Bidirectionally testable seal configuration

We claim: 1. A tubular carrier device for disposal in a well at an oilfield, the carrier device comprising: a tubular mechanism with a bore side at an interior thereof and an annular side to an exterior thereof; a test gauge for acquiring information from both the bore side and the annular side of the tubular mechanism; and a seal assembly at an interface between the test gauge and the tubular mechanism, the assembly having a bore side test port device pressurizably coupled to a first unidirectional seal and annular side test port device pressurizably coupled to a second unidirectional seal, the bore side test port device configured to detect failure of the second unidirectional seal and the annular side test port device configured to detect failure of the first unidirectional seal. 2. The tubular carrier device of claim 1 wherein the unidirectional seals are oppositely oriented c-rings. 3. The tubular carrier device of claim 1 wherein the seal assembly further comprises one of a bidirectional hydraulic gland and an elastomeric o-ring. 4. The tubular carrier device of claim 3 wherein the hydraulic gland is a ferrule seal body with a channel therethrough for accessing the bore side of the tubular mechanism. 5. The tubular carrier device of claim 1 further comprising a manually adjustable compression device for tightening the sealable interface. 6. The tubular carrier device of claim 1 wherein the information is one of downhole temperature information, pressure information and fluid flow information. 7. The tubular carrier device of claim 1 wherein the tubular mechanism is configured for coupling to production tubing for transport of hydrocarbon fluids to a surface at the oilfield. 8. The tubular carrier device of claim 7 wherein the production tubing is incorporated into completions hardware, the completions hardware further comprising lower completions hardware for the uptake of the hydrocarbon fluid from a formation defining the well and an isolation device thereabove for providing fluid isolation thereto, the lower completions hardware coupled to the production tubing for the transport of the fluids to the surface. 9. The tubular carrier device of claim 8 wherein the device is located adjacently above the isolation device. 10. A seal assembly for a tubular mechanism, the assembly comprising: a first test port device pressurizably coupled to a first unidirectional seal at a bore side of the mechanism; and a second test port device pressurizably coupled to a second unidirectional seal at an annular side of the mechanism, the first test port device configured to detect failure of the second unidirectional seal and the second test port device configured to detect failure of the first unidirectional seal. 11. The seal assembly of claim 10 wherein the first unidirectional seal is an inner bore seal and the second unidirectional seal is an outer annular seal adjacently disposed exterior of the bore seal. 12. The seal assembly of claim 10 wherein the seals are oppositely oriented c-rings. 13. The seal assembly of claim 12 wherein the seals are of metallic composition. 14. A method of testing a bidirectional seal assembly to confirm sealability of a bore seal and an annular seal thereof, the method comprising: directing fluid pressure at the bore seal with a bore test port fluidly coupled thereto; allowing the annular seal to collapse in the event of a leak in the bore seal in response to the fluid pressure directed thereat; detecting the leak of the bore seal at an annular test port fluidly coupled to the collapsed annular seal in the event of the leak of the bore seal; directing fluid pressure at the annular seal with an annular test port fluidly coupled thereto; allowing the bore seal to collapse in the event of a leak in the annular seal in response to the fluid pressure directed thereat; and detecting the leak of the annular seal at the bore test port coupled to the collapsed bore seal in the event of the leak of the annular seal. 15. The method of claim 14 wherein the seals are oppositely oriented c-rings. 16. The method of claim 14 wherein the seal assembly is at an interface of a test gauge and a tubular mechanism of a gauge carrier device, the method further comprising manually tightening a compression device at the test gauge while located at a surface of an oilfield prior to the directing of fluid pressures at the seals. 17. The method of claim 16 further comprising: securing the tubular mechanism of the gauge carrier device to a completions tubular; and deploying the completions tubular into a well at the oilfield with the gauge carrier device secured thereto. 18. The method of claim 17 further comprising using the test gauge of the gauge carrier device to acquire information relative one of flow, pressure and temperature from bore and annular regions adjacent the gauge carrier device. 19. The method of claim 18 further comprising relaying the information over a line coupled to the test gauge and to equipment located at the oilfield surface. 20. The method of claim 19 further comprising producing hydrocarbons through the gauge carrier device during the acquiring and relaying of the information.