System and methods for fuel vapor canister flow

The invention claimed is: 1. A method comprising: when an engine is operating, routing vapors from a fuel tank through a purge valve, and routing desorbed vapors from a vapor adsorbent through said purge valve, into said engine for combustion; and when said purge valve is detected as leaking and said engine is not operating, changing said routing so that said fuel tank vapors are first routed through said vapor adsorbent for adsorption and then to said purge valve. 2. The method recited in claim 1 , wherein said vapors from said fuel tank are routed through a buffer adsorbent before said routing through said purge valve, and said desorbed vapors from said vapor adsorbent are routed through said buffer adsorbent before said routing through said purge valve, said buffer adsorbent is substantially smaller than said vapor adsorbent. 3. The method recited in claim 1 , further comprising closing said purge valve and routing said fuel tank vapors across said vapor adsorbent to atmosphere when said engine is turned off and said purge valve is not detected as leaking. 4. The method recited in claim 1 , wherein said vapor adsorbent is housed in a canister and further comprising: venting said canister to atmosphere when said purge valve is not detected as leaking; and isolating said canister from atmosphere when said purge valve is detected as leaking and said engine is turned off. 5. The method recited in claim 4 , further comprising: opening said purge valve when said engine is operating under a predetermined set of conditions so that said fuel tank vapors are inducted into said engine air intake, and atmospheric air is inducted across said vapor adsorbent to desorb stored fuel vapors which are then inducted into said engine air intake. 6. The method recited in claim 1 , wherein said vapor adsorbent is housed in a canister and further comprising performing a diagnostic test on said purge valve while said engine is running, said diagnostic test comprising: closing said purge valve; isolating said canister from atmosphere; and indicating a leak in said purge valve when vapor pressure in said fuel tank falls below a predetermined pressure. 7. A method comprising: when an engine is off, routing fuel vapors from a fuel tank into a vapor adsorbent and venting said vapor adsorbent to atmosphere; when said engine is operating, venting said vapor adsorbent to atmosphere, and routing vapors from said fuel tank through a purge valve, and desorbed vapors from said vapor adsorbent through said purge valve, into said engine for combustion; and when said purge valve is detected as leaking and said engine is turned off, closing said purge valve, isolating said canister from atmosphere, and re-routing said vapors in said tank first through said vapor adsorbent and then to said purge valve. 8. The method recited in claim 7 , further comprising supplying air to said engine and supplying fuel from said fuel tank to said engine, and combusting in a plurality of combustion chambers within said engine, said air, said fuel, said vapors from said fuel tank and said desorbed vapors in said engine. 9. The method recited in claim 8 , further comprising adjusting said fuel from said fuel tank in response to an indication of engine exhaust air/fuel ratio to maintain an overall stoichiometric mixture of said air, said fuel from said fuel tank, said vapors from said fuel tank, and said desorbed vapors. 10. The method recited in claim 9 , wherein said vapor adsorbent is housed in a canister and said purge valve is coupled to an intake manifold of said engine which in turn is coupled to each of said combustion chambers. 11. The method recited in claim 10 , further comprising performing a diagnostic test on said purge valve while said engine is running, said diagnostic test comprising: closing said purge valve; isolating said canister from atmosphere; and indicating a leak in said purge valve if vapor pressure in said fuel tank falls below a predetermined pressure during said diagnostic test. 12. The method recited in claim 7 , wherein said purge valve is opened when said engine is operating and an estimate or measurement of temperature of a catalyst coupled to exhaust of said engine is above a predetermined temperature. 13. The method recited in claim 12 , wherein said purge valve is gradually opened. 14. The method recited in claim 9 , further comprising learning concentration of said desorbed vapors and said vapors from said fuel tank in response to said exhaust air/fuel ratio indication. 15. An evaporative emissions system for a vehicle, comprising: a fuel vapor canister comprising: an adsorbent bed and an adsorbent buffer, said adsorbent bed coupled to a canister vent port and said adsorbent buffer coupled to a canister load port and a canister purge port; a fuel tank fluidly connected to said vapor canister adsorbent buffer at said canister load port; a first two-way valve positioned in a vapor line between said canister vent port of said vapor canister and a canister vent valve (CVV), a second two-way valve positioned in a vapor line between said canister purge port of said vapor canister and a canister purge valve (CPV), a controller, holding executable instructions stored in non-transitory memory, that when executed, cause said controller to: responsive to a first condition, direct vapor from said fuel tank through said canister adsorbent buffer and said canister adsorbent bed via opening said canister vent valve (CVV) and controlling said first two-way valve and said second two-way valve; and responsive to a second condition, direct vapor from said fuel tank through said canister adsorbent buffer and said canister adsorbent bed via closing said CVV and controlling said first two-way valve and said second two-way valve. 16. The evaporative emissions system of claim 15 , wherein said controller further holds executable instructions stored in non-transitory memory, that when executed, cause said controller to: responsive to said first condition, command or maintain said first two-way valve in a first position such that said canister vent port of said vapor canister bed is fluidly coupled to atmosphere via said CVV, command or maintain said second two-way valve in a first position such that said canister purge port of said vapor canister buffer is fluidly coupled to engine intake via said CPV, responsive to said second condition, command or maintain said first two-way valve in a second position such that said canister vent port of said vapor canister is fluidly coupled to said engine intake via said CPV, via a junction between said CPV and said second two-way valve, and command or maintain said second two-way valve in a second position such that said canister purge port is fluidly coupled to atmosphere via said CVV, via a junction between said first two-way valve and said CVV. 17. The evaporative emissions system of claim 16 , wherein said first condition comprises a non-leaking CPV commanded or maintained in a closed state, and wherein said second condition comprises a leaky CPV. 18. The evaporative emissions system of claim 17 , wherein said first condition further comprises, responsive to a loading state of said vapor canister being above a threshold, opening said CPV and maintaining said CVV open such that air flow is directed from said canister adsorbent bed to said canister adsorbent buffer in order to purge desorbed vapors in said vapor canister to an intake manifold of an engine. 19. The evaporative emissions system of claim 17 , wherein said second condit