Pressure lock for jars

What is claimed: 1. A jar comprising: a mandrel; an outer housing slidably disposed about the mandrel; a low pressure chamber formed between the mandrel and the outer housing; a high pressure chamber formed between the mandrel and the outer housing; a fluid passage extending between the low and high pressure chambers; a first port connecting the low pressure chamber to the fluid passage; a second port connecting the high pressure chamber to the fluid passage; and a valve axially movably disposed in the fluid passage, the valve selected from the group consisting of a needle valve and a seal rod. 2. The jar of claim 1 , wherein the valve comprises a needle valve configured to seal the second port, thereby allowing pressure to build in the high pressure chamber. 3. The jar of claim 2 , wherein the needle valve translates axially as wellbore annulus pressure increases to seal the second port. 4. The jar of claim 2 , wherein the needle valve translates axially as wellbore annulus pressure decreases to permit fluid communication in the fluid passage between the first port and the second port. 5. The jar of claim 1 , further comprising a plunger disposed in the fluid passage. 6. The jar of claim 5 , wherein the plunger is configured to translate axially as pressure increases to cause the seal rod to close the fluid passage. 7. The jar of claim 6 , wherein an increase in pressure increases the temperature in the fluid passage and the increase in temperature expands the seal rod. 8. A drilling jar comprising: a mandrel; an outer housing around at least a portion of the mandrel; and a safety bypass configured to lock the jar when exposed to ambient wellbore pressure, the safety bypass including: a low pressure chamber radially between the mandrel and the outer housing; a high pressure chamber radially between the mandrel and the outer housing; a first port extending radially outward from the low pressure chamber; a second port extending radially outward from the high pressure chamber; a fluid passage connecting the first port and the second port; and a valve within the fluid passage and configured to move axially in response to wellbore pressure. 9. The drilling jar of claim 8 , the valve configured to seal the second port as wellbore annulus pressure increases, thereby allowing pressure to build in the high pressure chamber. 10. The drilling jar of claim 8 , the needle configured to permit fluid flow from the second port, into the fluid passage, and to the first port as wellbore annulus pressure decreases to restrict the pressure from building in the high pressure chamber. 11. The drilling jar of claim 8 , the valve including a needle valve or plunger. 12. The drilling jar of claim 8 , further comprising: a detent piston configured to transmit force on the mandrel to the outer housing. 13. The drilling jar of claim 12 , further comprising: a lower chamber between the housing and the mandrel, the detent piston configured to increase fluid pressure in the lower chamber in response to the force being applied to the mandrel. 14. The drilling jar of claim 13 , the fluid pressure in the lower chamber being directly proportional to the force applied to the mandrel. 15. The drilling jar of claim 13 , further comprising an upper chamber configured to receive fluid from the lower chamber. 16. The drilling jar of claim 15 , flow of fluid from the lower chamber to the upper chamber configured to cause relative axial movement between the outer housing and the mandrel. 17. A method of locking a jar from inadvertent actuation, comprising: tripping jar into a wellbore, the jar including a mandrel movably located within an outer housing, upper and lower chambers between the mandrel and the outer housing and configured to transfer fluid therebetween to activate the jar, and a safety bypass selectively providing fluid flow between a high pressure chamber and a low pressure chamber between the mandrel and the outer housing, through ports and a fluid passage connecting the high and low pressure chambers; in response to increased pressure in a wellbore annulus, moving a needle valve or seal rod valve of the safety bypass within the fluid passage and thereby blocking fluid flow between the high and low pressure chambers in the safety bypass valve; activating the jar; tripping the jar out of the wellbore, which includes exposing the safety bypass to reduced pressure in the wellbore annulus; and in response to the pressure decreasing in the wellbore annulus, moving the valve of the safety bypass within the fluid passage and thereby enabling fluid flow between the high and low pressure chambers in the safety bypass valve.