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gsi_ess_mobile/node_modules/@protobufjs/float/index.js

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  1. "use strict";
  3. module.exports = factory(factory);
  5. /**
  6. * Reads / writes floats / doubles from / to buffers.
  7. * @name util.float
  8. * @namespace
  9. */
  11. /**
  12. * Writes a 32 bit float to a buffer using little endian byte order.
  13. * @name util.float.writeFloatLE
  14. * @function
  15. * @param {number} val Value to write
  16. * @param {Uint8Array} buf Target buffer
  17. * @param {number} pos Target buffer offset
  18. * @returns {undefined}
  19. */
  21. /**
  22. * Writes a 32 bit float to a buffer using big endian byte order.
  23. * @name util.float.writeFloatBE
  24. * @function
  25. * @param {number} val Value to write
  26. * @param {Uint8Array} buf Target buffer
  27. * @param {number} pos Target buffer offset
  28. * @returns {undefined}
  29. */
  31. /**
  32. * Reads a 32 bit float from a buffer using little endian byte order.
  33. * @name util.float.readFloatLE
  34. * @function
  35. * @param {Uint8Array} buf Source buffer
  36. * @param {number} pos Source buffer offset
  37. * @returns {number} Value read
  38. */
  40. /**
  41. * Reads a 32 bit float from a buffer using big endian byte order.
  42. * @name util.float.readFloatBE
  43. * @function
  44. * @param {Uint8Array} buf Source buffer
  45. * @param {number} pos Source buffer offset
  46. * @returns {number} Value read
  47. */
  49. /**
  50. * Writes a 64 bit double to a buffer using little endian byte order.
  51. * @name util.float.writeDoubleLE
  52. * @function
  53. * @param {number} val Value to write
  54. * @param {Uint8Array} buf Target buffer
  55. * @param {number} pos Target buffer offset
  56. * @returns {undefined}
  57. */
  59. /**
  60. * Writes a 64 bit double to a buffer using big endian byte order.
  61. * @name util.float.writeDoubleBE
  62. * @function
  63. * @param {number} val Value to write
  64. * @param {Uint8Array} buf Target buffer
  65. * @param {number} pos Target buffer offset
  66. * @returns {undefined}
  67. */
  69. /**
  70. * Reads a 64 bit double from a buffer using little endian byte order.
  71. * @name util.float.readDoubleLE
  72. * @function
  73. * @param {Uint8Array} buf Source buffer
  74. * @param {number} pos Source buffer offset
  75. * @returns {number} Value read
  76. */
  78. /**
  79. * Reads a 64 bit double from a buffer using big endian byte order.
  80. * @name util.float.readDoubleBE
  81. * @function
  82. * @param {Uint8Array} buf Source buffer
  83. * @param {number} pos Source buffer offset
  84. * @returns {number} Value read
  85. */
  87. // Factory function for the purpose of node-based testing in modified global environments
  88. function factory(exports) {
  90. // float: typed array
  91. if (typeof Float32Array !== "undefined") (function() {
  93. var f32 = new Float32Array([ -0 ]),
  94. f8b = new Uint8Array(f32.buffer),
  95. le = f8b[3] === 128;
  97. function writeFloat_f32_cpy(val, buf, pos) {
  98. f32[0] = val;
  99. buf[pos ] = f8b[0];
  100. buf[pos + 1] = f8b[1];
  101. buf[pos + 2] = f8b[2];
  102. buf[pos + 3] = f8b[3];
  103. }
  105. function writeFloat_f32_rev(val, buf, pos) {
  106. f32[0] = val;
  107. buf[pos ] = f8b[3];
  108. buf[pos + 1] = f8b[2];
  109. buf[pos + 2] = f8b[1];
  110. buf[pos + 3] = f8b[0];
  111. }
  113. /* istanbul ignore next */
  114. exports.writeFloatLE = le ? writeFloat_f32_cpy : writeFloat_f32_rev;
  115. /* istanbul ignore next */
  116. exports.writeFloatBE = le ? writeFloat_f32_rev : writeFloat_f32_cpy;
  118. function readFloat_f32_cpy(buf, pos) {
  119. f8b[0] = buf[pos ];
  120. f8b[1] = buf[pos + 1];
  121. f8b[2] = buf[pos + 2];
  122. f8b[3] = buf[pos + 3];
  123. return f32[0];
  124. }
  126. function readFloat_f32_rev(buf, pos) {
  127. f8b[3] = buf[pos ];
  128. f8b[2] = buf[pos + 1];
  129. f8b[1] = buf[pos + 2];
  130. f8b[0] = buf[pos + 3];
  131. return f32[0];
  132. }
  134. /* istanbul ignore next */
  135. exports.readFloatLE = le ? readFloat_f32_cpy : readFloat_f32_rev;
  136. /* istanbul ignore next */
  137. exports.readFloatBE = le ? readFloat_f32_rev : readFloat_f32_cpy;
  139. // float: ieee754
  140. })(); else (function() {
  142. function writeFloat_ieee754(writeUint, val, buf, pos) {
  143. var sign = val < 0 ? 1 : 0;
  144. if (sign)
  145. val = -val;
  146. if (val === 0)
  147. writeUint(1 / val > 0 ? /* positive */ 0 : /* negative 0 */ 2147483648, buf, pos);
  148. else if (isNaN(val))
  149. writeUint(2143289344, buf, pos);
  150. else if (val > 3.4028234663852886e+38) // +-Infinity
  151. writeUint((sign << 31 | 2139095040) >>> 0, buf, pos);
  152. else if (val < 1.1754943508222875e-38) // denormal
  153. writeUint((sign << 31 | Math.round(val / 1.401298464324817e-45)) >>> 0, buf, pos);
  154. else {
  155. var exponent = Math.floor(Math.log(val) / Math.LN2),
  156. mantissa = Math.round(val * Math.pow(2, -exponent) * 8388608) & 8388607;
  157. writeUint((sign << 31 | exponent + 127 << 23 | mantissa) >>> 0, buf, pos);
  158. }
  159. }
  161. exports.writeFloatLE = writeFloat_ieee754.bind(null, writeUintLE);
  162. exports.writeFloatBE = writeFloat_ieee754.bind(null, writeUintBE);
  164. function readFloat_ieee754(readUint, buf, pos) {
  165. var uint = readUint(buf, pos),
  166. sign = (uint >> 31) * 2 + 1,
  167. exponent = uint >>> 23 & 255,
  168. mantissa = uint & 8388607;
  169. return exponent === 255
  170. ? mantissa
  171. ? NaN
  172. : sign * Infinity
  173. : exponent === 0 // denormal
  174. ? sign * 1.401298464324817e-45 * mantissa
  175. : sign * Math.pow(2, exponent - 150) * (mantissa + 8388608);
  176. }
  178. exports.readFloatLE = readFloat_ieee754.bind(null, readUintLE);
  179. exports.readFloatBE = readFloat_ieee754.bind(null, readUintBE);
  181. })();
  183. // double: typed array
  184. if (typeof Float64Array !== "undefined") (function() {
  186. var f64 = new Float64Array([-0]),
  187. f8b = new Uint8Array(f64.buffer),
  188. le = f8b[7] === 128;
  190. function writeDouble_f64_cpy(val, buf, pos) {
  191. f64[0] = val;
  192. buf[pos ] = f8b[0];
  193. buf[pos + 1] = f8b[1];
  194. buf[pos + 2] = f8b[2];
  195. buf[pos + 3] = f8b[3];
  196. buf[pos + 4] = f8b[4];
  197. buf[pos + 5] = f8b[5];
  198. buf[pos + 6] = f8b[6];
  199. buf[pos + 7] = f8b[7];
  200. }
  202. function writeDouble_f64_rev(val, buf, pos) {
  203. f64[0] = val;
  204. buf[pos ] = f8b[7];
  205. buf[pos + 1] = f8b[6];
  206. buf[pos + 2] = f8b[5];
  207. buf[pos + 3] = f8b[4];
  208. buf[pos + 4] = f8b[3];
  209. buf[pos + 5] = f8b[2];
  210. buf[pos + 6] = f8b[1];
  211. buf[pos + 7] = f8b[0];
  212. }
  214. /* istanbul ignore next */
  215. exports.writeDoubleLE = le ? writeDouble_f64_cpy : writeDouble_f64_rev;
  216. /* istanbul ignore next */
  217. exports.writeDoubleBE = le ? writeDouble_f64_rev : writeDouble_f64_cpy;
  219. function readDouble_f64_cpy(buf, pos) {
  220. f8b[0] = buf[pos ];
  221. f8b[1] = buf[pos + 1];
  222. f8b[2] = buf[pos + 2];
  223. f8b[3] = buf[pos + 3];
  224. f8b[4] = buf[pos + 4];
  225. f8b[5] = buf[pos + 5];
  226. f8b[6] = buf[pos + 6];
  227. f8b[7] = buf[pos + 7];
  228. return f64[0];
  229. }
  231. function readDouble_f64_rev(buf, pos) {
  232. f8b[7] = buf[pos ];
  233. f8b[6] = buf[pos + 1];
  234. f8b[5] = buf[pos + 2];
  235. f8b[4] = buf[pos + 3];
  236. f8b[3] = buf[pos + 4];
  237. f8b[2] = buf[pos + 5];
  238. f8b[1] = buf[pos + 6];
  239. f8b[0] = buf[pos + 7];
  240. return f64[0];
  241. }
  243. /* istanbul ignore next */
  244. exports.readDoubleLE = le ? readDouble_f64_cpy : readDouble_f64_rev;
  245. /* istanbul ignore next */
  246. exports.readDoubleBE = le ? readDouble_f64_rev : readDouble_f64_cpy;
  248. // double: ieee754
  249. })(); else (function() {
  251. function writeDouble_ieee754(writeUint, off0, off1, val, buf, pos) {
  252. var sign = val < 0 ? 1 : 0;
  253. if (sign)
  254. val = -val;
  255. if (val === 0) {
  256. writeUint(0, buf, pos + off0);
  257. writeUint(1 / val > 0 ? /* positive */ 0 : /* negative 0 */ 2147483648, buf, pos + off1);
  258. } else if (isNaN(val)) {
  259. writeUint(0, buf, pos + off0);
  260. writeUint(2146959360, buf, pos + off1);
  261. } else if (val > 1.7976931348623157e+308) { // +-Infinity
  262. writeUint(0, buf, pos + off0);
  263. writeUint((sign << 31 | 2146435072) >>> 0, buf, pos + off1);
  264. } else {
  265. var mantissa;
  266. if (val < 2.2250738585072014e-308) { // denormal
  267. mantissa = val / 5e-324;
  268. writeUint(mantissa >>> 0, buf, pos + off0);
  269. writeUint((sign << 31 | mantissa / 4294967296) >>> 0, buf, pos + off1);
  270. } else {
  271. var exponent = Math.floor(Math.log(val) / Math.LN2);
  272. if (exponent === 1024)
  273. exponent = 1023;
  274. mantissa = val * Math.pow(2, -exponent);
  275. writeUint(mantissa * 4503599627370496 >>> 0, buf, pos + off0);
  276. writeUint((sign << 31 | exponent + 1023 << 20 | mantissa * 1048576 & 1048575) >>> 0, buf, pos + off1);
  277. }
  278. }
  279. }
  281. exports.writeDoubleLE = writeDouble_ieee754.bind(null, writeUintLE, 0, 4);
  282. exports.writeDoubleBE = writeDouble_ieee754.bind(null, writeUintBE, 4, 0);
  284. function readDouble_ieee754(readUint, off0, off1, buf, pos) {
  285. var lo = readUint(buf, pos + off0),
  286. hi = readUint(buf, pos + off1);
  287. var sign = (hi >> 31) * 2 + 1,
  288. exponent = hi >>> 20 & 2047,
  289. mantissa = 4294967296 * (hi & 1048575) + lo;
  290. return exponent === 2047
  291. ? mantissa
  292. ? NaN
  293. : sign * Infinity
  294. : exponent === 0 // denormal
  295. ? sign * 5e-324 * mantissa
  296. : sign * Math.pow(2, exponent - 1075) * (mantissa + 4503599627370496);
  297. }
  299. exports.readDoubleLE = readDouble_ieee754.bind(null, readUintLE, 0, 4);
  300. exports.readDoubleBE = readDouble_ieee754.bind(null, readUintBE, 4, 0);
  302. })();
  304. return exports;
  305. }
  307. // uint helpers
  309. function writeUintLE(val, buf, pos) {
  310. buf[pos ] = val & 255;
  311. buf[pos + 1] = val >>> 8 & 255;
  312. buf[pos + 2] = val >>> 16 & 255;
  313. buf[pos + 3] = val >>> 24;
  314. }
  316. function writeUintBE(val, buf, pos) {
  317. buf[pos ] = val >>> 24;
  318. buf[pos + 1] = val >>> 16 & 255;
  319. buf[pos + 2] = val >>> 8 & 255;
  320. buf[pos + 3] = val & 255;
  321. }
  323. function readUintLE(buf, pos) {
  324. return (buf[pos ]
  325. | buf[pos + 1] << 8
  326. | buf[pos + 2] << 16
  327. | buf[pos + 3] << 24) >>> 0;
  328. }
  330. function readUintBE(buf, pos) {
  331. return (buf[pos ] << 24
  332. | buf[pos + 1] << 16
  333. | buf[pos + 2] << 8
  334. | buf[pos + 3]) >>> 0;
  335. }