Forging method and forging die

What is claimed is: 1. A forging method comprising: a placement step of placing a work having a first shape which is a rectangular hexahedron in a work space of a forging die, the forging die comprising the work space having a rectangular opening, being formed by rectangular plane wall portions, and being provided for holding the work, a substantially vertically-slidable upper die indenter, and a substantially-horizontally slidable pedestal portion defining a bottom of the work space, wherein a space communicating to outside of the work space is formed by sliding the pedestal portion; and a working step of applying, with the upper die indenter and the pedestal portion, a plastic strain to the work by deforming the placed work into a second shape which is a rectangular hexahedron, wherein placing the work in the work space of the forging die and applying, with the upper die indenter and the slidable pedestal portion of the plastic strain at least two times deforms the work in the x-axis direction, the y-axis direction, and the z-axis direction. 2. The forging method according to claim 1 , wherein the forging die includes an outer die which has a circular opening and which is provided with the inner peripheral surface of the circle and an inner die which forms the work space while a plurality of die parts of the inner die are combined and are fitted into the inner periphery of the outer die. 3. The forging method according to claim 1 , wherein in the forging die, an inner die is composed of a plurality of die parts which are separated from each other at corner portions formed by two planes of the work space. 4. The forging method according to claim 1 , wherein the forging die includes a base portion constituting the bottom of the work space, and the base portion is provided with a flow path, through which a cooling medium passes. 5. The forging method according to claim 1 , wherein in the placement step, the work and the work space define a volume ratio, the volume ratio being a ratio of a volume of the work space to a volume of the work, within a range of 1.20 or more and 3.50 or less. 6. The forging method according to claim 1 , wherein during the placement step, the ratio of lengths of the individual sides (side X, side Y, and side Z) of the work are x:y:z, the volume ratio of the work space to the work is within a range of (y/x)×(z/y)×z(1+α)/z; (where x<y<z, 1.03x≦y≦1.49x, 1.06x≦z≦2.22x, z=(y/x) 2 x, and 0<α≦0.5 are satisfied), and during the working step, a pressure is applied by the upper die indenter against an upper surface of the work to press in by an amount of (z−x). 7. The forging method according to claim 6 , wherein during the placement step, the range is 1.10x≦y≦1.20x and 1.21x≦z≦1.44x. 8. The forging method according to claim 1 , wherein during the working step, the work is deformed at a working ratio, the working ratio being an amount of work deformation divided by an original dimension of the work, expressed as an amount of strain, is within the range of 6% or more and less than 55%. 9. The forging method according to claim 8 , wherein during the working step, the work is deformed at the working ratio is within the range of 18% or more and less than 33%. 10. The forging method according to claim 1 , wherein the work is an alloy containing Be and Cu. 11. The forging method according to claim 1 , wherein after placing the work in the work space of the forging die and applying, with the upper die indenter and the slidable pedestal portion, the plastic strain at least two times the work having the first shape and the work having the second shape are different in length in the x-axis direction, the y-axis direction, and the z-axis direction. 12. The forging method according to claim 1 , wherein the forging die further comprises an inner die that is composed of a plurality of die parts having a concave portion and a convex portion that are fitted with each other to form an integral structure of the inner die. 13. A forging die used in a forging method that applies a plastic strain to a work by deforming the work having a first shape which is a rectangular hexahedron into a work having a second shape which is a rectangular hexahedron, the forging die comprising: an outer die which has a circular opening and which is provided with the inner peripheral surface of the circle; an inner die which has a rectangular opening and in which a work space for holding the work is formed by rectangular plane wall portions while a plurality of die parts are combined and are fitted into the inner periphery of the outer die; a substantially-vertically slidable upper die indenter positioned to be slidable into the work space; and a slidable pedestal portion defining a bottom of the work space, and positioned to be slidable into the work space; wherein a space communicating to outside of the work space is formed by sliding the pedestal portion; and wherein the outer die, the inner die, the upper die indenter, and the slidable pedestal portion are configured, after placing the work in the work space and applying a strain thereto with the upper die indenter and the slidable pedestal portion at least two times, the work is deformed in the x-axis direction, the y-axis direction, and the z-axis direction. 14. The forging die according to claim 13 , wherein the inner die is composed of the plurality of die parts which are separated from each other at corner portions formed by two planes of the work space. 15. The forging die according to claim 13 , comprising a base portion constituting the bottom of the work space, wherein the base portion is provided with a flow path, through which a cooling medium passes. 16. The forging die according to claim 13 , comprising: a base portion defining a bottom of the work space, and a lift mechanism which is disposed in the base portion and which lifts the work by pushing the bottom of the work held in the work space. 17. The forging die according to claim 13 , wherein the inner die is composed of the plurality of die parts having a concave portion and a convex portion that are fitted with each other to form an integral structure of the inner die.