{"version":3,"file":"spc-parser.min.js","sources":["../lib-esm/types.js","../lib-esm/utility/headerUtils.js","../lib-esm/fileHeader.js","../lib-esm/utility/getDataShape.js","../lib-esm/utility/guessSpectraType.js","../node_modules/iobuffer/lib-esm/text.browser.js","../node_modules/iobuffer/lib-esm/IOBuffer.js","../node_modules/ml-spectra-processing/lib-esm/utils/createFromToArray.js","../lib-esm/dataBlock/shared.js","../lib-esm/dataBlock/utility/ensureIncreasingXValues.js","../lib-esm/dataBlock/newDataBlock.js","../lib-esm/dataBlock/oldDataBlock.js","../lib-esm/parse.js","../lib-esm/logBlock.js"],"sourcesContent":["/**\n * Gives meaning to type codes.\n * @param xzwType x, z or w type code.\n * @return String corresponding to the code.\n */\nexport function xzwTypes(xzwType) {\n switch (xzwType) {\n case 1:\n return 'Wavenumber (cm-1)';\n case 2:\n return 'Micrometers (um)';\n case 3:\n return 'Nanometers (nm)';\n case 4:\n return 'Seconds';\n case 5:\n return 'Minutes';\n case 6:\n return 'Hertz (Hz)';\n case 7:\n return 'Kilohertz (KHz)';\n case 8:\n return 'Megahertz (MHz)';\n case 9:\n return 'Mass (M/z)';\n case 10:\n return 'Parts per million (PPM)';\n case 11:\n return 'Days';\n case 12:\n return 'Years';\n case 13:\n return 'Raman Shift (cm-1)';\n case 14:\n return 'eV';\n case 15:\n return 0;\n case 16:\n return 'Diode Number';\n case 17:\n return 'Channel ';\n case 18:\n return 'Degrees';\n case 19:\n return 'Temperature (F)';\n case 20:\n return 'Temperature (C)';\n case 21:\n return 'Temperature (K)';\n case 22:\n return 'Data Points';\n case 23:\n return 'Milliseconds (mSec)';\n case 24:\n return 'Microseconds (uSec)';\n case 25:\n return 'Nanoseconds (nSec)';\n case 26:\n return 'Gigahertz (GHz)';\n case 27:\n return 'Centimeters (cm)';\n case 28:\n return 'Meters (m)';\n case 29:\n return 'Millimeters (mm)';\n case 30:\n return 'Hours';\n case 255:\n return 'Double interferogram';\n default:\n return 'Arbitrary';\n }\n}\n/**\n * Gives meaning to y type codes\n * @param yType y type code\n * @return String corresponding to the code\n */\nexport function yTypes(yType) {\n switch (yType) {\n case 0:\n return 'Arbitrary Intensity';\n case 1:\n return 'Interferogram';\n case 2:\n return 'Absorbance';\n case 3:\n return 'Kubelka-Monk';\n case 4:\n return 'Counts';\n case 5:\n return 'Volts';\n case 6:\n return 'Degrees';\n case 7:\n return 'Milliamps';\n case 8:\n return 'Millimeters';\n case 9:\n return 'Millivolts';\n case 10:\n return 'Log(1/R)';\n case 11:\n return 'Percent';\n case 12:\n return 'Intensity';\n case 13:\n return 'Relative Intensity';\n case 14:\n return 'Energy';\n case 16:\n return 'Decibel';\n case 19:\n return 'Temperature (F)';\n case 20:\n return 'Temperature (C)';\n case 21:\n return 'Temperature (K)';\n case 22:\n return 'Index of Refraction [N]';\n case 23:\n return 'Extinction Coeff. [K]';\n case 24:\n return 'Real';\n case 25:\n return 'Imaginary';\n case 26:\n return 'Complex';\n case 128:\n return 'Transmission';\n case 129:\n return 'Reflectance';\n case 130:\n return 'Arbitrary or Single Beam with Valley Peaks';\n case 131:\n return 'Emission';\n default:\n return 'Reference Arbitrary Energy';\n }\n}\n/**\n * Convert code to experiment type\n * @param code\n * @returns type of experiment carried out.\n */\nexport function experimentSettings(code) {\n switch (code) {\n case 1:\n return 'Gas Chromatogram';\n case 2:\n return 'General Chromatogram (same as SPCGEN with TCGRAM)';\n case 3:\n return 'HPLC Chromatogram';\n case 4:\n return 'FT-IR, FT-NIR, FT-Raman Spectrum or Igram (Can also be used for scanning IR.)';\n case 5:\n return 'NIR Spectrum (Usually multi-spectral data sets for calibration.)';\n case 7:\n return 'UV-VIS Spectrum (Can be used for single scanning UV-VIS-NIR.)';\n case 8:\n return 'X-ray Diffraction Spectrum';\n case 9:\n return 'Mass Spectrum (Can be single, GC-MS, Continuum, Centroid or TOF.)';\n case 10:\n return 'NMR Spectrum or FID';\n case 11:\n return 'Raman Spectrum (Usually Diode Array, CCD, etc. use SPCFTIR for FT-Raman.)';\n case 12:\n return 'Fluorescence Spectrum';\n case 13:\n return 'Atomic Spectrum';\n case 14:\n return 'Chromatography Diode Array Spectra';\n default:\n return 'General SPC (could be anything)';\n }\n}\n//# sourceMappingURL=types.js.map","/**\n * Gets the parameter in each bit of the flag\n *\n * @param flag First byte of the main header.\n * @returns The parameters.\n */\nexport class FlagParameters {\n constructor(flag) {\n this.y16BitPrecision = (flag & 1) !== 0; //Y values are 16 bits instead of 32\n this.useExperimentExtension = (flag & 2) !== 0; //Enable experiment mode\n this.multiFile = (flag & 4) !== 0; //Multiple spectra (multifile)\n this.zValuesRandom = (flag & 8) !== 0; //Z values in random order if multiFile\n this.zValuesUneven = (flag & 16) !== 0; //Z values ordered but unevenly spaced if multi\n this.customAxisLabels = (flag & 32) !== 0; //Custom labels\n this.xyxy = (flag & 64) !== 0; //One X array per subfile, for discontinuous curves\n this.xy = (flag & 128) !== 0; // Non-evenly spaced X, X before Y\n }\n}\n/**\n * Gets the date encoded in binary in a long number.\n * @param long Binary date.\n * @return Date formatted to ISO 8601:2019 convention.\n */\nexport function longToDate(long) {\n if (long === 0) {\n return '0000-00-00T00:00:00.00Z';\n }\n const date = new Date();\n date.setUTCFullYear(long >> 20);\n date.setUTCMonth(((long >> 16) & 0x0f) - 1);\n date.setUTCDate((long >> 11) & 0x1f);\n date.setUTCHours((long >> 6) & 0x1f);\n date.setUTCMinutes(long & 0x3f);\n date.setUTCSeconds(0);\n date.setUTCMilliseconds(0);\n return date.toISOString();\n}\n//# sourceMappingURL=headerUtils.js.map","import { xzwTypes, yTypes, experimentSettings } from './types';\nimport { FlagParameters, longToDate } from './utility/headerUtils';\n/**\n * Old-format File-header parsing.\n * @param buffer spc buffer.\n * @param prev `{parameters,fileversion}`\n * @return file metadata\n */\nexport class TheOldHeader {\n constructor(buffer, prev) {\n this.fileVersion = prev.fileVersion; //Each bit contains a parameter\n this.parameters = prev.parameters; //4B => New format; 4D => LabCalc format\n this.exponentY = buffer.readInt16(); //Word (16 bits) instead of byte\n this.numberPoints = buffer.readFloat32();\n this.startingX = buffer.readFloat32();\n this.endingX = buffer.readFloat32();\n this.xUnitsType = xzwTypes(buffer.readUint8());\n this.yUnitsType = yTypes(buffer.readUint8());\n const date = new Date();\n const zTypeYear = buffer.readUint16(); //Unrelated to Z axis\n date.setUTCFullYear(zTypeYear % 4096); // TODO: might be wrong\n date.setUTCMonth(Math.max(buffer.readUint8() - 1, 0));\n date.setUTCDate(buffer.readUint8());\n date.setUTCHours(buffer.readUint8());\n date.setUTCMinutes(buffer.readUint8());\n this.date = date.toISOString();\n this.resolutionDescription = buffer\n .readChars(8)\n .replace(/\\x00/g, '')\n .trim();\n this.peakPointNumber = buffer.readUint16();\n this.scans = buffer.readUint16();\n this.spare = [];\n for (let i = 0; i < 7; i++) {\n this.spare.push(buffer.readFloat32());\n }\n this.memo = buffer.readChars(130).replace(/\\x00/g, '').trim();\n this.xyzLabels = buffer.readChars(30).replace(/\\x00/g, '').trim();\n }\n}\n/**\n * New format file-header parsing.\n * @param buffer spc buffer.\n * @param prev `{parameters,fileversion}`\n * @return file metadata\n */\nexport class TheNewHeader {\n constructor(buffer, prev) {\n this.fileVersion = prev.fileVersion; //Each bit contains a parameter\n this.parameters = prev.parameters; //4B => New format; 4D => LabCalc format\n this.experimentType = experimentSettings(buffer.readUint8()); //Experiment type code (See SPC.h)\n this.exponentY = buffer.readInt8(); //Exponent for Y values (80h = floating point): FloatY = (2^Exp)*IntY/(2^32) 32-bit; FloatY = (2^Exp)*IntY/(2^16) 32-bit\n this.numberPoints = buffer.readUint32(); //Number of points (if not XYXY)\n this.startingX = buffer.readFloat64(); //First X coordinate\n this.endingX = buffer.readFloat64(); //Last X coordinate\n this.spectra = buffer.readUint32(); //Number of spectrums\n this.xUnitsType = xzwTypes(buffer.readUint8()); //X Units type code (See types.js)\n this.yUnitsType = yTypes(buffer.readUint8()); //Y \"\"\n this.zUnitsType = xzwTypes(buffer.readUint8()); //Z \"\"\n this.postingDisposition = buffer.readUint8(); //Posting disposition (See GRAMSDDE.H)\n this.date = longToDate(buffer.readUint32()); //Date: minutes = first 6 bits, hours = 5 next bits, days = 5 next, months = 4 next, years = 12 last\n this.resolutionDescription = buffer\n .readChars(9)\n .replace(/\\x00/g, '')\n .trim(); //Resolution description text\n this.sourceInstrumentDescription = buffer\n .readChars(9)\n .replace(/\\x00/g, '')\n .trim(); // Source Instrument description text\n this.peakPointNumber = buffer.readUint16(); //Peak point number for interferograms\n this.spare = [];\n for (let i = 0; i < 8; i++) {\n this.spare.push(buffer.readFloat32());\n }\n if (this.fileVersion === 0x4c) {\n //Untested case because no test files\n this.spare.reverse();\n }\n this.memo = buffer.readChars(130).replace(/\\x00/g, '').trim();\n this.xyzLabels = buffer.readChars(30).replace(/\\x00/g, '').trim();\n this.logOffset = buffer.readUint32(); //Byte offset to Log Block\n this.modifiedFlag = buffer.readUint32(); //File modification flag (See values in SPC.H)\n this.processingCode = buffer.readUint8(); //Processing code (See GRAMSDDE.H)\n this.calibrationLevel = buffer.readUint8(); //Calibration level + 1\n this.subMethodSampleInjectionNumber = buffer.readUint16(); //Sub-method sample injection number\n this.concentrationFactor = buffer.readFloat32(); //Floating data multiplier concentration factor\n this.methodFile = buffer.readChars(48).replace(/\\x00/g, '').trim(); //Method file\n this.zSubIncrement = buffer.readFloat32(); //Z subfile increment for even Z Multifiles\n this.wPlanes = buffer.readUint32();\n this.wPlaneIncrement = buffer.readFloat32();\n this.wAxisUnits = xzwTypes(buffer.readUint8()); //W axis units code\n this.reserved = buffer.readChars(187).replace(/\\x00/g, '').trim(); //Reserved space (Must be zero)\n if (this.xUnitsType === 0) {\n this.xUnitsType = this.xyzLabels.substring(0, 10);\n }\n if (this.zUnitsType === 0) {\n this.zUnitsType = this.xyzLabels.substring(20, 30);\n }\n }\n}\n/**\n * File-header parsing - First 512/256 bytes (new/old format).\n * @param buffer SPC buffer.\n * @return File-header object\n */\nexport function fileHeader(buffer) {\n const parameters = new FlagParameters(buffer.readUint8()); //Each bit contains a parameter\n const fileVersion = buffer.readUint8(); //4B => New format; 4D => LabCalc format\n const headerOpts = { parameters, fileVersion };\n switch (fileVersion) {\n case 0x4b: // new format\n break;\n case 0x4c:\n buffer.setBigEndian();\n break;\n case 0x4d: {\n // old LabCalc format\n return new TheOldHeader(buffer, headerOpts);\n }\n default:\n throw new Error('Unrecognized file format: byte 01 must be either 4B, 4C or 4D');\n }\n return new TheNewHeader(buffer, headerOpts);\n}\n//# sourceMappingURL=fileHeader.js.map","/** Get how the data was stored\n * @param multiFile - whether there are multiple spectra (subfiles) or not.\n * @param xy - uneven x values\n * @param xyxy - multifile with separate x axis\n * @return the shape of the data as a string\n */\nexport function getDataShape({ multiFile, xy, xyxy, }) {\n /* single file */\n if (!multiFile) {\n // Y or XY,\n return !xy ? 'Y' : xyxy ? 'exception' : 'XY';\n }\n /* then multifile */\n if (!xy) {\n /* even X - equidistant */\n return 'YY';\n }\n else {\n // uneven x\n return !xyxy ? 'XYY' : 'XYXY';\n }\n}\n//# sourceMappingURL=getDataShape.js.map","import { TheNewHeader } from '../fileHeader';\nimport { getDataShape } from './getDataShape';\n/**\n * Inspects properties and tries to classify the spectra\n * For the most common spectra types\n * @param data the parsed data\n * @returns string describing the type of spectra ([[`SpectraType`]]) or \"General\" if unsure.\n */\nexport function guessSpectraType(meta) {\n //function tested with the `fileHeader.test.ts`\n const { xUnitsType: xU, yUnitsType: yU } = meta;\n // for the new file header they define a \"experiment type\"\n if (meta instanceof TheNewHeader) {\n // \"General SPC\" does not give any information\n if (!meta.experimentType.startsWith('General SPC')) {\n const id = meta.experimentType.split(' ')[0];\n switch (id //find all possible ids in `types.ts` file\n ) {\n case 'FT-IR,':\n return 'ir';\n case 'NIR':\n return 'ir';\n case 'UV-VIS':\n return 'uv';\n case 'Mass':\n return 'mass';\n case 'Raman':\n return 'raman';\n default:\n return 'other';\n }\n }\n }\n // for old header or General SPC\n switch (xU) {\n case 'Mass (M/z)':\n return 'mass';\n case 'Raman Shift (cm-1)':\n return 'raman';\n case 'Micrometers (um)':\n return uvOrIR(meta, 'micrometer');\n case 'Wavenumber (cm-1)': {\n return uvOrIR(meta, 'wavenumber');\n }\n case 'Nanometers (nm)':\n if ([/*'Kubelka-Monk'*/ 'Absorbance', 'Log(1/R)', 'Transmission'].includes(yU)) {\n return uvOrIR(meta, 'nanometer');\n }\n return 'other';\n default:\n return 'other';\n }\n}\n/**\n * Further classify an X axis that is using \"wavenumber\" as uv or ir.\n * @param data - the parsed file (a jsonlike object)\n * @returns\n */\nexport function uvOrIR(meta, xUnit) {\n //tested in \"parse\" because of the input\n const dataShape = getDataShape(meta.parameters);\n //xyxy and exception won't normally get here anyways (raman or ms normally.)\n const analyze = ['Y', 'YY', 'XY', 'XYY'].includes(dataShape);\n if (analyze) {\n let sX = meta.startingX;\n let eX = meta.endingX;\n if (xUnit !== 'nanometer') {\n sX = unitToNano(sX, xUnit);\n eX = unitToNano(eX, xUnit);\n }\n const lowerBound = sX <= eX ? sX : eX;\n return getRegion(lowerBound);\n }\n return 'other';\n}\n/**\n * @param lb - lower boundary in _nanometers_\n * @return type of spectra\n */\nexport function getRegion(lb) {\n return lb < 150 ? 'other' : lb < 700 ? 'uv' : 'ir';\n}\n/**\n * Converts micrometers or wavenumber units to nanometers\n * This allows a unique way to determine the spectra region (using nanometers).\n * @param x - value\n * @param from - input unit to convert\n * @return equivalent in nanometers\n */\nexport function unitToNano(x, from) {\n return from === 'micrometer' ? x * 1000 : (1 / x) * 10 ** 7;\n}\n//# sourceMappingURL=guessSpectraType.js.map","// eslint-disable-next-line import/no-unassigned-import\nimport './text-encoding-polyfill';\nexport function decode(bytes, encoding = 'utf8') {\n const decoder = new TextDecoder(encoding);\n return decoder.decode(bytes);\n}\nconst encoder = new TextEncoder();\nexport function encode(str) {\n return encoder.encode(str);\n}\n//# sourceMappingURL=text.browser.js.map","import { decode, encode } from './text';\nconst defaultByteLength = 1024 * 8;\nconst hostBigEndian = (() => {\n const array = new Uint8Array(4);\n const view = new Uint32Array(array.buffer);\n return !((view[0] = 1) & array[0]);\n})();\nconst typedArrays = {\n int8: globalThis.Int8Array,\n uint8: globalThis.Uint8Array,\n int16: globalThis.Int16Array,\n uint16: globalThis.Uint16Array,\n int32: globalThis.Int32Array,\n uint32: globalThis.Uint32Array,\n uint64: globalThis.BigUint64Array,\n int64: globalThis.BigInt64Array,\n float32: globalThis.Float32Array,\n float64: globalThis.Float64Array,\n};\nexport class IOBuffer {\n /**\n * @param data - The data to construct the IOBuffer with.\n * If data is a number, it will be the new buffer's length \n * If data is `undefined`, the buffer will be initialized with a default length of 8Kb \n * If data is an ArrayBuffer, SharedArrayBuffer, an ArrayBufferView (Typed Array), an IOBuffer instance,\n * or a Node.js Buffer, a view will be created over the underlying ArrayBuffer.\n * @param options\n */\n constructor(data = defaultByteLength, options = {}) {\n let dataIsGiven = false;\n if (typeof data === 'number') {\n data = new ArrayBuffer(data);\n }\n else {\n dataIsGiven = true;\n this.lastWrittenByte = data.byteLength;\n }\n const offset = options.offset ? options.offset >>> 0 : 0;\n const byteLength = data.byteLength - offset;\n let dvOffset = offset;\n if (ArrayBuffer.isView(data) || data instanceof IOBuffer) {\n if (data.byteLength !== data.buffer.byteLength) {\n dvOffset = data.byteOffset + offset;\n }\n data = data.buffer;\n }\n if (dataIsGiven) {\n this.lastWrittenByte = byteLength;\n }\n else {\n this.lastWrittenByte = 0;\n }\n this.buffer = data;\n this.length = byteLength;\n this.byteLength = byteLength;\n this.byteOffset = dvOffset;\n this.offset = 0;\n this.littleEndian = true;\n this._data = new DataView(this.buffer, dvOffset, byteLength);\n this._mark = 0;\n this._marks = [];\n }\n /**\n * Checks if the memory allocated to the buffer is sufficient to store more\n * bytes after the offset.\n * @param byteLength - The needed memory in bytes.\n * @returns `true` if there is sufficient space and `false` otherwise.\n */\n available(byteLength = 1) {\n return this.offset + byteLength <= this.length;\n }\n /**\n * Check if little-endian mode is used for reading and writing multi-byte\n * values.\n * @returns `true` if little-endian mode is used, `false` otherwise.\n */\n isLittleEndian() {\n return this.littleEndian;\n }\n /**\n * Set little-endian mode for reading and writing multi-byte values.\n */\n setLittleEndian() {\n this.littleEndian = true;\n return this;\n }\n /**\n * Check if big-endian mode is used for reading and writing multi-byte values.\n * @returns `true` if big-endian mode is used, `false` otherwise.\n */\n isBigEndian() {\n return !this.littleEndian;\n }\n /**\n * Switches to big-endian mode for reading and writing multi-byte values.\n */\n setBigEndian() {\n this.littleEndian = false;\n return this;\n }\n /**\n * Move the pointer n bytes forward.\n * @param n - Number of bytes to skip.\n */\n skip(n = 1) {\n this.offset += n;\n return this;\n }\n /**\n * Move the pointer n bytes backward.\n * @param n - Number of bytes to move back.\n */\n back(n = 1) {\n this.offset -= n;\n return this;\n }\n /**\n * Move the pointer to the given offset.\n * @param offset\n */\n seek(offset) {\n this.offset = offset;\n return this;\n }\n /**\n * Store the current pointer offset.\n * @see {@link IOBuffer#reset}\n */\n mark() {\n this._mark = this.offset;\n return this;\n }\n /**\n * Move the pointer back to the last pointer offset set by mark.\n * @see {@link IOBuffer#mark}\n */\n reset() {\n this.offset = this._mark;\n return this;\n }\n /**\n * Push the current pointer offset to the mark stack.\n * @see {@link IOBuffer#popMark}\n */\n pushMark() {\n this._marks.push(this.offset);\n return this;\n }\n /**\n * Pop the last pointer offset from the mark stack, and set the current\n * pointer offset to the popped value.\n * @see {@link IOBuffer#pushMark}\n */\n popMark() {\n const offset = this._marks.pop();\n if (offset === undefined) {\n throw new Error('Mark stack empty');\n }\n this.seek(offset);\n return this;\n }\n /**\n * Move the pointer offset back to 0.\n */\n rewind() {\n this.offset = 0;\n return this;\n }\n /**\n * Make sure the buffer has sufficient memory to write a given byteLength at\n * the current pointer offset.\n * If the buffer's memory is insufficient, this method will create a new\n * buffer (a copy) with a length that is twice (byteLength + current offset).\n * @param byteLength\n */\n ensureAvailable(byteLength = 1) {\n if (!this.available(byteLength)) {\n const lengthNeeded = this.offset + byteLength;\n const newLength = lengthNeeded * 2;\n const newArray = new Uint8Array(newLength);\n newArray.set(new Uint8Array(this.buffer));\n this.buffer = newArray.buffer;\n this.length = this.byteLength = newLength;\n this._data = new DataView(this.buffer);\n }\n return this;\n }\n /**\n * Read a byte and return false if the byte's value is 0, or true otherwise.\n * Moves pointer forward by one byte.\n */\n readBoolean() {\n return this.readUint8() !== 0;\n }\n /**\n * Read a signed 8-bit integer and move pointer forward by 1 byte.\n */\n readInt8() {\n return this._data.getInt8(this.offset++);\n }\n /**\n * Read an unsigned 8-bit integer and move pointer forward by 1 byte.\n */\n readUint8() {\n return this._data.getUint8(this.offset++);\n }\n /**\n * Alias for {@link IOBuffer#readUint8}.\n */\n readByte() {\n return this.readUint8();\n }\n /**\n * Read `n` bytes and move pointer forward by `n` bytes.\n */\n readBytes(n = 1) {\n return this.readArray(n, 'uint8');\n }\n /**\n * Creates an array of corresponding to the type `type` and size `size`.\n * For example type `uint8` will create a `Uint8Array`.\n * @param size - size of the resulting array\n * @param type - number type of elements to read\n */\n readArray(size, type) {\n const bytes = typedArrays[type].BYTES_PER_ELEMENT * size;\n const offset = this.byteOffset + this.offset;\n const slice = this.buffer.slice(offset, offset + bytes);\n if (this.littleEndian === hostBigEndian &&\n type !== 'uint8' &&\n type !== 'int8') {\n const slice = new Uint8Array(this.buffer.slice(offset, offset + bytes));\n slice.reverse();\n const returnArray = new typedArrays[type](slice.buffer);\n this.offset += bytes;\n returnArray.reverse();\n return returnArray;\n }\n const returnArray = new typedArrays[type](slice);\n this.offset += bytes;\n return returnArray;\n }\n /**\n * Read a 16-bit signed integer and move pointer forward by 2 bytes.\n */\n readInt16() {\n const value = this._data.getInt16(this.offset, this.littleEndian);\n this.offset += 2;\n return value;\n }\n /**\n * Read a 16-bit unsigned integer and move pointer forward by 2 bytes.\n */\n readUint16() {\n const value = this._data.getUint16(this.offset, this.littleEndian);\n this.offset += 2;\n return value;\n }\n /**\n * Read a 32-bit signed integer and move pointer forward by 4 bytes.\n */\n readInt32() {\n const value = this._data.getInt32(this.offset, this.littleEndian);\n this.offset += 4;\n return value;\n }\n /**\n * Read a 32-bit unsigned integer and move pointer forward by 4 bytes.\n */\n readUint32() {\n const value = this._data.getUint32(this.offset, this.littleEndian);\n this.offset += 4;\n return value;\n }\n /**\n * Read a 32-bit floating number and move pointer forward by 4 bytes.\n */\n readFloat32() {\n const value = this._data.getFloat32(this.offset, this.littleEndian);\n this.offset += 4;\n return value;\n }\n /**\n * Read a 64-bit floating number and move pointer forward by 8 bytes.\n */\n readFloat64() {\n const value = this._data.getFloat64(this.offset, this.littleEndian);\n this.offset += 8;\n return value;\n }\n /**\n * Read a 64-bit signed integer number and move pointer forward by 8 bytes.\n */\n readBigInt64() {\n const value = this._data.getBigInt64(this.offset, this.littleEndian);\n this.offset += 8;\n return value;\n }\n /**\n * Read a 64-bit unsigned integer number and move pointer forward by 8 bytes.\n */\n readBigUint64() {\n const value = this._data.getBigUint64(this.offset, this.littleEndian);\n this.offset += 8;\n return value;\n }\n /**\n * Read a 1-byte ASCII character and move pointer forward by 1 byte.\n */\n readChar() {\n return String.fromCharCode(this.readInt8());\n }\n /**\n * Read `n` 1-byte ASCII characters and move pointer forward by `n` bytes.\n */\n readChars(n = 1) {\n let result = '';\n for (let i = 0; i < n; i++) {\n result += this.readChar();\n }\n return result;\n }\n /**\n * Read the next `n` bytes, return a UTF-8 decoded string and move pointer\n * forward by `n` bytes.\n */\n readUtf8(n = 1) {\n return decode(this.readBytes(n));\n }\n /**\n * Read the next `n` bytes, return a string decoded with `encoding` and move pointer\n * forward by `n` bytes.\n * If no encoding is passed, the function is equivalent to @see {@link IOBuffer#readUtf8}\n */\n decodeText(n = 1, encoding = 'utf-8') {\n return decode(this.readBytes(n), encoding);\n }\n /**\n * Write 0xff if the passed value is truthy, 0x00 otherwise and move pointer\n * forward by 1 byte.\n */\n writeBoolean(value) {\n this.writeUint8(value ? 0xff : 0x00);\n return this;\n }\n /**\n * Write `value` as an 8-bit signed integer and move pointer forward by 1 byte.\n */\n writeInt8(value) {\n this.ensureAvailable(1);\n this._data.setInt8(this.offset++, value);\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as an 8-bit unsigned integer and move pointer forward by 1\n * byte.\n */\n writeUint8(value) {\n this.ensureAvailable(1);\n this._data.setUint8(this.offset++, value);\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * An alias for {@link IOBuffer#writeUint8}.\n */\n writeByte(value) {\n return this.writeUint8(value);\n }\n /**\n * Write all elements of `bytes` as uint8 values and move pointer forward by\n * `bytes.length` bytes.\n */\n writeBytes(bytes) {\n this.ensureAvailable(bytes.length);\n for (let i = 0; i < bytes.length; i++) {\n this._data.setUint8(this.offset++, bytes[i]);\n }\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 16-bit signed integer and move pointer forward by 2\n * bytes.\n */\n writeInt16(value) {\n this.ensureAvailable(2);\n this._data.setInt16(this.offset, value, this.littleEndian);\n this.offset += 2;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 16-bit unsigned integer and move pointer forward by 2\n * bytes.\n */\n writeUint16(value) {\n this.ensureAvailable(2);\n this._data.setUint16(this.offset, value, this.littleEndian);\n this.offset += 2;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 32-bit signed integer and move pointer forward by 4\n * bytes.\n */\n writeInt32(value) {\n this.ensureAvailable(4);\n this._data.setInt32(this.offset, value, this.littleEndian);\n this.offset += 4;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 32-bit unsigned integer and move pointer forward by 4\n * bytes.\n */\n writeUint32(value) {\n this.ensureAvailable(4);\n this._data.setUint32(this.offset, value, this.littleEndian);\n this.offset += 4;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 32-bit floating number and move pointer forward by 4\n * bytes.\n */\n writeFloat32(value) {\n this.ensureAvailable(4);\n this._data.setFloat32(this.offset, value, this.littleEndian);\n this.offset += 4;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 64-bit floating number and move pointer forward by 8\n * bytes.\n */\n writeFloat64(value) {\n this.ensureAvailable(8);\n this._data.setFloat64(this.offset, value, this.littleEndian);\n this.offset += 8;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 64-bit signed bigint and move pointer forward by 8\n * bytes.\n */\n writeBigInt64(value) {\n this.ensureAvailable(8);\n this._data.setBigInt64(this.offset, value, this.littleEndian);\n this.offset += 8;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write `value` as a 64-bit unsigned bigint and move pointer forward by 8\n * bytes.\n */\n writeBigUint64(value) {\n this.ensureAvailable(8);\n this._data.setBigUint64(this.offset, value, this.littleEndian);\n this.offset += 8;\n this._updateLastWrittenByte();\n return this;\n }\n /**\n * Write the charCode of `str`'s first character as an 8-bit unsigned integer\n * and move pointer forward by 1 byte.\n */\n writeChar(str) {\n return this.writeUint8(str.charCodeAt(0));\n }\n /**\n * Write the charCodes of all `str`'s characters as 8-bit unsigned integers\n * and move pointer forward by `str.length` bytes.\n */\n writeChars(str) {\n for (let i = 0; i < str.length; i++) {\n this.writeUint8(str.charCodeAt(i));\n }\n return this;\n }\n /**\n * UTF-8 encode and write `str` to the current pointer offset and move pointer\n * forward according to the encoded length.\n */\n writeUtf8(str) {\n return this.writeBytes(encode(str));\n }\n /**\n * Export a Uint8Array view of the internal buffer.\n * The view starts at the byte offset and its length\n * is calculated to stop at the last written byte or the original length.\n */\n toArray() {\n return new Uint8Array(this.buffer, this.byteOffset, this.lastWrittenByte);\n }\n /**\n * Update the last written byte offset\n * @private\n */\n _updateLastWrittenByte() {\n if (this.offset > this.lastWrittenByte) {\n this.lastWrittenByte = this.offset;\n }\n }\n}\n//# sourceMappingURL=IOBuffer.js.map","/**\n * Create an array with numbers between \"from\" and \"to\" of length \"length\"\n *\n * @param options - options\n * @return - array of distributed numbers between \"from\" and \"to\"\n */\nexport function createFromToArray(options = {}) {\n let { from = 0, to = 1, length = 1000, includeFrom = true, includeTo = true, distribution = 'uniform', } = options;\n const array = new Float64Array(length);\n let div = length;\n if (includeFrom && includeTo) {\n div = length - 1;\n }\n else if ((!includeFrom && includeTo) || (includeFrom && !includeTo)) {\n div = length;\n }\n else if (!includeFrom && !includeTo) {\n div = length + 1;\n }\n let delta = (to - from) / div;\n if (distribution === 'uniform') {\n if (includeFrom) {\n let index = 0;\n while (index < length) {\n array[index] = from + delta * index;\n index++;\n }\n }\n else {\n let index = 0;\n while (index < length) {\n array[index] = from + delta * (index + 1);\n index++;\n }\n }\n }\n else if (distribution === 'log') {\n let base = (to / from) ** (1 / div);\n let firstExponent = Math.log(from) / Math.log(base);\n if (includeFrom) {\n let index = 0;\n while (index < length) {\n array[index] = base ** (firstExponent + index);\n index++;\n }\n }\n else {\n let index = 0;\n while (index < length) {\n array[index] = base ** (firstExponent + index + 1);\n index++;\n }\n }\n }\n else {\n throw new Error('Please choose for the distribution either uniform or log. By default the distribution chosen is uniform.');\n }\n return array;\n}\n//# sourceMappingURL=createFromToArray.js.map","import { ensureIncreasingXValues } from './utility/ensureIncreasingXValues';\n/**\n * Gets the Subfile flags.\n *\n * @param flag First byte of the subheader.\n * @return The parameters.\n */\nexport class SubFlagParameters {\n constructor(flag) {\n this.changed = (flag & 1) !== 0;\n this.noPeakTable = (flag & 8) !== 0;\n this.modifiedArithmetic = (flag & 128) !== 0;\n }\n}\n/**\n * Parses the subheader (header of the subfile)\n *\n * @param buffer SPC buffer.\n * @return subheader object\n */\nexport class SubHeader {\n constructor(buffer) {\n this.parameters = new SubFlagParameters(buffer.readUint8());\n this.exponentY = buffer.readInt8();\n this.indexNumber = buffer.readUint16();\n this.startingZ = buffer.readFloat32();\n this.endingZ = buffer.readFloat32();\n this.noiseValue = buffer.readFloat32();\n this.numberPoints = buffer.readUint32();\n this.numberCoAddedScans = buffer.readUint32();\n this.wAxisValue = buffer.readFloat32();\n this.reserved = buffer.readChars(4).replace(/\\x00/g, '').trim();\n }\n}\n/**\n * Set the X and Y axis (object with labels, values etc.)\n * @param x\n * @param y\n * @param fileHeader\n * @return object with x and y as axis.\n */\nexport function setXYAxis(x, y, fileHeader) {\n var _a, _b, _c, _d;\n const xAxis = /(?