Four-legged construction machine having slope stability system with locking valves

What is claimed is: 1. A machine for roadwork comprising: a frame; a plurality of ground engaging units including a first rear ground engaging unit and a second rear ground engaging unit; a plurality of vertically moveable legs, each leg connecting one of the plurality of ground engaging units to the frame, the plurality of vertically moveable legs including a first rear leg connected to the first rear ground engaging unit and a second rear leg connected to the second rear ground engaging unit; and a hydraulic system to control a height of each of the plurality of vertically moveable legs, the hydraulic system comprising: a fluid circuit to control fluid between the first rear leg and the second rear leg; a load holding valve to let fluid into and out of the fluid circuit; a control valve system to let fluid into and out of the load holding valve, the control valve connected to a source of pressurized hydraulic fluid and a fluid reservoir; a first lock valve to control flow of fluid from the first rear leg to the second rear leg in a first direction; a second lock valve to control flow of fluid from the second rear leg to the first rear leg in a second direction; a first float valve configured to connect the first rear leg to the control valve system; and a second float valve configured to connect the second rear leg to the control valve system; wherein the first and second float valves each comprise two-way valves having a first directional flow configuration and a second directional flow configuration. 2. A machine for road work comprising: a frame; a plurality of ground engaging units including a first rear ground engaging unit and a second rear ground engaging unit; a plurality of vertically moveable legs, each leg connecting one of the plurality of ground engaging units to the frame, the plurality of vertically moveable legs including a first rear leg connected to the first rear ground engaging unit and a second rear leg connected to the second rear ground engaging unit; and a hydraulic system to control a height of each of the plurality of vertically moveable legs, the hydraulic system comprising: a fluid circuit to control fluid between the first rear leg and the second rear leg; a load holding valve to let fluid into and out of the fluid circuit; a control valve system to let fluid into and out of the load holding valve, the control valve connected to a source of pressurized hydraulic fluid and a fluid reservoir; a first lock valve to control flow of fluid from the first rear leg to the second rear leg in a first direction; a second lock valve to control flow of fluid from the second rear leg to the first rear leg in a second direction; a first float valve configured to connect the first rear leg to the control valve system; and a second float valve configured to connect the second rear leg to the control valve system, wherein each of the first and second legs comprises: a cylinder; a piston disposed in the cylinder; and a rod extending from the piston out of the cylinder; wherein the first and second lock valves connect to piston-ends of the cylinders; and wherein the first and second float valves connect the first and second lock valves to the load holding valve. 3. The machine for road work of claim 1 , wherein the first and second lock valves each comprise two-way valves having a free-flow configuration and a checked-flow configuration. 4. The machine for road work of claim 1 , wherein: the first directional flow configuration of the first and second float valves connects the first and second rear legs to the first and second lock valves; and the second directional flow configuration of the first and second float valves connects the first and second rear legs to the control valve. 5. The machine for road work of claim 1 , wherein the control valve system further comprises: a low pressure supply valve configured to receive a first fluid pressure from the source of pressurized fluid at an inlet and provide a second fluid pressure at an outlet, the second fluid pressure less than the first fluid pressure; and a float pressure valve configured to connect the outlet of the low pressure supply valve to the first and second float valves. 6. The machine for road work of claim 1 , further comprising a controller configured to receive sensor information related to a center of gravity of the machine for roadwork, the controller configured to operate one of the first and second lock valves in response to determining a center of gravity of the machine for roadwork is at or beyond a threshold center of gravity value. 7. The machine for road work of claim 6 , further comprising a multi-axis slope sensor coupled to the frame to detect a pitch and slope of the frame, wherein the multi-axis slope sensor generates the sensor information. 8. The machine for road work of claim 6 , further comprising a liquid level sensor for sensing a fluid level in a liquid tank mounted to the machine for road work or a position sensor for a conveyor mounted to the machine for road work for sensing a position of a conveyor relative to the frame, wherein the liquid level sensor or the position sensor generates the sensor information. 9. The machine for road work of claim 6 , further comprising a pressure sensor for at least one of the plurality of vertically moveable legs for sensing a hydraulic pressure within the at least one of the plurality of vertically moveable legs, wherein the pressure sensor generates the sensor information. 10. A method for controlling side-to-side slope of a four-legged construction machine having multiple independent propulsors each mounted to a hydraulic lifting device, the method comprising: adjusting a height of first and second rear hydraulic lifting devices of the multiple independent propulsors by connecting to a high pressure source; traversing a ground surface having a changing topography with the multiple independent propulsors; floating individual heights of the first and second rear hydraulic lifting devices in a fluid circuit; activating a lock valve positioned between the first and second rear hydraulic lifting devices to inhibit flow out of a piston-end of the first rear hydraulic lifting device; activating a float valve positioned between the lock valve and the second rear hydraulic lifting device to connect a piston-end of the second rear hydraulic lifting device to a low pressure source; and lifting the first rear hydraulic lifting device by: activating a second lock valve positioned between the first lock valve and the first rear hydraulic lifting device to connect the piston-end of the first rear hydraulic lifting device to the high pressure source. 11. The method of claim 10 , wherein the lock valve and the float valve are activated by operator action. 12. The method of claim 10 , wherein the lock valve and the float valve are activated when a center of gravity of the four-legged construction machine moves outside an operating envelope. 13. The method of claim 12 , wherein the center of gravity of the machine is calculated using a slope sensor. 14. The method of claim 13 , wherein the center of gravity of the machine is further calculated using input from a liquid tank level sensor mounted to the four-legged construction machine. 15. The method of claim 13 , wherein the center of gravity of the machine is further calculated using input from a position sensor for a conveyor mounted to the four-legged construction machine. 16. The method of claim 10 , further comprising moving a control valve to connect a rod-end of the