Go through and express your rectangles not as (x,y,w,h) but as (x1,y1,x2,y2), which is simply (x,y,x+w,y+h).
Then, loop over all Rj`s and "clip" the rectangles to the coordinates of Rect1:
Rj.x1 = max(Rj.x1, Rect1.x1)
Rj.y1 = max(Rj.y1, Rect1.y1)
Rj.x2 = min(Rj.x2, Rect1.x2)
Rj.y2 = min(Rj.y2, Rect1.y2)
Now, go through and remove any Rj's where
Rj.y1>=Rj.y2 as in that case, the rectangles didn't intersect.
After, sum up all the areas of the remaining rectangles (simply
(Rj.x2-Rj.x1) * (Rj.y2-Rj.y1)).
At this point, you will have double-counted any area where any of the clipped Rj`s overlap.
So, you then need to go through and loop over all Ri's and all Rj's where j>i and, clip the two with each other, but this time, if there is an intersection (same test as above), you need to subtract the area of the intersection from the value you have so far to remove the double-counting.
Unfortunately, this will double-remove any areas of a triple-overlap. So, you will then need to find those areas and add them back in. And so on and so forth for quadruple-overlaps, quintuple-overlaps, etc.
Sounds like it'll get pretty messy...
Maybe the easiest is to just draw the Rj's to a canvas in red and then count the red pixels inside Rect1 at the end. (Of course, you don't have to use a real Canvas. You can write your own using a bit-array.) There might even be scenarios (like a small coordinate space with lot's of tiny rectangles), where this is faster than the analytical solution. But, of course this will only work if you have integer coordinates.