无方块塔帕[No Squares Tapa]（方块塔防破解版无限金币钻石版）

Understanding the nuances of the circles and how they interact with each other is the key to solving a Masyu puzzle. Generally speaking, it is easiest to start along the outside border of the grid and work inwards. Here are some basic scenarios where portions of the loop can be determined:

• Any segment travelling from a black circle must travel two cells in that direction without intersecting another part of the loop or the outer border; each black cell must have two such segments at a right angle. The logical combination of those two statements is that if a segment from a black cell cannot be drawn in some orthogonal direction, a segment in the opposite direction must be drawn. For example, if one cannot legally travel up two cells from a black circle, then the loop must travel down from that black circle for two cells. This has two common results:
  • Any black circle along the outer border or one cell from the outer border must have a segment leading away from the border (and those sufficiently near a corner must lead from both walls, defining the loop's path through the circle);
  • Orthogonally adjacent black circles must have segments travelling away from each other.
  • Black circles that are orthogonally next to the end of the loop that does not travel towards it must have the loop heading away from the other loop segment.
• White circles along the outer border obviously need the loop to travel through them parallel to the border; if two white circles along a border are adjacent or are one cell apart, then the loop will need to turn away from the border just beyond the circles.
• If three or more white circles are orthogonally contiguous and collinear, then the loop will need to pass through each of those circles perpendicular to the line of circles.
• If two white circles are orthogonally contiguous and a cell on either end has a loop segment entering parallel to the line of the circles, then the loop will need to pass through each of those circles perpendicular to their line. (Otherwise, the line through them would connect to the adjacent segment and one of the white cells would not be next to a turn in the loop.)
• A black circle with two white circles diagonally adjacent on the same side must have the loop heading away from that side. If not, and it went between the white circles instead, then the white circles would be parallel to that section of the loop, and make it impossible to complete the black circle.
  • Black circles with three white circles diagonally adjacent can be fully completed by this rule.
• If the diagram is cut virtually into two pieces, the loop must cross the cutting line an even number of times. This is due to the Jordan Curve Theorem.