HttpInterceptor to cache clientside in Angular 8

I have been working with a sample project of HttpInterceptor to cache data clientside in Angular 8 hosted on Github. The repository is here: https://github.com/toreaurstadboss/AngularHttpInterceptorSample First off, the data is delivered by a small backend using Express.Js.The server.js file looks like this:

const express = require('express');
const path = require('path');
const fs = require('fs');
var favicon = require('serve-favicon');
var logger = require('morgan');
var cookieParser = require('cookie-parser');
var bodyParser = require('body-parser');

var towns = require('./server/routes/towns');

var app = express();

// view engine setup
app.set('views', path.join(__dirname, '/server/views'));
app.set('view engine', 'jade');

app.use(favicon(path.join(__dirname, 'dist/favicon.ico')));
app.use(logger('dev'));
app.use(bodyParser.json());
app.use(bodyParser.urlencoded({ extended: false }));
app.use(cookieParser());
app.use(express.static(path.join(__dirname, 'dist')));

app.use(function (req, res, next) {
    if (!req.url.startsWith('/api')){
      req.url = '/api' + req.url;
    }
    console.log('got requst url: ' + req.url);
    console.log('Server handling request at Time:', new Date())
    next()
  })

// app.use('/', routes);
app.get('/api/towns', function(req, res) {
    let townsFileContents = fs.readFileSync(path.join(__dirname, 'server/data/townsandcities.json'), 'utf-8');
    let townsFound = JSON.parse(townsFileContents);
    console.log(townsFileContents);
    res.json(townsFound);
});

// app.get('*', function(req, res) {
//   res.sendFile(path.join(__dirname, 'dist/index.html'));
// });

// catch 404 and forward to error handler
// app.use(function(req, res, next) {
//     var err = new Error('Not Found');
//     err.status = 404;
//     next(err);
// });

// error handlers

// development error handler
// will print stacktrace
if (app.get('env') === 'development') {
    app.use(function(err, req, res, next) {
        res.status(err.status || 500);
        res.render('error', {
            message: err.message,
            error: err
        });
    });
}

// production error handler
// no stacktraces leaked to user
app.use(function(err, req, res, next) {
    res.status(err.status || 500);
    res.render('error', {
        message: err.message,
        error: {}
    });
});

var debug = require('debug')('server');

app.set('port', process.env.PORT || 3000);

app.listen(app.get('port'));

console.log('Listening on port: ' + app.get('port'));

module.exports = app;

Angular bits is written in Typescript instead of just Js. The Http Interceptor itself is a ES 6 class which is exported and caches http responses according to route urls.

import { HttpInterceptor, HttpRequest, HttpHandler, HttpEvent, HttpResponse } from '@angular/common/http';
import { Observable, of } from 'rxjs';
import { tap } from 'rxjs/operators';
import { CacheService } from './cache.service';


export class CacheInterceptor implements HttpInterceptor {

    constructor(private cacheService: CacheService) {
    }

    intercept(req: HttpRequest<any>, next: HttpHandler): Observable<HttpEvent<any>> {


        if (req.method !== 'GET') {
            this.cacheService.invalidateCache();
        }
        const cachedResponse: HttpResponse<any> = this.cacheService.get(req.url);
        if (cachedResponse !== undefined) {
         return of(cachedResponse);
        }

        return next.handle(req).pipe(
            tap(event => {
                if (event instanceof HttpResponse) {
                    this.cacheService.put(req.url, event);
                    let reponse: HttpResponse<any>;
                    reponse  = event;

                }
                return of(event);
            })
        );
    }

}

The CacheService caches responses to the client by route url as mentioned. It looks like this:

import { Injectable } from '@angular/core';
import { ICacheservice } from './icacheservice';
import { HttpResponse } from '@angular/common/http';

@Injectable({
  providedIn: 'root'
})
export class CacheService implements ICacheservice {
  private requests = { };
  put(url: string, response: HttpResponse): void {
    this.requests[url] = response;
  }
  get(url: string): HttpResponse | undefined {
    return this.requests[url] ? this.requests[url] : undefined;
  }
  invalidateCache(): void {
    this.requests = {};
  }
  expireItem(url: string, timeoutInMilliseconds: number) {
    const itemFound = this.get(url);
    if (itemFound !== undefined) {
      setTimeout(() => {
        this.requests[url] = undefined;
      }, timeoutInMilliseconds);
    }

  }

  constructor() { }

}

We inject the HttpInterceptor to the app module like this:

import { BrowserModule } from '@angular/platform-browser';
import { NgModule } from '@angular/core';
import { AppComponent } from './app.component';
import { CacheInterceptor } from './core/cache.interceptor';
import { HTTP_INTERCEPTORS, HttpClientModule } from '@angular/common/http';
import { BrowserAnimationsModule } from '@angular/platform-browser/animations';
import { MatTableModule } from  '@angular/material';

@NgModule({
  declarations: [
    AppComponent
  ],
  imports: [
    BrowserModule,
    HttpClientModule,
    MatTableModule,
    BrowserAnimationsModule
  ],
  providers: [
    { provide: HTTP_INTERCEPTORS, useClass: CacheInterceptor, multi: true }
  ],
  bootstrap: [AppComponent]
})
export class AppModule { }

The index page then contains some markup including a Material Table using Google's Material UI. The app.component.ts handles the client side call back that triggers the retrieval and clearing of the data. If you click the load link, the data is retrieved and cached. If you open up Developer tools with F12, you will spot that the data is cached if you hit load many times. If you hit clear link, the data is cleared from cache and next click on load will fetch data again and inject into the cache. This sample shows how you can create a cache side feature of Angular 8 and support an HTTP interceptor. To check it out yourself run: git clone https://github.com/toreaurstadboss/AngularHttpInterceptorSample.git Afterwards, run: npm run start This will start both the Angular website on port 4200 and the Node.js Express.js backend on port 3000. The package.json script for npm run start looks like this: "start": "concurrently --kill-others \"ng build --watch --no-delete-output-path\" \"nodemon server.js\" \"ng serve --proxy-config proxy.conf.json \"", You can also just enter: npm start

Http echo service written in Node.js

I have added a small repo on Github that shows how to create a simple HTTP echo service. https://github.com/toreaurstadboss/NodeJsHttpEchoServer The server.js is script is this:

let http = require('http');

console.log('Attempting to start the Node.js echos server on port 8081..')
http.createServer().on('request', function(request, response){
 request.pipe(response);
}).on('close', function(){
    console.log('The Node.js echo server has been closed.')
})
.listen(8081);

console.log('Node.js echo server started on port 8081.')

This will pipe out the requesting data to the response. Test it out with this command for example in a command window: curl -d "Hello dog" http://localhost:8081 Note - use not Powershell for this command as Powershell has aliased curl command for Invoke-WebRequest. Rather install curl with Chocolatey for example, choco install curl

Using Ndepend to investigate method cycles

Ndepend is a very powerful Code analysis platform for DotNet and I have created a method cycle detection rule. The method cycle detection also supports property setters and getters. A cycle in a property or method will often cause problems, such as stack overflow exceptions due to too many recursive calls. Spotting such cycles can often be hard in real-world scenarios. A classic error is to actually do a cycle through a property getter, by just calling the getter once more or a property setter for that instance. The following C# attribute invokes a Rules extracted from Source code from Ndepend.

using System;
using NDepend.Attributes;

namespace Hemit.OpPlan.Client.Infrastructure.Aspects
{
    /// Ndepend attribute to enable cyclic loops in methods in the source code 
    [CodeRule(@"// <Name>Avoid methods of a type to be in cycles. Detect also recursive property setter calls</Name>
warnif count > 0

from t in Application.Types
                 .Where(t => t.ContainsMethodDependencyCycle != null && 
                             t.ContainsMethodDependencyCycle.Value)

// Optimization: restreint methods set
// A method involved in a cycle necessarily have a null Level.
let methodsSuspect = t.Methods.Where(m => m.Level == null)

// hashset is used to avoid iterating again on methods already caught in a cycle.
let hashset = new HashSet<IMethod>()


from suspect in methodsSuspect
   // By commenting this line, the query matches all methods involved in a cycle.
   where !hashset.Contains(suspect)

   // Define 2 code metrics
   // - Methods depth of is using indirectly the suspect method.
   // - Methods depth of is used by the suspect method indirectly.
   // Note: for direct usage the depth is equal to 1.
   let methodsUserDepth = methodsSuspect.DepthOfIsUsing(suspect)
   let methodsUsedDepth = methodsSuspect.DepthOfIsUsedBy(suspect)

   // Select methods that are both using and used by methodSuspect
   let usersAndUsed = from n in methodsSuspect where 
                         methodsUserDepth[n] > 0 && 
                         methodsUsedDepth[n] > 0 
                      select n

   where usersAndUsed.Count() > 0

   // Here we've found method(s) both using and used by the suspect method.
   // A cycle involving the suspect method is found!
   let cycle = System.Linq.Enumerable.Append(usersAndUsed,suspect)


   // Fill hashset with methods in the cycle.
   // .ToArray() is needed to force the iterating process.
   let unused1 = (from n in cycle let unused2 = hashset.Add(n) select n).ToArray()

let cycleContainsSetter = (from n1 in cycle where n1.IsPropertySetter select n1).Count()

  
select new { suspect, cycle, cycleContainsSetter }",
        Active = true,
        DisplayStatInReport = true,
        DisplayListInReport = true,
        DisplaySelectionViewInReport = true,
        IsCriticalRule = false)]
    public class MethodCycleDetectionAttribute : Attribute
    {
    }
}

Note that this Ndepend Code rule uses the CQLinq syntax placed into a C# attribute class that inherits from Attribute and itself is attributed with a Ndepend.Attributes.CodeRuleAttribute. I had to adjust the attribute a little bit using the ExtensionMethodsEnumerable fix for .Net 4.6.2 mentioned on Ndepend blog post here: https://blog.ndepend.com/problem-extension-methods/ The following screen shot shows Visual Studio 2019 with Ndepend version 2019.2.5 installed. It shows the method cycle detection code rule I created showing up as a code rule through source code. Selecting that code rule in the menu Ndepend => Rules Explorer that selects Queries and Rules Explorer allows to not only view the code rule but quickly see the code analysis results.

One method cycle I have is shown in the following image, the method ProcessPasRequest of my system. This case shows how advanced Ndepend really is in code analysis. It can detect transitive cycles with multiple function calls. The following two screen shots shows the cycle in question. In this case, it was not a bug, since the cycle will only happend a finite amount of times for a given set of patients, but it still can go into an infinite loop if the external system is not working correct. However in this case, if that external system is not working, the system I have been working with also faults as it relies on that external system. With Ndepend I could spot method cycles with transitive cycles with a breeze! I can also spot property getter and setter cycles, as property getters and setters in C# are methods anyways (compiler generated). I managed to get Ndepend back to the main menu in Visual Studio 2019 using this extension.

https://marketplace.visualstudio.com/items?itemName=Evgeny.RestoreExtensions