I want to create a tile system with isometric blocks I've finally after a lot of trial and error got it working with this code,

```
function worldGen(){
var lvl = 100;
for (x=0; x<=50; x++){
imageObj.src = "grass.png";
square.n.push(imageObj);
}
//Corner Top
console.log("Top Corner")
for(x=1; x<=1; x++){
for(y=0; y<=1; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+40*5-lvl);
square.y[n] = (y*64+32*3);
context.drawImage(square.n[n], square.y[y], square.x[x], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=2; x<=2; x++){
for(y=0; y<=2; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+40*4-lvl);
square.y[n] = (y*64+32*2);
context.drawImage(square.n[n], square.y[y], square.x[x], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=3; x<=3; x++){
for(y=0; y<=3; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+40*3-lvl);
square.y[n] = (y*64+32*1);
context.drawImage(square.n[n], square.y[y], square.x[x], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=4; x<=4; x++){
for(y=0; y<=4; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+40*2-lvl);
square.y[n] = (y*64);
context.drawImage(square.n[n], square.y[y], square.x[x], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=5; x<=5; x++){
for(y=0; y<=5; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+40-lvl);
square.y[n] = (y*64-32);
context.drawImage(square.n[n], square.y[y], square.x[x], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
//Center
console.log("Start Center Gen")
for(z=0; z<=5; z++){
for(x=6; x<=6; x++){
for(y=0; y<=5; y++){
for(n=2; n<=50; n++){
square.x[x] = (x*64+(24*z)-lvl);
square.y[y] = (y*64+(32*z));
context.drawImage(square.n[n], square.y[y], square.x[x], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
}
//Bottom Corner
console.log("Start Bottom Corner")
for(x=6; x<=6; x++){
for(y=0; y<=4; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+44);
square.y[n] = (y*64+32*6);
context.drawImage(square.n[n], square.y[n], square.x[n], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
console.log("Start Bottom Corner")
for(x=6; x<=6; x++){
for(y=0; y<=4; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+44);
square.y[n] = (y*64+32*6);
context.drawImage(square.n[n], square.y[n], square.x[n], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=7; x<=7; x++){
for(y=0; y<=3; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64+4);
square.y[n] = (y*64+32*7);
context.drawImage(square.n[n], square.y[n], square.x[n], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=8; x<=8; x++){
for(y=0; y<=2; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64-36);
square.y[n] = (y*64+32*8);
context.drawImage(square.n[n], square.y[n], square.x[n], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=9; x<=9; x++){
for(y=0; y<=1; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64-38*2);
square.y[n] = (y*64+32*9);
context.drawImage(square.n[n], square.y[n], square.x[n], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
for(x=10; x<=10; x++){
for(y=0; y<=0; y++){
for(n=1; n<=50; n++){
square.x[n] = (x*64-39*3);
square.y[n] = (y*64+32*10);
context.drawImage(square.n[n], square.y[n], square.x[n], 64, 64);
console.log("Tile X: "+x+" | Tile Y: "+y+" - X Pos: "+square.x[x]+" | Y Pos: "+square.y[y]);
}
}
}
}
```

}

but there is a list of things it isn't doing, it isn't allowing a change of size, it isn't actually a diamond, and it seems pretty clunky for what I think diamond generation would look like. any help would be appreciated.