How to use the @ethersproject/sha2.computeHmac function in @ethersproject/sha2

// Data = 0x00 || ser_256(k_par)
            data.set(arrayify(this.privateKey), 1);
            // Hardened path
            if (path) {
                path += "'";
            }
        }
        else {
            // Data = ser_p(point(k_par))
            data.set(arrayify(this.publicKey));
        }
        // Data += ser_32(i)
        for (let i = 24; i >= 0; i -= 8) {
            data[33 + (i >> 3)] = ((index >> (24 - i)) & 0xff);
        }
        const I = arrayify(computeHmac(SupportedAlgorithms.sha512, this.chainCode, data));
        const IL = I.slice(0, 32);
        const IR = I.slice(32);
        // The private key
        let ki = null;
        // The public key
        let Ki = null;
        if (this.privateKey) {
            ki = bytes32(BigNumber.from(IL).add(this.privateKey).mod(N));
        }
        else {
            const ek = new SigningKey(hexlify(IL));
            Ki = ek._addPoint(this.publicKey);
        }
        return new HDNode(_constructorGuard, ki, Ki, this.fingerprint, bytes32(IR), index, this.depth + 1, this.mnemonic, path);
    }
    derivePath(path) {

// Data = 0x00 || ser_256(k_par)
            data.set(arrayify(this.privateKey), 1);

            // Hardened path
            if (path) { path += "'"; }

        } else {
            // Data = ser_p(point(k_par))
            data.set(arrayify(this.publicKey));
        }

        // Data += ser_32(i)
        for (let i = 24; i >= 0; i -= 8) { data[33 + (i >> 3)] = ((index >> (24 - i)) & 0xff); }

        const I = arrayify(computeHmac(SupportedAlgorithms.sha512, this.chainCode, data));
        const IL = I.slice(0, 32);
        const IR = I.slice(32);

        // The private key
        let ki: string = null

        // The public key
        let Ki: string = null;

        if (this.privateKey) {
            ki = bytes32(BigNumber.from(IL).add(this.privateKey).mod(N));
        } else {
            const ek = new SigningKey(hexlify(IL));
            Ki = ek._addPoint(this.publicKey);
        }

// Data = 0x00 || ser_256(k_par)
            data.set(bytes_1.arrayify(this.privateKey), 1);
            // Hardened path
            if (path) {
                path += "'";
            }
        }
        else {
            // Data = ser_p(point(k_par))
            data.set(bytes_1.arrayify(this.publicKey));
        }
        // Data += ser_32(i)
        for (var i = 24; i >= 0; i -= 8) {
            data[33 + (i >> 3)] = ((index >> (24 - i)) & 0xff);
        }
        var I = bytes_1.arrayify(sha2_1.computeHmac(sha2_1.SupportedAlgorithms.sha512, this.chainCode, data));
        var IL = I.slice(0, 32);
        var IR = I.slice(32);
        // The private key
        var ki = null;
        // The public key
        var Ki = null;
        if (this.privateKey) {
            ki = bytes32(bignumber_1.BigNumber.from(IL).add(this.privateKey).mod(N));
        }
        else {
            var ek = new signing_key_1.SigningKey(bytes_1.hexlify(IL));
            Ki = ek._addPoint(this.publicKey);
        }
        return new HDNode(_constructorGuard, ki, Ki, this.fingerprint, bytes32(IR), index, this.depth + 1, this.mnemonic, path);
    };
    HDNode.prototype.derivePath = function (path) {

const block1 = new Uint8Array(salt.length + 4)
    block1.set(salt);
    //salt.copy(block1, 0, 0, salt.length)

    let r: number;
    let T: Uint8Array;

    for (let i = 1; i <= l; i++) {
        //block1.writeUInt32BE(i, salt.length)
        block1[salt.length] = (i >> 24) & 0xff;
        block1[salt.length + 1] = (i >> 16) & 0xff;
        block1[salt.length + 2] = (i >> 8) & 0xff;
        block1[salt.length + 3] = i & 0xff;

        //let U = createHmac(password).update(block1).digest();
        let U = arrayify(computeHmac(hashAlgorithm, password, block1));

        if (!hLen) {
            hLen = U.length
            T = new Uint8Array(hLen)
            l = Math.ceil(keylen / hLen)
            r = keylen - (l - 1) * hLen
        }

        //U.copy(T, 0, 0, hLen)
        T.set(U);


        for (let j = 1; j < iterations; j++) {
            //U = createHmac(password).update(U).digest();
            U = arrayify(computeHmac(hashAlgorithm, password, U));
            for (let k = 0; k < hLen; k++) T[k] ^= U[k]

block1[salt.length + 1] = (i >> 16) & 0xff;
        block1[salt.length + 2] = (i >> 8) & 0xff;
        block1[salt.length + 3] = i & 0xff;
        //let U = createHmac(password).update(block1).digest();
        let U = arrayify(computeHmac(hashAlgorithm, password, block1));
        if (!hLen) {
            hLen = U.length;
            T = new Uint8Array(hLen);
            l = Math.ceil(keylen / hLen);
            r = keylen - (l - 1) * hLen;
        }
        //U.copy(T, 0, 0, hLen)
        T.set(U);
        for (let j = 1; j < iterations; j++) {
            //U = createHmac(password).update(U).digest();
            U = arrayify(computeHmac(hashAlgorithm, password, U));
            for (let k = 0; k < hLen; k++)
                T[k] ^= U[k];
        }
        const destPos = (i - 1) * hLen;
        const len = (i === l ? r : hLen);
        //T.copy(DK, destPos, 0, len)
        DK.set(arrayify(T).slice(0, len), destPos);
    }
    return hexlify(DK);
}

let hLen;
    let l = 1;
    const DK = new Uint8Array(keylen);
    const block1 = new Uint8Array(salt.length + 4);
    block1.set(salt);
    //salt.copy(block1, 0, 0, salt.length)
    let r;
    let T;
    for (let i = 1; i <= l; i++) {
        //block1.writeUInt32BE(i, salt.length)
        block1[salt.length] = (i >> 24) & 0xff;
        block1[salt.length + 1] = (i >> 16) & 0xff;
        block1[salt.length + 2] = (i >> 8) & 0xff;
        block1[salt.length + 3] = i & 0xff;
        //let U = createHmac(password).update(block1).digest();
        let U = arrayify(computeHmac(hashAlgorithm, password, block1));
        if (!hLen) {
            hLen = U.length;
            T = new Uint8Array(hLen);
            l = Math.ceil(keylen / hLen);
            r = keylen - (l - 1) * hLen;
        }
        //U.copy(T, 0, 0, hLen)
        T.set(U);
        for (let j = 1; j < iterations; j++) {
            //U = createHmac(password).update(U).digest();
            U = arrayify(computeHmac(hashAlgorithm, password, U));
            for (let k = 0; k < hLen; k++)
                T[k] ^= U[k];
        }
        const destPos = (i - 1) * hLen;
        const len = (i === l ? r : hLen);

var hLen;
    var l = 1;
    var DK = new Uint8Array(keylen);
    var block1 = new Uint8Array(salt.length + 4);
    block1.set(salt);
    //salt.copy(block1, 0, 0, salt.length)
    var r;
    var T;
    for (var i = 1; i <= l; i++) {
        //block1.writeUInt32BE(i, salt.length)
        block1[salt.length] = (i >> 24) & 0xff;
        block1[salt.length + 1] = (i >> 16) & 0xff;
        block1[salt.length + 2] = (i >> 8) & 0xff;
        block1[salt.length + 3] = i & 0xff;
        //let U = createHmac(password).update(block1).digest();
        var U = bytes_1.arrayify(sha2_1.computeHmac(hashAlgorithm, password, block1));
        if (!hLen) {
            hLen = U.length;
            T = new Uint8Array(hLen);
            l = Math.ceil(keylen / hLen);
            r = keylen - (l - 1) * hLen;
        }
        //U.copy(T, 0, 0, hLen)
        T.set(U);
        for (var j = 1; j < iterations; j++) {
            //U = createHmac(password).update(U).digest();
            U = bytes_1.arrayify(sha2_1.computeHmac(hashAlgorithm, password, U));
            for (var k = 0; k < hLen; k++)
                T[k] ^= U[k];
        }
        var destPos = (i - 1) * hLen;
        var len = (i === l ? r : hLen);