How do I downgrade Android SDK emulator version?

I was trying to run Android Studio Emulator on my old 13-inch Mid 2012 MacBook Pro (Mac OS X Catalina, version 10.15.7). Every time I tried to start a Virtual Device it failed to start, it crashed all the time. Checking the idea.log, which located at $HOME/Library/Logs/Google/AndroidStudio2023.1/, give me some hints.

The log tells me that the current installed emulator was build for the newer version of MacBook Pro and newer Mac OS, in this case the Mac OS X 11.1. So to make the Android SDK Emulator run again on my MacBook Pro, I need to downgrade my Android emulator version.

Here are the clues from the log file:

2024-02-11 07:30:14,110 [7595298]   INFO - Emulator: Medium Phone API 27 - /Users/wayan/Library/Android/sdk/emulator/emulator -netdelay none -netspeed full -avd Medium_Phone_API_27 -qt-hide-window -grpc-use-token -idle-grpc-timeout 300
2024-02-11 07:30:14,200 [7595388]   INFO - Emulator: Medium Phone API 27 - Android emulator version (build_id 11237101) (CL:N/A)
2024-02-11 07:30:14,200 [7595388]   INFO - Emulator: Medium Phone API 27 - Found systemPath /Users/wayan/Library/Android/sdk/system-images/android-27/google_apis_playstore/x86/
2024-02-11 07:30:15,424 [7596612]   INFO - Emulator: Medium Phone API 27 - dyld: Symbol not found: _vmnet_e
2024-02-11 07:30:15,428 [7596616]   INFO - Emulator: Medium Phone API 27 - nable_isolation_key
2024-02-11 07:30:15,429 [7596617]   INFO - Emulator: Medium Phone API 27 - Referenced
2024-02-11 07:30:15,429 [7596617]   INFO - Emulator: Medium Phone API 27 - from: /Users/wayan/Library/Android/sdk/emulator/qemu/darwin-x86_64/qemu-system-i386 (which was built for Mac OS X 11.1)
2024-02-11 07:30:15,429 [7596617]   INFO - Emulator: Medium Phone API 27 - Expected in: /System/Library/Frameworks/vmnet.framework/Versions/A/vmnet
2024-02-11 07:30:15,429 [7596617]   INFO - Emulator: Medium Phone API 27 - in /Users/wayan/Library/Android/sdk/emulator/qemu/darwin-x86_64/qemu-system-i386
2024-02-11 07:30:15,430 [7596618]   INFO - Emulator: Medium Phone API 27 - Process finished with exit code 134 (interrupted by signal 6: SIGABRT)
2024-02-11 07:30:15,431 [7596619] SEVERE - Emulator: Medium Phone API 27 - Emulator terminated with exit code 134
java.lang.Throwable: Emulator terminated with exit code 134
    at com.intellij.openapi.diagnostic.Logger.error(
    at jdk.internal.reflect.GeneratedMethodAccessor40.invoke(Unknown Source)

So these are the steps that I need to do to downgrade it:

  • Download an older version of Android Emulator, here is the link to Android Emulator archive:
  • I download version 30.7.4.
  • Locate the current emulator directory, which is under my Android SDK installation directory at $HOME/Library/Android/sdk.
  • Rename the existing emulator directory from emulator to emulator_original.
  • Next, I unzip the downloaded emulator,, and copy it to the same location where the original emulator was located.
  • In the SDK installation directory, run the following command xattr -dr emulator/ from the terminal app to clear the quarantine attribute on the emulator package.
  • Copy the package.xml file from the emulator_original directory to the emulator directory.
  • Change the emulator version in the package.xml file, it located at the end of the file. It should look something like:

After downgrading the emulator, I restarted the Android Studio, and I can now start the emulator successfully and able to run and test my application in the old MacBook Pro again.

How do I format a number as percentage with fraction digits?

In Java, the NumberFormat class of java.text package can be used to format numbers. For formatting a number as a percentage string with fraction digits, you can use the getPercentInstance() method that returns a percentage format for the current default Locale.

Here is a sample code snippet showing how to format a number as a percentage string with two digits of fractions:

package org.kodejava.text;

import java.text.NumberFormat;

public class FormatPercentage {
    public static void main(String[] args) {
        double number = 0.12345;

        // Get an instance of NumberFormat for percentage
        NumberFormat percentFormat = NumberFormat.getPercentInstance();

        // Set the fraction digits - change this value to control the
        // number of fraction digits.
        percentFormat.setMinimumFractionDigits(2); // set the minimum
        percentFormat.setMaximumFractionDigits(4); // set the maximum

        // Format the number as a percentage
        String formattedPercent = percentFormat.format(number);

        System.out.println("Number as percentage: " + formattedPercent);


Number as percentage: 12.345%

In the above example, 0.12345 will be formatted as 12.35% because we have set the MinimumFractionDigits to 2 which means up to two decimal points will be included in the formatted percentage. If we also set the MaximumFractionDigits it will allow us to have up to four decimal points in the output value, here we have 12.345%.

Note that the actual percentage is calculated by multiplying the number by 100, so 0.12345 becomes 12.345% and then rounded to 12.35% (because of the fraction digits setting, in this case we only set the minimum fraction digits to two decimal points).

We can also use the DecimalFormat class. The DecimalFormat class in Java is used to format decimal numbers. It is a subclass of NumberFormat and you can customize the format of your number using it.

Here’s a simple example of how you can format a number as a percentage string using DecimalFormat:

package org.kodejava.text;

import java.text.DecimalFormat;

public class DecimalFormatPercentDemo {
    public static void main(String[] args) {
        double number = 0.123;

        // Create a new DecimalFormat instance with a percentage pattern
        DecimalFormat df = new DecimalFormat("#%");

        // Set the number of fraction digits 

        // Format the number into a percentage
        String percentage = df.format(number);


This program will output 12.30%

The "#%" pattern means that the number should be formatted as a percentage. And df.setMinimumFractionDigits(2); means that the decimal will be formatted to two places.

The DecimalFormat will automatically multiply our value by 100, which is why 0.123 appears as 12.30%.

How do I create a table in PDF document using iText 8?

When it comes to generating PDF documents dynamically, iText 8 is a powerful and versatile Java library that provides a wide range of functionalities. One common requirement in PDF generation is the need to include tables to present structured data. In this blog post, we will explore how to create a table in a PDF document using the iText 8 library.

The Table class in iText 8 is a layout element that represents data in a two-dimensional grid. It allows you to create tables with rows and columns to organize and display data in a structured format.

To create a table using iText 8, we would first need to create an instance of Document class where the table will be added. We then define a Table object either by passing the number columns, or an array of float for the column width as parameter.

Here is how you can create a table with iText 8:

package org.kodejava.itext;

import com.itextpdf.kernel.colors.DeviceGray;
import com.itextpdf.kernel.colors.DeviceRgb;
import com.itextpdf.kernel.pdf.PdfWriter;
import com.itextpdf.kernel.pdf.PdfDocument;
import com.itextpdf.layout.Document;
import com.itextpdf.layout.element.Paragraph;
import com.itextpdf.layout.element.Table;
import com.itextpdf.layout.element.Cell;


public class CreateTable {
    public static void main(String[] args) throws FileNotFoundException {
        String destination = "table_example.pdf";
        PdfWriter writer = new PdfWriter(destination);

        PdfDocument pdf = new PdfDocument(writer);
        try (Document document = new Document(pdf)) {

            float[] pointColumnWidths = {150F, 200F, 100F};
            Table table = new Table(pointColumnWidths);

            // Add header cells to the table
            table.addHeaderCell(new Cell().add(new Paragraph("Id"))
            table.addHeaderCell(new Cell().add(new Paragraph("Name"))
            table.addHeaderCell(new Cell().add(new Paragraph("Age"))

            // Add cells to the table
            table.addCell(new Cell().add(new Paragraph("1")));
            table.addCell(new Cell().add(new Paragraph("Alice")));
            table.addCell(new Cell().add(new Paragraph("20")));

            table.addCell(new Cell().add(new Paragraph("2")));
            table.addCell(new Cell().add(new Paragraph("Bob")));
            table.addCell(new Cell().add(new Paragraph("25")));

            // Add table to document

This will create a new document with a table including three columns and three rows. The first row is the table header, we style it with a gray background, set the font weight to bold and center aligned the text.

iText 8 Table Example

Maven Dependencies


Maven Central

How do I use ConcurrentHasMap forEach() method?

The forEach() method in ConcurrentHashMap is used for iteration over the entries in the map. The method takes a BiConsumer as an argument, which is a functional interface that represents an operation that accepts two input arguments and returns no result.

Here’s an example of how to use forEach() with a ConcurrentHashMap:

package org.kodejava.util.concurrent;

import java.util.concurrent.ConcurrentHashMap;

public class ConcurrentHashMapForEachExample {
    public static void main(String[] args) {
        // Create a new ConcurrentHashMap
        ConcurrentHashMap<String, Integer> map = new ConcurrentHashMap<>();

        // Add some key-value pairs
        map.put("One", 1);
        map.put("Two", 2);
        map.put("Three", 3);
        map.put("Four", 4);

        // Use forEach to iterate over the ConcurrentHashMap.
        // The BiConsumer takes a key (k) and value (v), and we're
        // just printing them here.
        map.forEach((k, v) -> System.out.println("Key: " + k + ", Value: " + v));


Key: One, Value: 1
Key: Four, Value: 4
Key: Two, Value: 2
Key: Three, Value: 3

In the above example, forEach() is used to iterate over the entries of the map. For each entry, the key and value are printed. The forEach() method is often more convenient to use than an iterator, especially when you’re only performing a single operation (like print) for each entry in the map.

What is ConcurrentHasMap and how do I use it in Java?

ConcurrentHashMap is a class in Java that implements the ConcurrentMap interface. It is part of the Java Collection Framework and extends the AbstractMap class.

ConcurrentHashMap is thread-safe, which means it is designed to support high concurrency levels by handling multiple threads concurrently without any inconsistencies. It allows multiple threads to perform retrieve (get) and update (insert & delete) operations. Internally, ConcurrentHashMap uses concepts of Segmentation to store data which allows higher degree of concurrency.

Here is an example of how to use ConcurrentHashMap in Java:

package org.kodejava.util;

import java.util.concurrent.ConcurrentHashMap;

public class ConcurrentHashMapExample {
    public static void main(String[] args) {
        // Create a ConcurrentHashMap instance
        ConcurrentHashMap<String, Integer> map = new ConcurrentHashMap<>();

        // Add elements
        map.put("One", 1);
        map.put("Two", 2);
        map.put("Three", 3);

        // Retrieve elements
        Integer one = map.get("One");
        System.out.println("Retrieved value for 'One': " + one);

        // Remove an element

        // Print all elements
        map.forEach((key, value) -> System.out.println(key + " = " + value));


Retrieved value for 'One': 1
One = 1
Three = 3

In this example, we’re creating a ConcurrentHashMap, adding some elements to it, retrieving an element, removing an element, and finally printing all the elements.

One thing to note is that while ConcurrentHashMap allows multiple threads to read and write concurrently, a get() operation might not reflect the latest put() operation, since it might be looking at a previous segment. Further thread synchronization mechanisms might be necessary depending on your exact use case.

Also, worth mentioning, null values and null keys are not permitted in ConcurrentHashMap to prevent ambiguities and potential errors in multithreaded contexts. If you try to use null, ConcurrentHashMap will throw a NullPointerException.

Here’s an example demonstrating the usage of ConcurrentHashMap in a multithreaded context:

package org.kodejava.util;

import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.TimeUnit;

public class ConcurrentHashMapThreadDemo {
    public static void main(String[] args) throws InterruptedException {
        ConcurrentHashMap<String, Integer> map = new ConcurrentHashMap<>();

        // Create a ThreadPool with 5 threads
        try (ExecutorService executor = Executors.newFixedThreadPool(5)) {

            // Runnable task to increment a value in the map
            Runnable task = () -> {
                for (int i = 0; i < 10; i++) {
                    map.compute("TestKey", (key, value) -> {
                        if (value == null) {
                            return 1;
                        } else {
                            return value + 1;

            // Submit the task to each thread in the pool
            for (int i = 0; i < 5; i++) {

            // Shut down the executor and wait for tasks to complete
            if (!executor.awaitTermination(60, TimeUnit.SECONDS)) {

        System.out.println("Final value for 'TestKey': " + map.get("TestKey"));


Final value for 'TestKey': 50

In this example, we’re creating a ConcurrentHashMap and a thread pool with ExecutorService. We’re then defining a Runnable task, which increments the value of the “TestKey” key in the map 10 times.

The task uses ConcurrentHashMap‘s compute() method, which is atomic, meaning that the retrieval and update of the value is done as a single operation that cannot be interleaved with other operations. We then submit the task to each of the five threads in our thread pool. After all threads have completed their tasks, we retrieve and print the final value of “TestKey”.

If everything works correctly, the output should be “Final value for ‘TestKey’: 50”, because we have 5 threads each incrementing the value 10 times. This demonstrates the thread-safety of ConcurrentHashMap, as the compute() operation is done atomically and many threads were able to modify the map simultaneously without causing inconsistencies. If we were using a plain HashMap instead, we could not guarantee this would be the case.