Controlling valve operation using pressure

What is claimed is: 1 . A valve, comprising: a valve body including an interior surface; a fluid inlet communicating fluid into an interior of the valve body; a piston slideable successively through first, second, third, and fourth positions within the valve body and including: a head, a skirt forming an upper skirt portion connected to and extending from the head in a direction of the fluid inlet, the upper skirt portion forming a seal against the interior surface of the valve body; a piston port formed in the upper skirt portion; a low pressure port formed through the interior surface of the valve body, the low pressure port sealed against the interior of the valve body when the piston is in the first and third positions, the low pressure port in fluid communication with the piston port when the piston is in the second position; a high pressure port formed through the interior surface of the valve body, the high pressure port in fluid communication with the piston port when the piston is in the fourth position; and a biasing element positioned within the valve body to urge the piston head in a direction of the first position, the piston moveable against a biasing force of the biasing element to slide successively from the first to the fourth position as the pressure at the fluid inlet is increased. 2 . The valve of claim 1 , further including a lower skirt portion connected to and extending from the head in a direction away from the fluid inlet, the lower skirt portion forming a seal against the interior surface of the valve body. 3 . The valve of claim 2 , the lower skirt portion forming a seal against the low pressure port and the high pressure port when the piston is in the first position. 4 . The valve of claim 2 , the lower skirt portion forming a seal against the high pressure port when the piston is in the second position. 5 . The valve of claim 2 , the lower skirt portion forming a seal against the high pressure port when the piston is in the second position and the third position, the upper skirt portion forming a seal against the low pressure port when the piston is in the third position. 6 . The valve of claim 1 , wherein the biasing element is a spring. 7 . The valve of claim 1 , further including at least one tab connected to the valve body and slideable within a slot in the piston skirt to prevent rotation of the skirt. 8 . The valve of claim 1 , wherein the piston has the form of a cylinder. 9 . The valve of claim 1 , further including a lower skirt portion connected to and extending from the head in a direction away from the fluid inlet, the piston forming the shape of a cylinder having two open ends, and an interior closed by the piston head. 10 . The valve of claim 1 , further including: a fluid retaining chamber disposed at an outlet of at least one of the low and high pressure ports; and a membrane dividing the chamber, the membrane displaceable by fluid passing under pressure into the chamber from the at least one of the low and high pressure ports, the membrane movable to a non-displaced configuration to gradually release fluid passed into the chamber when fluid is not passing into the chamber. 11 . A method of irrigating plants, comprising: positioning along a supply line of water, a plurality of valves, each valve including: a valve body including an interior surface; a fluid inlet communicating fluid into an interior of the valve body; a piston slideable successively through first, second, third, and fourth positions within the valve body and including: a head, a skirt forming an upper skirt portion connected to and extending from the head in a direction of the fluid inlet, the upper skirt portion forming a seal against the interior surface of the valve body; a piston port formed in the upper skirt portion; a low pressure port formed through the interior surface of the valve body, the low pressure port sealed against the interior of the valve body when the piston is in the first and third positions, the low pressure port in fluid communication with the piston port when the piston is in the second position; a high pressure port formed through the interior surface of the valve body, the high pressure port in fluid communication with the piston port when the piston is in the fourth position; a biasing element positioned within the valve body to urge the piston head in a direction of the first position, the piston moveable against a biasing force of the biasing element to slide successively from the first to the fourth position as the pressure at the fluid inlet is increased configuring first and second sets of valves differently, wherein configuring differently includes providing valves in the first set relative to the second set with at least one of a different biasing element and a different position of the low pressure port, wherein the low pressure port of valves of the first set open at a first pressure, and the low pressure port of valves of the second set open at a second pressure greater than the first pressure, and the low pressure port of the first set are closed at the second pressure; supplying water to the supply line at the first pressure wherein valves of the first set flow water, and valves of the second set do not flow water; and supplying water to the supply line at the second pressure, wherein valves of the second set flow water, and valves of the first set do not flow water. 12 . The method of claim 11 , wherein configuring includes opening the valve body and replacing at least one of the piston and the biasing element, and closing the valve body. 13 . The method of claim 11 , wherein the biasing element is a gas or liquid under pressure admitted to a side of the piston head opposite to a side of the piston head in fluid communication with the fluid inlet. 14 . The method of claim 11 , wherein the supply line is between 1 and 1000 feet and includes between 1 and 1000 valves. 15 . The method of claim 11 , wherein the supply line is a drip irrigation supply line. 16 . The method of claim 11 , wherein the piston further includes a lower skirt portion connected to and extending from the head in a direction away from the fluid inlet, the lower skirt portion forming a seal against the interior surface of the valve body, and wherein supplying water at the first pressure includes blocking the high pressure port with the lower skirt portion. 17 . The method of claim 11 , wherein the piston further includes a lower skirt portion connected to and extending from the head in a direction away from the fluid inlet, the lower skirt portion forming a seal against the interior surface of the valve body, and wherein supplying water at an intermediate pressure between the first pressure and the second pressure includes blocking the low pressure port with the upper skirt portion, and blocking the high pressure port with the lower skirt portion. 18 . The method of claim 11 , further including supplying water at a third pressure higher than the first pressure and the second pressure, wherein the high pressure port of all of the first and second sets of valves are open. 19 . The method of claim 11 , wherein the valve further includes a fluid retaining chamber disposed at an outlet of at least one of the low and high pressure ports; a membrane dividing the chamber, the membrane displaceable by fluid passing through the piston port and out of the valve body and into the chamber, the membrane movable to a non-displaced configuration to gradually releas