The scope of the unsafe block can be appropriately reduced

src/binary_heap.rs

@@ -942,8 +942,8 @@ impl<T, C: Compare<T>> BinaryHeap<T, C> {
             //  so it's always a valid index to access.
             //  It is safe to access index 0 (i.e. `ptr`), because
             //  1 <= end < self.len(), which means self.len() >= 2.
+            let ptr = self.data.as_mut_ptr();
             unsafe {
-                let ptr = self.data.as_mut_ptr();
                 ptr::swap(ptr, ptr.add(end));
             }
             self.sift_down_range(0, end);
@@ -960,47 +960,47 @@ impl<T, C: Compare<T>> BinaryHeap<T, C> {
     // Using a hole reduces the constant factor compared to using swaps,
     // which involves twice as many moves.
     fn sift_up(&mut self, start: usize, pos: usize) -> usize {
-        unsafe {
+
             // Take out the value at `pos` and create a hole.
-            let mut hole = Hole::new(&mut self.data, pos);
+            let mut hole = unsafe { Hole::new(&mut self.data, pos) };
 
             while hole.pos() > start {
                 let parent = (hole.pos() - 1) / 2;
                 // if hole.element() <= hole.get(parent) {
-                if self.cmp.compare(hole.element(), hole.get(parent)) != Ordering::Greater {
+                if self.cmp.compare(hole.element(), unsafe { hole.get(parent) }) != Ordering::Greater {
                     break;
                 }
-                hole.move_to(parent);
+                unsafe { hole.move_to(parent) };
             }
             hole.pos()
-        }
+
     }
 
     /// Take an element at `pos` and move it down the heap,
     /// while its children are larger.
     fn sift_down_range(&mut self, pos: usize, end: usize) {
-        unsafe {
-            let mut hole = Hole::new(&mut self.data, pos);
+
+            let mut hole = unsafe { Hole::new(&mut self.data, pos) };
             let mut child = 2 * pos + 1;
             while child < end - 1 {
                 // compare with the greater of the two children
                 // if !(hole.get(child) > hole.get(child + 1)) { child += 1 }
-                child += (self.cmp.compare(hole.get(child), hole.get(child + 1))
+                child += (self.cmp.compare(unsafe { hole.get(child) }, unsafe { hole.get(child + 1) })
                     != Ordering::Greater) as usize;
                 // if we are already in order, stop.
                 // if hole.element() >= hole.get(child) {
-                if self.cmp.compare(hole.element(), hole.get(child)) != Ordering::Less {
+                if self.cmp.compare(hole.element(), unsafe { hole.get(child) }) != Ordering::Less {
                     return;
                 }
-                hole.move_to(child);
+                unsafe { hole.move_to(child) };
                 child = 2 * hole.pos() + 1;
             }
             if child == end - 1
-                && self.cmp.compare(hole.element(), hole.get(child)) == Ordering::Less
+                && self.cmp.compare(hole.element(), unsafe { hole.get(child) }) == Ordering::Less
             {
-                hole.move_to(child);
+                unsafe { hole.move_to(child) };
             }
-        }
+
     }
 
     fn sift_down(&mut self, pos: usize) {