
"iso-8859-8-i",
"logical"
],
"name": "ISO-8859-8-I"
},
{
"labels": [
"csisolatin6",
"iso-8859-10",
"iso-ir-157",
"iso8859-10",
"iso885910",
"l6",
"latin6"
],
"name": "ISO-8859-10"
},
{
"labels": [
"iso-8859-13",
"iso8859-13",
"iso885913"
],
"name": "ISO-8859-13"
},
{
"labels": [
"iso-8859-14",
"iso8859-14",
"iso885914"
],
"name": "ISO-8859-14"
},
{
"labels": [
"csisolatin9",
"iso-8859-15",
"iso8859-15",
"iso885915",
"iso_8859-15",
"l9"
],
"name": "ISO-8859-15"
},
{
"labels": [
"iso-8859-16"
],
"name": "ISO-8859-16"
},
{
"labels": [
"cskoi8r",
"koi",
"koi8",
"koi8-r",
"koi8_r"
],
"name": "KOI8-R"
},
{
"labels": [
"koi8-ru",
"koi8-u"
],
"name": "KOI8-U"
},
{
"labels": [
"csmacintosh",
"mac",
"macintosh",
"x-mac-roman"
],
"name": "macintosh"
},
{
"labels": [
"dos-874",
"iso-8859-11",
"iso8859-11",
"iso885911",
"tis-620",
"windows-874"
],
"name": "windows-874"
},
{
"labels": [
"cp1250",
"windows-1250",
"x-cp1250"
],
"name": "windows-1250"
},
{
"labels": [
"cp1251",
"windows-1251",
"x-cp1251"
],
"name": "windows-1251"
},
{
"labels": [
"ansi_x3.4-1968",
"ascii",
"cp1252",
"cp819",
"csisolatin1",
"ibm819",
"iso-8859-1",
"iso-ir-100",
"iso8859-1",
"iso88591",
"iso_8859-1",
"iso_8859-1:1987",
"l1",
"latin1",
"us-ascii",
"windows-1252",
"x-cp1252"
],
"name": "windows-1252"
},
{
"labels": [
"cp1253",
"windows-1253",
"x-cp1253"
],
"name": "windows-1253"
},
{
"labels": [
"cp1254",
"csisolatin5",
"iso-8859-9",
"iso-ir-148",
"iso8859-9",
"iso88599",
"iso_8859-9",
"iso_8859-9:1989",
"l5",
"latin5",
"windows-1254",
"x-cp1254"
],
"name": "windows-1254"
},
{
"labels": [
"cp1255",
"windows-1255",
"x-cp1255"
],
"name": "windows-1255"
},
{
"labels": [
"cp1256",
"windows-1256",
"x-cp1256"
],
"name": "windows-1256"
},
{
"labels": [
"cp1257",
"windows-1257",
"x-cp1257"
],
"name": "windows-1257"
},
{
"labels": [
"cp1258",
"windows-1258",
"x-cp1258"
],
"name": "windows-1258"
},
{
"labels": [
"x-mac-cyrillic",
"x-mac-ukrainian"
],
"name": "x-mac-cyrillic"
}
],
"heading": "Legacy single-byte encodings"
},
{
"encodings": [
{
"labels": [
"chinese",
"csgb2312",
"csiso58gb231280",
"gb2312",
"gb_2312",
"gb_2312-80",
"gbk",
"iso-ir-58",
"x-gbk"
],
"name": "GBK"
},
{
"labels": [
"gb18030"
],
"name": "gb18030"
}
],
"heading": "Legacy multi-byte Chinese (simplified) encodings"
},
{
"encodings": [
{
"labels": [
"big5",
"big5-hkscs",
"cn-big5",
"csbig5",
"x-x-big5"
],
"name": "Big5"
}
],
"heading": "Legacy multi-byte Chinese (traditional) encodings"
},
{
"encodings": [
{
"labels": [
"cseucpkdfmtjapanese",
"euc-jp",
"x-euc-jp"
],
"name": "EUC-JP"
},
{
"labels": [
"csiso2022jp",
"iso-2022-jp"
],
"name": "ISO-2022-JP"
},
{
"labels": [
"csshiftjis",
"ms932",
"ms_kanji",
"shift-jis",
"shift_jis",
"sjis",
"windows-31j",
"x-sjis"
],
"name": "Shift_JIS"
}
],
"heading": "Legacy multi-byte Japanese encodings"
},
{
"encodings": [
{
"labels": [
"cseuckr",
"csksc56011987",
"euc-kr",
"iso-ir-149",
"korean",
"ks_c_5601-1987",
"ks_c_5601-1989",
"ksc5601",
"ksc_5601",
"windows-949"
],
"name": "EUC-KR"
}
],
"heading": "Legacy multi-byte Korean encodings"
},
{
"encodings": [
{
"labels": [
"csiso2022kr",
"hz-gb-2312",
"iso-2022-cn",
"iso-2022-cn-ext",
"iso-2022-kr"
],
"name": "replacement"
},
{
"labels": [
"utf-16be"
],
"name": "UTF-16BE"
},
{
"labels": [
"utf-16",
"utf-16le"
],
"name": "UTF-16LE"
},
{
"labels": [
"x-user-defined"
],
"name": "x-user-defined"
}
],
"heading": "Legacy miscellaneous encodings"
}
];
// Label to encoding registry.
/** @type {Object.<string,{name:string,labels:Array.<string>}>} */
var label_to_encoding = {};
encodings.forEach(function(category) {
category.encodings.forEach(function(encoding) {
encoding.labels.forEach(function(label) {
label_to_encoding[label] = encoding;
});
});
});
// Registry of of encoder/decoder factories, by encoding name.
/** @type {Object.<string, function({fatal:boolean}): Encoder>} */
var encoders = {};
/** @type {Object.<string, function({fatal:boolean}): Decoder>} */
var decoders = {};
//
// 6. Indexes
//
/**
* @param {number} pointer The |pointer| to search for.
* @param {(!Array.<?number>|undefined)} index The |index| to search within.
* @return {?number} The code point corresponding to |pointer| in |index|,
* or null if |code point| is not in |index|.
*/
function indexCodePointFor(pointer, index) {
if (!index) return null;
return index[pointer] || null;
}
/**
* @param {number} code_point The |code point| to search for.
* @param {!Array.<?number>} index The |index| to search within.
* @return {?number} The first pointer corresponding to |code point| in
* |index|, or null if |code point| is not in |index|.
*/
function indexPointerFor(code_point, index) {
var pointer = index.indexOf(code_point);
return pointer === -1 ? null : pointer;
}
/**
* @param {string} name Name of the index.
* @return {(!Array.<number>|!Array.<Array.<number>>)}
* */
function index(name) {
if (!('encoding-indexes' in global)) {
throw Error("Indexes missing." +
" Did you forget to include encoding-indexes.js first?");
}
return global['encoding-indexes'][name];
}
/**
* @param {number} pointer The |pointer| to search for in the gb18030 index.
* @return {?number} The code point corresponding to |pointer| in |index|,
* or null if |code point| is not in the gb18030 index.
*/
function indexGB18030RangesCodePointFor(pointer) {
// 1. If pointer is greater than 39419 and less than 189000, or
// pointer is greater than 1237575, return null.
if ((pointer > 39419 && pointer < 189000) || (pointer > 1237575))
return null;
// 2. If pointer is 7457, return code point U+E7C7.
if (pointer === 7457) return 0xE7C7;
// 3. Let offset be the last pointer in index gb18030 ranges that
// is equal to or less than pointer and let code point offset be
// its corresponding code point.
var offset = 0;
var code_point_offset = 0;
var idx = index('gb18030-ranges');
var i;
for (i = 0; i < idx.length; ++i) {
/** @type {!Array.<number>} */
var entry = idx[i];
if (entry[0] <= pointer) {
offset = entry[0];
code_point_offset = entry[1];
} else {
break;
}
}
// 4. Return a code point whose value is code point offset +
// pointer − offset.
return code_point_offset + pointer - offset;
}
/**
* @param {number} code_point The |code point| to locate in the gb18030 index.
* @return {number} The first pointer corresponding to |code point| in the
* gb18030 index.
*/
function indexGB18030RangesPointerFor(code_point) {
// 1. If code point is U+E7C7, return pointer 7457.
if (code_point === 0xE7C7) return 7457;
// 2. Let offset be the last code point in index gb18030 ranges
// that is equal to or less than code point and let pointer offset
// be its corresponding pointer.
var offset = 0;
var pointer_offset = 0;
var idx = index('gb18030-ranges');
var i;
for (i = 0; i < idx.length; ++i) {
/** @type {!Array.<number>} */
var entry = idx[i];
if (entry[1] <= code_point) {
offset = entry[1];
pointer_offset = entry[0];
} else {
break;
}
}
// 3. Return a pointer whose value is pointer offset + code point
// − offset.
return pointer_offset + code_point - offset;
}
/**
* @param {number} code_point The |code_point| to search for in the Shift_JIS
* index.
* @return {?number} The code point corresponding to |pointer| in |index|,
* or null if |code point| is not in the Shift_JIS index.
*/
function indexShiftJISPointerFor(code_point) {
// 1. Let index be index jis0208 excluding all entries whose
// pointer is in the range 8272 to 8835, inclusive.
shift_jis_index = shift_jis_index ||
index('jis0208').map(function(code_point, pointer) {
return inRange(pointer, 8272, 8835) ? null : code_point;
});
var index_ = shift_jis_index;
// 2. Return the index pointer for code point in index.
return index_.indexOf(code_point);
}
var shift_jis_index;
/**
* @param {number} code_point The |code_point| to search for in the big5
* index.
* @return {?number} The code point corresponding to |pointer| in |index|,
* or null if |code point| is not in the big5 index.
*/
function indexBig5PointerFor(code_point) {
// 1. Let index be index Big5 excluding all entries whose pointer
big5_index_no_hkscs = big5_index_no_hkscs ||
index('big5').map(function(code_point, pointer) {
return (pointer < (0xA1 - 0x81) * 157) ? null : code_point;
});
var index_ = big5_index_no_hkscs;
// 2. If code point is U+2550, U+255E, U+2561, U+256A, U+5341, or
// U+5345, return the last pointer corresponding to code point in
// index.
if (code_point === 0x2550 || code_point === 0x255E ||
code_point === 0x2561 || code_point === 0x256A ||
code_point === 0x5341 || code_point === 0x5345) {
return index_.lastIndexOf(code_point);
}
// 3. Return the index pointer for code point in index.
return indexPointerFor(code_point, index_);
}
var big5_index_no_hkscs;
//
// 8. API
//
/** @const */ var DEFAULT_ENCODING = 'utf-8';
// 8.1 Interface TextDecoder
/**
* @constructor
* @param {string=} label The label of the encoding;
* defaults to 'utf-8'.
* @param {Object=} options
*/
function TextDecoder(label, options) {
// Web IDL conventions
if (!(this instanceof TextDecoder))
throw TypeError('Called as a function. Did you forget \'new\'?');
label = label !== undefined ? String(label) : DEFAULT_ENCODING;
options = ToDictionary(options);
// A TextDecoder object has an associated encoding, decoder,
// stream, ignore BOM flag (initially unset), BOM seen flag
// (initially unset), error mode (initially replacement), and do
// not flush flag (initially unset).
/** @private */
this._encoding = null;
/** @private @type {?Decoder} */
this._decoder = null;
/** @private @type {boolean} */
this._ignoreBOM = false;
/** @private @type {boolean} */
this._BOMseen = false;
/** @private @type {string} */
this._error_mode = 'replacement';
/** @private @type {boolean} */
this._do_not_flush = false;
// 1. Let encoding be the result of getting an encoding from
// label.
var encoding = getEncoding(label);
// 2. If encoding is failure or replacement, throw a RangeError.
if (encoding === null || encoding.name === 'replacement')
throw RangeError('Unknown encoding: ' + label);
if (!decoders[encoding.name]) {
throw Error('Decoder not present.' +
' Did you forget to include encoding-indexes.js first?');
}
// 3. Let dec be a new TextDecoder object.
var dec = this;
// 4. Set dec's encoding to encoding.
dec._encoding = encoding;
// 5. If options's fatal member is true, set dec's error mode to
// fatal.
if (Boolean(options['fatal']))
dec._error_mode = 'fatal';
// 6. If options's ignoreBOM member is true, set dec's ignore BOM
// flag.
if (Boolean(options['ignoreBOM']))
dec._ignoreBOM = true;
// For pre-ES5 runtimes:
if (!Object.defineProperty) {
this.encoding = dec._encoding.name.toLowerCase();
this.fatal = dec._error_mode === 'fatal';
this.ignoreBOM = dec._ignoreBOM;
}
// 7. Return dec.
return dec;
}
if (Object.defineProperty) {
// The encoding attribute's getter must return encoding's name.
Object.defineProperty(TextDecoder.prototype, 'encoding', {
/** @this {TextDecoder} */
get: function() { return this._encoding.name.toLowerCase(); }
});
// The fatal attribute's getter must return true if error mode
// is fatal, and false otherwise.
Object.defineProperty(TextDecoder.prototype, 'fatal', {
/** @this {TextDecoder} */
get: function() { return this._error_mode === 'fatal'; }
});
// The ignoreBOM attribute's getter must return true if ignore
// BOM flag is set, and false otherwise.
Object.defineProperty(TextDecoder.prototype, 'ignoreBOM', {
/** @this {TextDecoder} */
get: function() { return this._ignoreBOM; }
});
}
/**
* @param {BufferSource=} input The buffer of bytes to decode.
* @param {Object=} options
* @return {string} The decoded string.
*/
TextDecoder.prototype.decode = function decode(input, options) {
var bytes;
if (typeof input === 'object' && input instanceof ArrayBuffer) {
bytes = new Uint8Array(input);
} else if (typeof input === 'object' && 'buffer' in input &&
input.buffer instanceof ArrayBuffer) {
bytes = new Uint8Array(input.buffer,
input.byteOffset,
input.byteLength);
} else {
bytes = new Uint8Array(0);
}
options = ToDictionary(options);
// 1. If the do not flush flag is unset, set decoder to a new
// encoding's decoder, set stream to a new stream, and unset the
// BOM seen flag.
if (!this._do_not_flush) {
this._decoder = decoders[this._encoding.name]({
fatal: this._error_mode === 'fatal'});
this._BOMseen = false;
}
// 2. If options's stream is true, set the do not flush flag, and
// unset the do not flush flag otherwise.
this._do_not_flush = Boolean(options['stream']);
// 3. If input is given, push a copy of input to stream.
// TODO: Align with spec algorithm - maintain stream on instance.
var input_stream = new Stream(bytes);
// 4. Let output be a new stream.
var output = [];
/** @type {?(number|!Array.<number>)} */
var result;
// 5. While true:
while (true) {
// 1. Let token be the result of reading from stream.
var token = input_stream.read();
// 2. If token is end-of-stream and the do not flush flag is
// set, return output, serialized.
// TODO: Align with spec algorithm.
if (token === end_of_stream)
break;
// 3. Otherwise, run these subsubsteps:
// 1. Let result be the result of processing token for decoder,
// stream, output, and error mode.
result = this._decoder.handler(input_stream, token);
// 2. If result is finished, return output, serialized.
if (result === finished)
break;
if (result !== null) {
if (Array.isArray(result))
output.push.apply(output, /**@type {!Array.<number>}*/(result));
else
output.push(result);
}
// 3. Otherwise, if result is error, throw a TypeError.
// (Thrown in handler)
// 4. Otherwise, do nothing.
}
// TODO: Align with spec algorithm.
if (!this._do_not_flush) {
do {
result = this._decoder.handler(input_stream, input_stream.read());
if (result === finished)
break;
if (result === null)
continue;
if (Array.isArray(result))
output.push.apply(output, /**@type {!Array.<number>}*/(result));
else
output.push(result);
} while (!input_stream.endOfStream());
this._decoder = null;
}
// A TextDecoder object also has an associated serialize stream
// algorithm...
/**
* @param {!Array.<number>} stream
* @return {string}
* @this {TextDecoder}
*/
function serializeStream(stream) {
// 1. Let token be the result of reading from stream.
// (Done in-place on array, rather than as a stream)
// 2. If encoding is UTF-8, UTF-16BE, or UTF-16LE, and ignore
// BOM flag and BOM seen flag are unset, run these subsubsteps:
if (includes(['UTF-8', 'UTF-16LE', 'UTF-16BE'], this._encoding.name) &&
!this._ignoreBOM && !this._BOMseen) {
if (stream.length > 0 && stream[0] === 0xFEFF) {
// 1. If token is U+FEFF, set BOM seen flag.
this._BOMseen = true;
stream.shift();
} else if (stream.length > 0) {
// 2. Otherwise, if token is not end-of-stream, set BOM seen
// flag and append token to stream.
this._BOMseen = true;
} else {
// 3. Otherwise, if token is not end-of-stream, append token
// to output.
// (no-op)
}
}
// 4. Otherwise, return output.
return codePointsToString(stream);
}
return serializeStream.call(this, output);
};
// 8.2 Interface TextEncoder
/**
* @constructor
* @param {string=} label The label of the encoding. NONSTANDARD.
* @param {Object=} options NONSTANDARD.
*/
function TextEncoder(label, options) {
// Web IDL conventions
if (!(this instanceof TextEncoder))
throw TypeError('Called as a function. Did you forget \'new\'?');
options = ToDictionary(options);
// A TextEncoder object has an associated encoding and encoder.
/** @private */
this._encoding = null;
/** @private @type {?Encoder} */
this._encoder = null;
// Non-standard
/** @private @type {boolean} */
this._do_not_flush = false;
/** @private @type {string} */
this._fatal = Boolean(options['fatal']) ? 'fatal' : 'replacement';
// 1. Let enc be a new TextEncoder object.
var enc = this;
// 2. Set enc's encoding to UTF-8's encoder.
if (Boolean(options['NONSTANDARD_allowLegacyEncoding'])) {
// NONSTANDARD behavior.
label = label !== undefined ? String(label) : DEFAULT_ENCODING;
var encoding = getEncoding(label);
if (encoding === null || encoding.name === 'replacement')
throw RangeError('Unknown encoding: ' + label);
if (!encoders[encoding.name]) {
throw Error('Encoder not present.' +
' Did you forget to include encoding-indexes.js first?');
}
enc._encoding = encoding;
} else {
// Standard behavior.
enc._encoding = getEncoding('utf-8');
if (label !== undefined && 'console' in global) {
console.warn('TextEncoder constructor called with encoding label, '
+ 'which is ignored.');
}
}
// For pre-ES5 runtimes:
if (!Object.defineProperty)
this.encoding = enc._encoding.name.toLowerCase();
// 3. Return enc.
return enc;
}
if (Object.defineProperty) {
// The encoding attribute's getter must return encoding's name.
Object.defineProperty(TextEncoder.prototype, 'encoding', {
/** @this {TextEncoder} */
get: function() { return this._encoding.name.toLowerCase(); }
});
}
/**
* @param {string=} opt_string The string to encode.
* @param {Object=} options
* @return {!Uint8Array} Encoded bytes, as a Uint8Array.
*/
TextEncoder.prototype.encode = function encode(opt_string, options) {
opt_string = opt_string === undefined ? '' : String(opt_string);
options = ToDictionary(options);
// NOTE: This option is nonstandard. None of the encodings
// permitted for encoding (i.e. UTF-8, UTF-16) are stateful when
// the input is a USVString so streaming is not necessary.
if (!this._do_not_flush)
this._encoder = encoders[this._encoding.name]({
fatal: this._fatal === 'fatal'});
this._do_not_flush = Boolean(options['stream']);
// 1. Convert input to a stream.
var input = new Stream(stringToCodePoints(opt_string));
// 2. Let output be a new stream
var output = [];
/** @type {?(number|!Array.<number>)} */
var result;
// 3. While true, run these substeps:
while (true) {
// 1. Let token be the result of reading from input.
var token = input.read();
if (token === end_of_stream)
break;
// 2. Let result be the result of processing token for encoder,
// input, output.
result = this._encoder.handler(input, token);
if (result === finished)
break;
if (Array.isArray(result))
output.push.apply(output, /**@type {!Array.<number>}*/(result));
else
output.push(result);
}
// TODO: Align with spec algorithm.
if (!this._do_not_flush) {
while (true) {
result = this._encoder.handler(input, input.read());
if (result === finished)
break;
if (Array.isArray(result))
output.push.apply(output, /**@type {!Array.<number>}*/(result));
else
output.push(result);
}
this._encoder = null;
}
// 3. If result is finished, convert output into a byte sequence,
// and then return a Uint8Array object wrapping an ArrayBuffer
// containing output.
return new Uint8Array(output);
};
//
// 9. The encoding
//
// 9.1 utf-8
// 9.1.1 utf-8 decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function UTF8Decoder(options) {
var fatal = options.fatal;
// utf-8's decoder's has an associated utf-8 code point, utf-8
// bytes seen, and utf-8 bytes needed (all initially 0), a utf-8
// lower boundary (initially 0x80), and a utf-8 upper boundary
// (initially 0xBF).
var /** @type {number} */ utf8_code_point = 0,
/** @type {number} */ utf8_bytes_seen = 0,
/** @type {number} */ utf8_bytes_needed = 0,
/** @type {number} */ utf8_lower_boundary = 0x80,
/** @type {number} */ utf8_upper_boundary = 0xBF;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and utf-8 bytes needed is not 0,
// set utf-8 bytes needed to 0 and return error.
if (bite === end_of_stream && utf8_bytes_needed !== 0) {
utf8_bytes_needed = 0;
return decoderError(fatal);
}
// 2. If byte is end-of-stream, return finished.
if (bite === end_of_stream)
return finished;
// 3. If utf-8 bytes needed is 0, based on byte:
if (utf8_bytes_needed === 0) {
// 0x00 to 0x7F
if (inRange(bite, 0x00, 0x7F)) {
// Return a code point whose value is byte.
return bite;
}
// 0xC2 to 0xDF
else if (inRange(bite, 0xC2, 0xDF)) {
// 1. Set utf-8 bytes needed to 1.
utf8_bytes_needed = 1;
// 2. Set UTF-8 code point to byte & 0x1F.
utf8_code_point = bite & 0x1F;
}
// 0xE0 to 0xEF
else if (inRange(bite, 0xE0, 0xEF)) {
// 1. If byte is 0xE0, set utf-8 lower boundary to 0xA0.
if (bite === 0xE0)
utf8_lower_boundary = 0xA0;
// 2. If byte is 0xED, set utf-8 upper boundary to 0x9F.
if (bite === 0xED)
utf8_upper_boundary = 0x9F;
// 3. Set utf-8 bytes needed to 2.
utf8_bytes_needed = 2;
// 4. Set UTF-8 code point to byte & 0xF.
utf8_code_point = bite & 0xF;
}
// 0xF0 to 0xF4
else if (inRange(bite, 0xF0, 0xF4)) {
// 1. If byte is 0xF0, set utf-8 lower boundary to 0x90.
if (bite === 0xF0)
utf8_lower_boundary = 0x90;
// 2. If byte is 0xF4, set utf-8 upper boundary to 0x8F.
if (bite === 0xF4)
utf8_upper_boundary = 0x8F;
// 3. Set utf-8 bytes needed to 3.
utf8_bytes_needed = 3;
// 4. Set UTF-8 code point to byte & 0x7.
utf8_code_point = bite & 0x7;
}
// Otherwise
else {
// Return error.
return decoderError(fatal);
}
// Return continue.
return null;
}
// 4. If byte is not in the range utf-8 lower boundary to utf-8
// upper boundary, inclusive, run these substeps:
if (!inRange(bite, utf8_lower_boundary, utf8_upper_boundary)) {
// 1. Set utf-8 code point, utf-8 bytes needed, and utf-8
// bytes seen to 0, set utf-8 lower boundary to 0x80, and set
// utf-8 upper boundary to 0xBF.
utf8_code_point = utf8_bytes_needed = utf8_bytes_seen = 0;
utf8_lower_boundary = 0x80;
utf8_upper_boundary = 0xBF;
// 2. Prepend byte to stream.
stream.prepend(bite);
// 3. Return error.
return decoderError(fatal);
}
// 5. Set utf-8 lower boundary to 0x80 and utf-8 upper boundary
// to 0xBF.
utf8_lower_boundary = 0x80;
utf8_upper_boundary = 0xBF;
// 6. Set UTF-8 code point to (UTF-8 code point << 6) | (byte &
// 0x3F)
utf8_code_point = (utf8_code_point << 6) | (bite & 0x3F);
// 7. Increase utf-8 bytes seen by one.
utf8_bytes_seen += 1;
// 8. If utf-8 bytes seen is not equal to utf-8 bytes needed,
// continue.
if (utf8_bytes_seen !== utf8_bytes_needed)
return null;
// 9. Let code point be utf-8 code point.
var code_point = utf8_code_point;
// 10. Set utf-8 code point, utf-8 bytes needed, and utf-8 bytes
// seen to 0.
utf8_code_point = utf8_bytes_needed = utf8_bytes_seen = 0;
// 11. Return a code point whose value is code point.
return code_point;
};
}
// 9.1.2 utf-8 encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function UTF8Encoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. Set count and offset based on the range code point is in:
var count, offset;
// U+0080 to U+07FF, inclusive:
if (inRange(code_point, 0x0080, 0x07FF)) {
// 1 and 0xC0
count = 1;
offset = 0xC0;
}
// U+0800 to U+FFFF, inclusive:
else if (inRange(code_point, 0x0800, 0xFFFF)) {
// 2 and 0xE0
count = 2;
offset = 0xE0;
}
// U+10000 to U+10FFFF, inclusive:
else if (inRange(code_point, 0x10000, 0x10FFFF)) {
// 3 and 0xF0
count = 3;
offset = 0xF0;
}
// 4. Let bytes be a byte sequence whose first byte is (code
// point >> (6 × count)) + offset.
var bytes = [(code_point >> (6 * count)) + offset];
// 5. Run these substeps while count is greater than 0:
while (count > 0) {
// 1. Set temp to code point >> (6 × (count − 1)).
var temp = code_point >> (6 * (count - 1));
// 2. Append to bytes 0x80 | (temp & 0x3F).
bytes.push(0x80 | (temp & 0x3F));
// 3. Decrease count by one.
count -= 1;
}
// 6. Return bytes bytes, in order.
return bytes;
};
}
/** @param {{fatal: boolean}} options */
encoders['UTF-8'] = function(options) {
return new UTF8Encoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['UTF-8'] = function(options) {
return new UTF8Decoder(options);
};
//
// 10. Legacy single-byte encodings
//
// 10.1 single-byte decoder
/**
* @constructor
* @implements {Decoder}
* @param {!Array.<number>} index The encoding index.
* @param {{fatal: boolean}} options
*/
function SingleByteDecoder(index, options) {
var fatal = options.fatal;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream, return finished.
if (bite === end_of_stream)
return finished;
// 2. If byte is an ASCII byte, return a code point whose value
// is byte.
if (isASCIIByte(bite))
return bite;
// 3. Let code point be the index code point for byte − 0x80 in
// index single-byte.
var code_point = index[bite - 0x80];
// 4. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 5. Return a code point whose value is code point.
return code_point;
};
}
// 10.2 single-byte encoder
/**
* @constructor
* @implements {Encoder}
* @param {!Array.<?number>} index The encoding index.
* @param {{fatal: boolean}} options
*/
function SingleByteEncoder(index, options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. Let pointer be the index pointer for code point in index
// single-byte.
var pointer = indexPointerFor(code_point, index);
// 4. If pointer is null, return error with code point.
if (pointer === null)
encoderError(code_point);
// 5. Return a byte whose value is pointer + 0x80.
return pointer + 0x80;
};
}
(function() {
if (!('encoding-indexes' in global))
return;
encodings.forEach(function(category) {
if (category.heading !== 'Legacy single-byte encodings')
return;
category.encodings.forEach(function(encoding) {
var name = encoding.name;
var idx = index(name.toLowerCase());
/** @param {{fatal: boolean}} options */
decoders[name] = function(options) {
return new SingleByteDecoder(idx, options);
};
/** @param {{fatal: boolean}} options */
encoders[name] = function(options) {
return new SingleByteEncoder(idx, options);
};
});
});
}());
//
// 11. Legacy multi-byte Chinese (simplified) encodings
//
// 11.1 gbk
// 11.1.1 gbk decoder
// gbk's decoder is gb18030's decoder.
/** @param {{fatal: boolean}} options */
decoders['GBK'] = function(options) {
return new GB18030Decoder(options);
};
// 11.1.2 gbk encoder
// gbk's encoder is gb18030's encoder with its gbk flag set.
/** @param {{fatal: boolean}} options */
encoders['GBK'] = function(options) {
return new GB18030Encoder(options, true);
};
// 11.2 gb18030
// 11.2.1 gb18030 decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function GB18030Decoder(options) {
var fatal = options.fatal;
// gb18030's decoder has an associated gb18030 first, gb18030
// second, and gb18030 third (all initially 0x00).
var /** @type {number} */ gb18030_first = 0x00,
/** @type {number} */ gb18030_second = 0x00,
/** @type {number} */ gb18030_third = 0x00;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and gb18030 first, gb18030
// second, and gb18030 third are 0x00, return finished.
if (bite === end_of_stream && gb18030_first === 0x00 &&
gb18030_second === 0x00 && gb18030_third === 0x00) {
return finished;
}
// 2. If byte is end-of-stream, and gb18030 first, gb18030
// second, or gb18030 third is not 0x00, set gb18030 first,
// gb18030 second, and gb18030 third to 0x00, and return error.
if (bite === end_of_stream &&
(gb18030_first !== 0x00 || gb18030_second !== 0x00 ||
gb18030_third !== 0x00)) {
gb18030_first = 0x00;
gb18030_second = 0x00;
gb18030_third = 0x00;
decoderError(fatal);
}
var code_point;
// 3. If gb18030 third is not 0x00, run these substeps:
if (gb18030_third !== 0x00) {
// 1. Let code point be null.
code_point = null;
// 2. If byte is in the range 0x30 to 0x39, inclusive, set
// code point to the index gb18030 ranges code point for
// (((gb18030 first − 0x81) × 10 + gb18030 second − 0x30) ×
// 126 + gb18030 third − 0x81) × 10 + byte − 0x30.
if (inRange(bite, 0x30, 0x39)) {
code_point = indexGB18030RangesCodePointFor(
(((gb18030_first - 0x81) * 10 + gb18030_second - 0x30) * 126 +
gb18030_third - 0x81) * 10 + bite - 0x30);
}
// 3. Let buffer be a byte sequence consisting of gb18030
// second, gb18030 third, and byte, in order.
var buffer = [gb18030_second, gb18030_third, bite];
// 4. Set gb18030 first, gb18030 second, and gb18030 third to
// 0x00.
gb18030_first = 0x00;
gb18030_second = 0x00;
gb18030_third = 0x00;
// 5. If code point is null, prepend buffer to stream and
// return error.
if (code_point === null) {
stream.prepend(buffer);
return decoderError(fatal);
}
// 6. Return a code point whose value is code point.
return code_point;
}
// 4. If gb18030 second is not 0x00, run these substeps:
if (gb18030_second !== 0x00) {
// 1. If byte is in the range 0x81 to 0xFE, inclusive, set
// gb18030 third to byte and return continue.
if (inRange(bite, 0x81, 0xFE)) {
gb18030_third = bite;
return null;
}
// 2. Prepend gb18030 second followed by byte to stream, set
// gb18030 first and gb18030 second to 0x00, and return error.
stream.prepend([gb18030_second, bite]);
gb18030_first = 0x00;
gb18030_second = 0x00;
return decoderError(fatal);
}
// 5. If gb18030 first is not 0x00, run these substeps:
if (gb18030_first !== 0x00) {
// 1. If byte is in the range 0x30 to 0x39, inclusive, set
// gb18030 second to byte and return continue.
if (inRange(bite, 0x30, 0x39)) {
gb18030_second = bite;
return null;
}
// 2. Let lead be gb18030 first, let pointer be null, and set
// gb18030 first to 0x00.
var lead = gb18030_first;
var pointer = null;
gb18030_first = 0x00;
// 3. Let offset be 0x40 if byte is less than 0x7F and 0x41
// otherwise.
var offset = bite < 0x7F ? 0x40 : 0x41;
// 4. If byte is in the range 0x40 to 0x7E, inclusive, or 0x80
// to 0xFE, inclusive, set pointer to (lead − 0x81) × 190 +
// (byte − offset).
if (inRange(bite, 0x40, 0x7E) || inRange(bite, 0x80, 0xFE))
pointer = (lead - 0x81) * 190 + (bite - offset);
// 5. Let code point be null if pointer is null and the index
// code point for pointer in index gb18030 otherwise.
code_point = pointer === null ? null :
indexCodePointFor(pointer, index('gb18030'));
// 6. If code point is null and byte is an ASCII byte, prepend
// byte to stream.
if (code_point === null && isASCIIByte(bite))
stream.prepend(bite);
// 7. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 8. Return a code point whose value is code point.
return code_point;
}
// 6. If byte is an ASCII byte, return a code point whose value
// is byte.
if (isASCIIByte(bite))
return bite;
// 7. If byte is 0x80, return code point U+20AC.
if (bite === 0x80)
return 0x20AC;
// 8. If byte is in the range 0x81 to 0xFE, inclusive, set
// gb18030 first to byte and return continue.
if (inRange(bite, 0x81, 0xFE)) {
gb18030_first = bite;
return null;
}
// 9. Return error.
return decoderError(fatal);
};
}
// 11.2.2 gb18030 encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
* @param {boolean=} gbk_flag
*/
function GB18030Encoder(options, gbk_flag) {
var fatal = options.fatal;
// gb18030's decoder has an associated gbk flag (initially unset).
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. If code point is U+E5E5, return error with code point.
if (code_point === 0xE5E5)
return encoderError(code_point);
// 4. If the gbk flag is set and code point is U+20AC, return
// byte 0x80.
if (gbk_flag && code_point === 0x20AC)
return 0x80;
// 5. Let pointer be the index pointer for code point in index
// gb18030.
var pointer = indexPointerFor(code_point, index('gb18030'));
// 6. If pointer is not null, run these substeps:
if (pointer !== null) {
// 1. Let lead be floor(pointer / 190) + 0x81.
var lead = floor(pointer / 190) + 0x81;
// 2. Let trail be pointer % 190.
var trail = pointer % 190;
// 3. Let offset be 0x40 if trail is less than 0x3F and 0x41 otherwise.
var offset = trail < 0x3F ? 0x40 : 0x41;
// 4. Return two bytes whose values are lead and trail + offset.
return [lead, trail + offset];
}
// 7. If gbk flag is set, return error with code point.
if (gbk_flag)
return encoderError(code_point);
// 8. Set pointer to the index gb18030 ranges pointer for code
// point.
pointer = indexGB18030RangesPointerFor(code_point);
// 9. Let byte1 be floor(pointer / 10 / 126 / 10).
var byte1 = floor(pointer / 10 / 126 / 10);
// 10. Set pointer to pointer − byte1 × 10 × 126 × 10.
pointer = pointer - byte1 * 10 * 126 * 10;
// 11. Let byte2 be floor(pointer / 10 / 126).
var byte2 = floor(pointer / 10 / 126);
// 12. Set pointer to pointer − byte2 × 10 × 126.
pointer = pointer - byte2 * 10 * 126;
// 13. Let byte3 be floor(pointer / 10).
var byte3 = floor(pointer / 10);
// 14. Let byte4 be pointer − byte3 × 10.
var byte4 = pointer - byte3 * 10;
// 15. Return four bytes whose values are byte1 + 0x81, byte2 +
// 0x30, byte3 + 0x81, byte4 + 0x30.
return [byte1 + 0x81,
byte2 + 0x30,
byte3 + 0x81,
byte4 + 0x30];
};
}
/** @param {{fatal: boolean}} options */
encoders['gb18030'] = function(options) {
return new GB18030Encoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['gb18030'] = function(options) {
return new GB18030Decoder(options);
};
//
// 12. Legacy multi-byte Chinese (traditional) encodings
//
// 12.1 Big5
// 12.1.1 Big5 decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function Big5Decoder(options) {
var fatal = options.fatal;
// Big5's decoder has an associated Big5 lead (initially 0x00).
var /** @type {number} */ Big5_lead = 0x00;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and Big5 lead is not 0x00, set
// Big5 lead to 0x00 and return error.
if (bite === end_of_stream && Big5_lead !== 0x00) {
Big5_lead = 0x00;
return decoderError(fatal);
}
// 2. If byte is end-of-stream and Big5 lead is 0x00, return
// finished.
if (bite === end_of_stream && Big5_lead === 0x00)
return finished;
// 3. If Big5 lead is not 0x00, let lead be Big5 lead, let
// pointer be null, set Big5 lead to 0x00, and then run these
// substeps:
if (Big5_lead !== 0x00) {
var lead = Big5_lead;
var pointer = null;
Big5_lead = 0x00;
// 1. Let offset be 0x40 if byte is less than 0x7F and 0x62
// otherwise.
var offset = bite < 0x7F ? 0x40 : 0x62;
// 2. If byte is in the range 0x40 to 0x7E, inclusive, or 0xA1
// to 0xFE, inclusive, set pointer to (lead − 0x81) × 157 +
// (byte − offset).
if (inRange(bite, 0x40, 0x7E) || inRange(bite, 0xA1, 0xFE))
pointer = (lead - 0x81) * 157 + (bite - offset);
// 3. If there is a row in the table below whose first column
// is pointer, return the two code points listed in its second
// column
// Pointer | Code points
// --------+--------------
// 1133 | U+00CA U+0304
// 1135 | U+00CA U+030C
// 1164 | U+00EA U+0304
// 1166 | U+00EA U+030C
switch (pointer) {
case 1133: return [0x00CA, 0x0304];
case 1135: return [0x00CA, 0x030C];
case 1164: return [0x00EA, 0x0304];
case 1166: return [0x00EA, 0x030C];
}
// 4. Let code point be null if pointer is null and the index
// code point for pointer in index Big5 otherwise.
var code_point = (pointer === null) ? null :
indexCodePointFor(pointer, index('big5'));
// 5. If code point is null and byte is an ASCII byte, prepend
// byte to stream.
if (code_point === null && isASCIIByte(bite))
stream.prepend(bite);
// 6. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 7. Return a code point whose value is code point.
return code_point;
}
// 4. If byte is an ASCII byte, return a code point whose value
// is byte.
if (isASCIIByte(bite))
return bite;
// 5. If byte is in the range 0x81 to 0xFE, inclusive, set Big5
// lead to byte and return continue.
if (inRange(bite, 0x81, 0xFE)) {
Big5_lead = bite;
return null;
}
// 6. Return error.
return decoderError(fatal);
};
}
// 12.1.2 Big5 encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function Big5Encoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. Let pointer be the index Big5 pointer for code point.
var pointer = indexBig5PointerFor(code_point);
// 4. If pointer is null, return error with code point.
if (pointer === null)
return encoderError(code_point);
// 5. Let lead be floor(pointer / 157) + 0x81.
var lead = floor(pointer / 157) + 0x81;
// 6. If lead is less than 0xA1, return error with code point.
if (lead < 0xA1)
return encoderError(code_point);
// 7. Let trail be pointer % 157.
var trail = pointer % 157;
// 8. Let offset be 0x40 if trail is less than 0x3F and 0x62
// otherwise.
var offset = trail < 0x3F ? 0x40 : 0x62;
// Return two bytes whose values are lead and trail + offset.
return [lead, trail + offset];
};
}
/** @param {{fatal: boolean}} options */
encoders['Big5'] = function(options) {
return new Big5Encoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['Big5'] = function(options) {
return new Big5Decoder(options);
};
//
// 13. Legacy multi-byte Japanese encodings
//
// 13.1 euc-jp
// 13.1.1 euc-jp decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function EUCJPDecoder(options) {
var fatal = options.fatal;
// euc-jp's decoder has an associated euc-jp jis0212 flag
// (initially unset) and euc-jp lead (initially 0x00).
var /** @type {boolean} */ eucjp_jis0212_flag = false,
/** @type {number} */ eucjp_lead = 0x00;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and euc-jp lead is not 0x00, set
// euc-jp lead to 0x00, and return error.
if (bite === end_of_stream && eucjp_lead !== 0x00) {
eucjp_lead = 0x00;
return decoderError(fatal);
}
// 2. If byte is end-of-stream and euc-jp lead is 0x00, return
// finished.
if (bite === end_of_stream && eucjp_lead === 0x00)
return finished;
// 3. If euc-jp lead is 0x8E and byte is in the range 0xA1 to
// 0xDF, inclusive, set euc-jp lead to 0x00 and return a code
// point whose value is 0xFF61 − 0xA1 + byte.
if (eucjp_lead === 0x8E && inRange(bite, 0xA1, 0xDF)) {
eucjp_lead = 0x00;
return 0xFF61 - 0xA1 + bite;
}
// 4. If euc-jp lead is 0x8F and byte is in the range 0xA1 to
// 0xFE, inclusive, set the euc-jp jis0212 flag, set euc-jp lead
// to byte, and return continue.
if (eucjp_lead === 0x8F && inRange(bite, 0xA1, 0xFE)) {
eucjp_jis0212_flag = true;
eucjp_lead = bite;
return null;
}
// 5. If euc-jp lead is not 0x00, let lead be euc-jp lead, set
// euc-jp lead to 0x00, and run these substeps:
if (eucjp_lead !== 0x00) {
var lead = eucjp_lead;
eucjp_lead = 0x00;
// 1. Let code point be null.
var code_point = null;
// 2. If lead and byte are both in the range 0xA1 to 0xFE,
// inclusive, set code point to the index code point for (lead
// − 0xA1) × 94 + byte − 0xA1 in index jis0208 if the euc-jp
// jis0212 flag is unset and in index jis0212 otherwise.
if (inRange(lead, 0xA1, 0xFE) && inRange(bite, 0xA1, 0xFE)) {
code_point = indexCodePointFor(
(lead - 0xA1) * 94 + (bite - 0xA1),
index(!eucjp_jis0212_flag ? 'jis0208' : 'jis0212'));
}
// 3. Unset the euc-jp jis0212 flag.
eucjp_jis0212_flag = false;
// 4. If byte is not in the range 0xA1 to 0xFE, inclusive,
// prepend byte to stream.
if (!inRange(bite, 0xA1, 0xFE))
stream.prepend(bite);
// 5. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 6. Return a code point whose value is code point.
return code_point;
}
// 6. If byte is an ASCII byte, return a code point whose value
// is byte.
if (isASCIIByte(bite))
return bite;
// 7. If byte is 0x8E, 0x8F, or in the range 0xA1 to 0xFE,
// inclusive, set euc-jp lead to byte and return continue.
if (bite === 0x8E || bite === 0x8F || inRange(bite, 0xA1, 0xFE)) {
eucjp_lead = bite;
return null;
}
// 8. Return error.
return decoderError(fatal);
};
}
// 13.1.2 euc-jp encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function EUCJPEncoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. If code point is U+00A5, return byte 0x5C.
if (code_point === 0x00A5)
return 0x5C;
// 4. If code point is U+203E, return byte 0x7E.
if (code_point === 0x203E)
return 0x7E;
// 5. If code point is in the range U+FF61 to U+FF9F, inclusive,
// return two bytes whose values are 0x8E and code point −
// 0xFF61 + 0xA1.
if (inRange(code_point, 0xFF61, 0xFF9F))
return [0x8E, code_point - 0xFF61 + 0xA1];
// 6. If code point is U+2212, set it to U+FF0D.
if (code_point === 0x2212)
code_point = 0xFF0D;
// 7. Let pointer be the index pointer for code point in index
// jis0208.
var pointer = indexPointerFor(code_point, index('jis0208'));
// 8. If pointer is null, return error with code point.
if (pointer === null)
return encoderError(code_point);
// 9. Let lead be floor(pointer / 94) + 0xA1.
var lead = floor(pointer / 94) + 0xA1;
// 10. Let trail be pointer % 94 + 0xA1.
var trail = pointer % 94 + 0xA1;
// 11. Return two bytes whose values are lead and trail.
return [lead, trail];
};
}
/** @param {{fatal: boolean}} options */
encoders['EUC-JP'] = function(options) {
return new EUCJPEncoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['EUC-JP'] = function(options) {
return new EUCJPDecoder(options);
};
// 13.2 iso-2022-jp
// 13.2.1 iso-2022-jp decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function ISO2022JPDecoder(options) {
var fatal = options.fatal;
/** @enum */
var states = {
ASCII: 0,
Roman: 1,
Katakana: 2,
LeadByte: 3,
TrailByte: 4,
EscapeStart: 5,
Escape: 6
};
// iso-2022-jp's decoder has an associated iso-2022-jp decoder
// state (initially ASCII), iso-2022-jp decoder output state
// (initially ASCII), iso-2022-jp lead (initially 0x00), and
// iso-2022-jp output flag (initially unset).
var /** @type {number} */ iso2022jp_decoder_state = states.ASCII,
/** @type {number} */ iso2022jp_decoder_output_state = states.ASCII,
/** @type {number} */ iso2022jp_lead = 0x00,
/** @type {boolean} */ iso2022jp_output_flag = false;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// switching on iso-2022-jp decoder state:
switch (iso2022jp_decoder_state) {
default:
case states.ASCII:
// ASCII
// Based on byte:
// 0x1B
if (bite === 0x1B) {
// Set iso-2022-jp decoder state to escape start and return
// continue.
iso2022jp_decoder_state = states.EscapeStart;
return null;
}
// 0x00 to 0x7F, excluding 0x0E, 0x0F, and 0x1B
if (inRange(bite, 0x00, 0x7F) && bite !== 0x0E
&& bite !== 0x0F && bite !== 0x1B) {
// Unset the iso-2022-jp output flag and return a code point
// whose value is byte.
iso2022jp_output_flag = false;
return bite;
}
// end-of-stream
if (bite === end_of_stream) {
// Return finished.
return finished;
}
// Otherwise
// Unset the iso-2022-jp output flag and return error.
iso2022jp_output_flag = false;
return decoderError(fatal);
case states.Roman:
// Roman
// Based on byte:
// 0x1B
if (bite === 0x1B) {
// Set iso-2022-jp decoder state to escape start and return
// continue.
iso2022jp_decoder_state = states.EscapeStart;
return null;
}
// 0x5C
if (bite === 0x5C) {
// Unset the iso-2022-jp output flag and return code point
// U+00A5.
iso2022jp_output_flag = false;
return 0x00A5;
}
// 0x7E
if (bite === 0x7E) {
// Unset the iso-2022-jp output flag and return code point
// U+203E.
iso2022jp_output_flag = false;
return 0x203E;
}
// 0x00 to 0x7F, excluding 0x0E, 0x0F, 0x1B, 0x5C, and 0x7E
if (inRange(bite, 0x00, 0x7F) && bite !== 0x0E && bite !== 0x0F
&& bite !== 0x1B && bite !== 0x5C && bite !== 0x7E) {
// Unset the iso-2022-jp output flag and return a code point
// whose value is byte.
iso2022jp_output_flag = false;
return bite;
}
// end-of-stream
if (bite === end_of_stream) {
// Return finished.
return finished;
}
// Otherwise
// Unset the iso-2022-jp output flag and return error.
iso2022jp_output_flag = false;
return decoderError(fatal);
case states.Katakana:
// Katakana
// Based on byte:
// 0x1B
if (bite === 0x1B) {
// Set iso-2022-jp decoder state to escape start and return
// continue.
iso2022jp_decoder_state = states.EscapeStart;
return null;
}
// 0x21 to 0x5F
if (inRange(bite, 0x21, 0x5F)) {
// Unset the iso-2022-jp output flag and return a code point
// whose value is 0xFF61 − 0x21 + byte.
iso2022jp_output_flag = false;
return 0xFF61 - 0x21 + bite;
}
// end-of-stream
if (bite === end_of_stream) {
// Return finished.
return finished;
}
// Otherwise
// Unset the iso-2022-jp output flag and return error.
iso2022jp_output_flag = false;
return decoderError(fatal);
case states.LeadByte:
// Lead byte
// Based on byte:
// 0x1B
if (bite === 0x1B) {
// Set iso-2022-jp decoder state to escape start and return
// continue.
iso2022jp_decoder_state = states.EscapeStart;
return null;
}
// 0x21 to 0x7E
if (inRange(bite, 0x21, 0x7E)) {
// Unset the iso-2022-jp output flag, set iso-2022-jp lead
// to byte, iso-2022-jp decoder state to trail byte, and
// return continue.
iso2022jp_output_flag = false;
iso2022jp_lead = bite;
iso2022jp_decoder_state = states.TrailByte;
return null;
}
// end-of-stream
if (bite === end_of_stream) {
// Return finished.
return finished;
}
// Otherwise
// Unset the iso-2022-jp output flag and return error.
iso2022jp_output_flag = false;
return decoderError(fatal);
case states.TrailByte:
// Trail byte
// Based on byte:
// 0x1B
if (bite === 0x1B) {
// Set iso-2022-jp decoder state to escape start and return
// continue.
iso2022jp_decoder_state = states.EscapeStart;
return decoderError(fatal);
}
// 0x21 to 0x7E
if (inRange(bite, 0x21, 0x7E)) {
// 1. Set the iso-2022-jp decoder state to lead byte.
iso2022jp_decoder_state = states.LeadByte;
// 2. Let pointer be (iso-2022-jp lead − 0x21) × 94 + byte − 0x21.
var pointer = (iso2022jp_lead - 0x21) * 94 + bite - 0x21;
// 3. Let code point be the index code point for pointer in
// index jis0208.
var code_point = indexCodePointFor(pointer, index('jis0208'));
// 4. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 5. Return a code point whose value is code point.
return code_point;
}
// end-of-stream
if (bite === end_of_stream) {
// Set the iso-2022-jp decoder state to lead byte, prepend
// byte to stream, and return error.
iso2022jp_decoder_state = states.LeadByte;
stream.prepend(bite);
return decoderError(fatal);
}
// Otherwise
// Set iso-2022-jp decoder state to lead byte and return
// error.
iso2022jp_decoder_state = states.LeadByte;
return decoderError(fatal);
case states.EscapeStart:
// Escape start
// 1. If byte is either 0x24 or 0x28, set iso-2022-jp lead to
// byte, iso-2022-jp decoder state to escape, and return
// continue.
if (bite === 0x24 || bite === 0x28) {
iso2022jp_lead = bite;
iso2022jp_decoder_state = states.Escape;
return null;
}
// 2. Prepend byte to stream.
stream.prepend(bite);
// 3. Unset the iso-2022-jp output flag, set iso-2022-jp
// decoder state to iso-2022-jp decoder output state, and
// return error.
iso2022jp_output_flag = false;
iso2022jp_decoder_state = iso2022jp_decoder_output_state;
return decoderError(fatal);
case states.Escape:
// Escape
// 1. Let lead be iso-2022-jp lead and set iso-2022-jp lead to
// 0x00.
var lead = iso2022jp_lead;
iso2022jp_lead = 0x00;
// 2. Let state be null.
var state = null;
// 3. If lead is 0x28 and byte is 0x42, set state to ASCII.
if (lead === 0x28 && bite === 0x42)
state = states.ASCII;
// 4. If lead is 0x28 and byte is 0x4A, set state to Roman.
if (lead === 0x28 && bite === 0x4A)
state = states.Roman;
// 5. If lead is 0x28 and byte is 0x49, set state to Katakana.
if (lead === 0x28 && bite === 0x49)
state = states.Katakana;
// 6. If lead is 0x24 and byte is either 0x40 or 0x42, set
// state to lead byte.
if (lead === 0x24 && (bite === 0x40 || bite === 0x42))
state = states.LeadByte;
// 7. If state is non-null, run these substeps:
if (state !== null) {
// 1. Set iso-2022-jp decoder state and iso-2022-jp decoder
// output state to states.
iso2022jp_decoder_state = iso2022jp_decoder_state = state;
// 2. Let output flag be the iso-2022-jp output flag.
var output_flag = iso2022jp_output_flag;
// 3. Set the iso-2022-jp output flag.
iso2022jp_output_flag = true;
// 4. Return continue, if output flag is unset, and error
// otherwise.
return !output_flag ? null : decoderError(fatal);
}
// 8. Prepend lead and byte to stream.
stream.prepend([lead, bite]);
// 9. Unset the iso-2022-jp output flag, set iso-2022-jp
// decoder state to iso-2022-jp decoder output state and
// return error.
iso2022jp_output_flag = false;
iso2022jp_decoder_state = iso2022jp_decoder_output_state;
return decoderError(fatal);
}
};
}
// 13.2.2 iso-2022-jp encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function ISO2022JPEncoder(options) {
var fatal = options.fatal;
// iso-2022-jp's encoder has an associated iso-2022-jp encoder
// state which is one of ASCII, Roman, and jis0208 (initially
// ASCII).
/** @enum */
var states = {
ASCII: 0,
Roman: 1,
jis0208: 2
};
var /** @type {number} */ iso2022jp_state = states.ASCII;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream and iso-2022-jp encoder
// state is not ASCII, prepend code point to stream, set
// iso-2022-jp encoder state to ASCII, and return three bytes
// 0x1B 0x28 0x42.
if (code_point === end_of_stream &&
iso2022jp_state !== states.ASCII) {
stream.prepend(code_point);
iso2022jp_state = states.ASCII;
return [0x1B, 0x28, 0x42];
}
// 2. If code point is end-of-stream and iso-2022-jp encoder
// state is ASCII, return finished.
if (code_point === end_of_stream && iso2022jp_state === states.ASCII)
return finished;
// 3. If ISO-2022-JP encoder state is ASCII or Roman, and code
// point is U+000E, U+000F, or U+001B, return error with U+FFFD.
if ((iso2022jp_state === states.ASCII ||
iso2022jp_state === states.Roman) &&
(code_point === 0x000E || code_point === 0x000F ||
code_point === 0x001B)) {
return encoderError(0xFFFD);
}
// 4. If iso-2022-jp encoder state is ASCII and code point is an
// ASCII code point, return a byte whose value is code point.
if (iso2022jp_state === states.ASCII &&
isASCIICodePoint(code_point))
return code_point;
// 5. If iso-2022-jp encoder state is Roman and code point is an
// ASCII code point, excluding U+005C and U+007E, or is U+00A5
// or U+203E, run these substeps:
if (iso2022jp_state === states.Roman &&
((isASCIICodePoint(code_point) &&
code_point !== 0x005C && code_point !== 0x007E) ||
(code_point == 0x00A5 || code_point == 0x203E))) {
// 1. If code point is an ASCII code point, return a byte
// whose value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 2. If code point is U+00A5, return byte 0x5C.
if (code_point === 0x00A5)
return 0x5C;
// 3. If code point is U+203E, return byte 0x7E.
if (code_point === 0x203E)
return 0x7E;
}
// 6. If code point is an ASCII code point, and iso-2022-jp
// encoder state is not ASCII, prepend code point to stream, set
// iso-2022-jp encoder state to ASCII, and return three bytes
// 0x1B 0x28 0x42.
if (isASCIICodePoint(code_point) &&
iso2022jp_state !== states.ASCII) {
stream.prepend(code_point);
iso2022jp_state = states.ASCII;
return [0x1B, 0x28, 0x42];
}
// 7. If code point is either U+00A5 or U+203E, and iso-2022-jp
// encoder state is not Roman, prepend code point to stream, set
// iso-2022-jp encoder state to Roman, and return three bytes
// 0x1B 0x28 0x4A.
if ((code_point === 0x00A5 || code_point === 0x203E) &&
iso2022jp_state !== states.Roman) {
stream.prepend(code_point);
iso2022jp_state = states.Roman;
return [0x1B, 0x28, 0x4A];
}
// 8. If code point is U+2212, set it to U+FF0D.
if (code_point === 0x2212)
code_point = 0xFF0D;
// 9. Let pointer be the index pointer for code point in index
// jis0208.
var pointer = indexPointerFor(code_point, index('jis0208'));
// 10. If pointer is null, return error with code point.
if (pointer === null)
return encoderError(code_point);
// 11. If iso-2022-jp encoder state is not jis0208, prepend code
// point to stream, set iso-2022-jp encoder state to jis0208,
// and return three bytes 0x1B 0x24 0x42.
if (iso2022jp_state !== states.jis0208) {
stream.prepend(code_point);
iso2022jp_state = states.jis0208;
return [0x1B, 0x24, 0x42];
}
// 12. Let lead be floor(pointer / 94) + 0x21.
var lead = floor(pointer / 94) + 0x21;
// 13. Let trail be pointer % 94 + 0x21.
var trail = pointer % 94 + 0x21;
// 14. Return two bytes whose values are lead and trail.
return [lead, trail];
};
}
/** @param {{fatal: boolean}} options */
encoders['ISO-2022-JP'] = function(options) {
return new ISO2022JPEncoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['ISO-2022-JP'] = function(options) {
return new ISO2022JPDecoder(options);
};
// 13.3 Shift_JIS
// 13.3.1 Shift_JIS decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function ShiftJISDecoder(options) {
var fatal = options.fatal;
// Shift_JIS's decoder has an associated Shift_JIS lead (initially
// 0x00).
var /** @type {number} */ Shift_JIS_lead = 0x00;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and Shift_JIS lead is not 0x00,
// set Shift_JIS lead to 0x00 and return error.
if (bite === end_of_stream && Shift_JIS_lead !== 0x00) {
Shift_JIS_lead = 0x00;
return decoderError(fatal);
}
// 2. If byte is end-of-stream and Shift_JIS lead is 0x00,
// return finished.
if (bite === end_of_stream && Shift_JIS_lead === 0x00)
return finished;
// 3. If Shift_JIS lead is not 0x00, let lead be Shift_JIS lead,
// let pointer be null, set Shift_JIS lead to 0x00, and then run
// these substeps:
if (Shift_JIS_lead !== 0x00) {
var lead = Shift_JIS_lead;
var pointer = null;
Shift_JIS_lead = 0x00;
// 1. Let offset be 0x40, if byte is less than 0x7F, and 0x41
// otherwise.
var offset = (bite < 0x7F) ? 0x40 : 0x41;
// 2. Let lead offset be 0x81, if lead is less than 0xA0, and
// 0xC1 otherwise.
var lead_offset = (lead < 0xA0) ? 0x81 : 0xC1;
// 3. If byte is in the range 0x40 to 0x7E, inclusive, or 0x80
// to 0xFC, inclusive, set pointer to (lead − lead offset) ×
// 188 + byte − offset.
if (inRange(bite, 0x40, 0x7E) || inRange(bite, 0x80, 0xFC))
pointer = (lead - lead_offset) * 188 + bite - offset;
// 4. If pointer is in the range 8836 to 10715, inclusive,
// return a code point whose value is 0xE000 − 8836 + pointer.
if (inRange(pointer, 8836, 10715))
return 0xE000 - 8836 + pointer;
// 5. Let code point be null, if pointer is null, and the
// index code point for pointer in index jis0208 otherwise.
var code_point = (pointer === null) ? null :
indexCodePointFor(pointer, index('jis0208'));
// 6. If code point is null and byte is an ASCII byte, prepend
// byte to stream.
if (code_point === null && isASCIIByte(bite))
stream.prepend(bite);
// 7. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 8. Return a code point whose value is code point.
return code_point;
}
// 4. If byte is an ASCII byte or 0x80, return a code point
// whose value is byte.
if (isASCIIByte(bite) || bite === 0x80)
return bite;
// 5. If byte is in the range 0xA1 to 0xDF, inclusive, return a
// code point whose value is 0xFF61 − 0xA1 + byte.
if (inRange(bite, 0xA1, 0xDF))
return 0xFF61 - 0xA1 + bite;
// 6. If byte is in the range 0x81 to 0x9F, inclusive, or 0xE0
// to 0xFC, inclusive, set Shift_JIS lead to byte and return
// continue.
if (inRange(bite, 0x81, 0x9F) || inRange(bite, 0xE0, 0xFC)) {
Shift_JIS_lead = bite;
return null;
}
// 7. Return error.
return decoderError(fatal);
};
}
// 13.3.2 Shift_JIS encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function ShiftJISEncoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point or U+0080, return a
// byte whose value is code point.
if (isASCIICodePoint(code_point) || code_point === 0x0080)
return code_point;
// 3. If code point is U+00A5, return byte 0x5C.
if (code_point === 0x00A5)
return 0x5C;
// 4. If code point is U+203E, return byte 0x7E.
if (code_point === 0x203E)
return 0x7E;
// 5. If code point is in the range U+FF61 to U+FF9F, inclusive,
// return a byte whose value is code point − 0xFF61 + 0xA1.
if (inRange(code_point, 0xFF61, 0xFF9F))
return code_point - 0xFF61 + 0xA1;
// 6. If code point is U+2212, set it to U+FF0D.
if (code_point === 0x2212)
code_point = 0xFF0D;
// 7. Let pointer be the index Shift_JIS pointer for code point.
var pointer = indexShiftJISPointerFor(code_point);
// 8. If pointer is null, return error with code point.
if (pointer === null)
return encoderError(code_point);
// 9. Let lead be floor(pointer / 188).
var lead = floor(pointer / 188);
// 10. Let lead offset be 0x81, if lead is less than 0x1F, and
// 0xC1 otherwise.
var lead_offset = (lead < 0x1F) ? 0x81 : 0xC1;
// 11. Let trail be pointer % 188.
var trail = pointer % 188;
// 12. Let offset be 0x40, if trail is less than 0x3F, and 0x41
// otherwise.
var offset = (trail < 0x3F) ? 0x40 : 0x41;
// 13. Return two bytes whose values are lead + lead offset and
// trail + offset.
return [lead + lead_offset, trail + offset];
};
}
/** @param {{fatal: boolean}} options */
encoders['Shift_JIS'] = function(options) {
return new ShiftJISEncoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['Shift_JIS'] = function(options) {
return new ShiftJISDecoder(options);
};
//
// 14. Legacy multi-byte Korean encodings
//
// 14.1 euc-kr
// 14.1.1 euc-kr decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function EUCKRDecoder(options) {
var fatal = options.fatal;
// euc-kr's decoder has an associated euc-kr lead (initially 0x00).
var /** @type {number} */ euckr_lead = 0x00;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and euc-kr lead is not 0x00, set
// euc-kr lead to 0x00 and return error.
if (bite === end_of_stream && euckr_lead !== 0) {
euckr_lead = 0x00;
return decoderError(fatal);
}
// 2. If byte is end-of-stream and euc-kr lead is 0x00, return
// finished.
if (bite === end_of_stream && euckr_lead === 0)
return finished;
// 3. If euc-kr lead is not 0x00, let lead be euc-kr lead, let
// pointer be null, set euc-kr lead to 0x00, and then run these
// substeps:
if (euckr_lead !== 0x00) {
var lead = euckr_lead;
var pointer = null;
euckr_lead = 0x00;
// 1. If byte is in the range 0x41 to 0xFE, inclusive, set
// pointer to (lead − 0x81) × 190 + (byte − 0x41).
if (inRange(bite, 0x41, 0xFE))
pointer = (lead - 0x81) * 190 + (bite - 0x41);
// 2. Let code point be null, if pointer is null, and the
// index code point for pointer in index euc-kr otherwise.
var code_point = (pointer === null)
? null : indexCodePointFor(pointer, index('euc-kr'));
// 3. If code point is null and byte is an ASCII byte, prepend
// byte to stream.
if (pointer === null && isASCIIByte(bite))
stream.prepend(bite);
// 4. If code point is null, return error.
if (code_point === null)
return decoderError(fatal);
// 5. Return a code point whose value is code point.
return code_point;
}
// 4. If byte is an ASCII byte, return a code point whose value
// is byte.
if (isASCIIByte(bite))
return bite;
// 5. If byte is in the range 0x81 to 0xFE, inclusive, set
// euc-kr lead to byte and return continue.
if (inRange(bite, 0x81, 0xFE)) {
euckr_lead = bite;
return null;
}
// 6. Return error.
return decoderError(fatal);
};
}
// 14.1.2 euc-kr encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function EUCKREncoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. Let pointer be the index pointer for code point in index
// euc-kr.
var pointer = indexPointerFor(code_point, index('euc-kr'));
// 4. If pointer is null, return error with code point.
if (pointer === null)
return encoderError(code_point);
// 5. Let lead be floor(pointer / 190) + 0x81.
var lead = floor(pointer / 190) + 0x81;
// 6. Let trail be pointer % 190 + 0x41.
var trail = (pointer % 190) + 0x41;
// 7. Return two bytes whose values are lead and trail.
return [lead, trail];
};
}
/** @param {{fatal: boolean}} options */
encoders['EUC-KR'] = function(options) {
return new EUCKREncoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['EUC-KR'] = function(options) {
return new EUCKRDecoder(options);
};
//
// 15. Legacy miscellaneous encodings
//
// 15.1 replacement
// Not needed - API throws RangeError
// 15.2 Common infrastructure for utf-16be and utf-16le
/**
* @param {number} code_unit
* @param {boolean} utf16be
* @return {!Array.<number>} bytes
*/
function convertCodeUnitToBytes(code_unit, utf16be) {
// 1. Let byte1 be code unit >> 8.
var byte1 = code_unit >> 8;
// 2. Let byte2 be code unit & 0x00FF.
var byte2 = code_unit & 0x00FF;
// 3. Then return the bytes in order:
// utf-16be flag is set: byte1, then byte2.
if (utf16be)
return [byte1, byte2];
// utf-16be flag is unset: byte2, then byte1.
return [byte2, byte1];
}
// 15.2.1 shared utf-16 decoder
/**
* @constructor
* @implements {Decoder}
* @param {boolean} utf16_be True if big-endian, false if little-endian.
* @param {{fatal: boolean}} options
*/
function UTF16Decoder(utf16_be, options) {
var fatal = options.fatal;
var /** @type {?number} */ utf16_lead_byte = null,
/** @type {?number} */ utf16_lead_surrogate = null;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream and either utf-16 lead byte or
// utf-16 lead surrogate is not null, set utf-16 lead byte and
// utf-16 lead surrogate to null, and return error.
if (bite === end_of_stream && (utf16_lead_byte !== null ||
utf16_lead_surrogate !== null)) {
return decoderError(fatal);
}
// 2. If byte is end-of-stream and utf-16 lead byte and utf-16
// lead surrogate are null, return finished.
if (bite === end_of_stream && utf16_lead_byte === null &&
utf16_lead_surrogate === null) {
return finished;
}
// 3. If utf-16 lead byte is null, set utf-16 lead byte to byte
// and return continue.
if (utf16_lead_byte === null) {
utf16_lead_byte = bite;
return null;
}
// 4. Let code unit be the result of:
var code_unit;
if (utf16_be) {
// utf-16be decoder flag is set
// (utf-16 lead byte << 8) + byte.
code_unit = (utf16_lead_byte << 8) + bite;
} else {
// utf-16be decoder flag is unset
// (byte << 8) + utf-16 lead byte.
code_unit = (bite << 8) + utf16_lead_byte;
}
// Then set utf-16 lead byte to null.
utf16_lead_byte = null;
// 5. If utf-16 lead surrogate is not null, let lead surrogate
// be utf-16 lead surrogate, set utf-16 lead surrogate to null,
// and then run these substeps:
if (utf16_lead_surrogate !== null) {
var lead_surrogate = utf16_lead_surrogate;
utf16_lead_surrogate = null;
// 1. If code unit is in the range U+DC00 to U+DFFF,
// inclusive, return a code point whose value is 0x10000 +
// ((lead surrogate − 0xD800) << 10) + (code unit − 0xDC00).
if (inRange(code_unit, 0xDC00, 0xDFFF)) {
return 0x10000 + (lead_surrogate - 0xD800) * 0x400 +
(code_unit - 0xDC00);
}
// 2. Prepend the sequence resulting of converting code unit
// to bytes using utf-16be decoder flag to stream and return
// error.
stream.prepend(convertCodeUnitToBytes(code_unit, utf16_be));
return decoderError(fatal);
}
// 6. If code unit is in the range U+D800 to U+DBFF, inclusive,
// set utf-16 lead surrogate to code unit and return continue.
if (inRange(code_unit, 0xD800, 0xDBFF)) {
utf16_lead_surrogate = code_unit;
return null;
}
// 7. If code unit is in the range U+DC00 to U+DFFF, inclusive,
// return error.
if (inRange(code_unit, 0xDC00, 0xDFFF))
return decoderError(fatal);
// 8. Return code point code unit.
return code_unit;
};
}
// 15.2.2 shared utf-16 encoder
/**
* @constructor
* @implements {Encoder}
* @param {boolean} utf16_be True if big-endian, false if little-endian.
* @param {{fatal: boolean}} options
*/
function UTF16Encoder(utf16_be, options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1. If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is in the range U+0000 to U+FFFF, inclusive,
// return the sequence resulting of converting code point to
// bytes using utf-16be encoder flag.
if (inRange(code_point, 0x0000, 0xFFFF))
return convertCodeUnitToBytes(code_point, utf16_be);
// 3. Let lead be ((code point − 0x10000) >> 10) + 0xD800,
// converted to bytes using utf-16be encoder flag.
var lead = convertCodeUnitToBytes(
((code_point - 0x10000) >> 10) + 0xD800, utf16_be);
// 4. Let trail be ((code point − 0x10000) & 0x3FF) + 0xDC00,
// converted to bytes using utf-16be encoder flag.
var trail = convertCodeUnitToBytes(
((code_point - 0x10000) & 0x3FF) + 0xDC00, utf16_be);
// 5. Return a byte sequence of lead followed by trail.
return lead.concat(trail);
};
}
// 15.3 utf-16be
// 15.3.1 utf-16be decoder
/** @param {{fatal: boolean}} options */
encoders['UTF-16BE'] = function(options) {
return new UTF16Encoder(true, options);
};
// 15.3.2 utf-16be encoder
/** @param {{fatal: boolean}} options */
decoders['UTF-16BE'] = function(options) {
return new UTF16Decoder(true, options);
};
// 15.4 utf-16le
// 15.4.1 utf-16le decoder
/** @param {{fatal: boolean}} options */
encoders['UTF-16LE'] = function(options) {
return new UTF16Encoder(false, options);
};
// 15.4.2 utf-16le encoder
/** @param {{fatal: boolean}} options */
decoders['UTF-16LE'] = function(options) {
return new UTF16Decoder(false, options);
};
// 15.5 x-user-defined
// 15.5.1 x-user-defined decoder
/**
* @constructor
* @implements {Decoder}
* @param {{fatal: boolean}} options
*/
function XUserDefinedDecoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream The stream of bytes being decoded.
* @param {number} bite The next byte read from the stream.
* @return {?(number|!Array.<number>)} The next code point(s)
* decoded, or null if not enough data exists in the input
* stream to decode a complete code point.
*/
this.handler = function(stream, bite) {
// 1. If byte is end-of-stream, return finished.
if (bite === end_of_stream)
return finished;
// 2. If byte is an ASCII byte, return a code point whose value
// is byte.
if (isASCIIByte(bite))
return bite;
// 3. Return a code point whose value is 0xF780 + byte − 0x80.
return 0xF780 + bite - 0x80;
};
}
// 15.5.2 x-user-defined encoder
/**
* @constructor
* @implements {Encoder}
* @param {{fatal: boolean}} options
*/
function XUserDefinedEncoder(options) {
var fatal = options.fatal;
/**
* @param {Stream} stream Input stream.
* @param {number} code_point Next code point read from the stream.
* @return {(number|!Array.<number>)} Byte(s) to emit.
*/
this.handler = function(stream, code_point) {
// 1.If code point is end-of-stream, return finished.
if (code_point === end_of_stream)
return finished;
// 2. If code point is an ASCII code point, return a byte whose
// value is code point.
if (isASCIICodePoint(code_point))
return code_point;
// 3. If code point is in the range U+F780 to U+F7FF, inclusive,
// return a byte whose value is code point − 0xF780 + 0x80.
if (inRange(code_point, 0xF780, 0xF7FF))
return code_point - 0xF780 + 0x80;
// 4. Return error with code point.
return encoderError(code_point);
};
}
/** @param {{fatal: boolean}} options */
encoders['x-user-defined'] = function(options) {
return new XUserDefinedEncoder(options);
};
/** @param {{fatal: boolean}} options */
decoders['x-user-defined'] = function(options) {
return new XUserDefinedDecoder(options);
};
if (!global['TextEncoder'])
global['TextEncoder'] = TextEncoder;
if (!global['TextDecoder'])
global['TextDecoder'] = TextDecoder;
if (typeof module !== "undefined" && module.exports) {
module.exports = {
TextEncoder: global['TextEncoder'],
TextDecoder: global['TextDecoder'],
EncodingIndexes: global["encoding-indexes"]
};
}
// For strict environments where `this` inside the global scope
// is `undefined`, take a pure object instead
}(this || {}));
text-encoding/encoding-indexes:文件内容太多放不下了
(function(global) {
'use strict';
if (typeof module !== "undefined" && module.exports) {
module.exports = global;
}
global["encoding-indexes"] =
{
"gb18030":[]
}
}(this || {}));
gb18030:是一个汉字编码集
注:
1、连接的蓝牙必须是低功耗的蓝牙,经典蓝牙无法搜索到(因为不能执行uni.onBluetoothDeviceFound)
2、部分手机需要将定位打开才能搜索到蓝牙(开启定位才能执行uni.onBluetoothDeviceFound)
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