Downhole customization of fracturing fluids for micro-fracturing operations

What is claimed is: 1. A computer-implemented method of customizing fracturing fluids downhole for real-time optimization of micro-fracturing operations, the method comprising: monitoring, by a computer system, downhole operating conditions during a micro-fracturing operation along a portion of a wellbore within a subterranean formation, based on downhole measurements collected by sensors of a downhole formation tester communicatively coupled to the computer system and disposed within the wellbore; determining, by the computer system, injection parameters for a fracturing fluid to be injected from a bulk storage chamber of the downhole formation tester into the subterranean formation, based on the downhole operating conditions; transmitting, from the computer system to a controller of the downhole formation tester, signals for customizing the fracturing fluid using one or more fluid additives stored within corresponding fluid storage chambers of the downhole formation tester, based on the injection parameters; and controlling, by the computer system using control signals transmitted to the controller of the downhole formation tester during the micro-fracturing operation, injection of the customized fracturing fluid from the downhole formation tester into an area of the subterranean formation surrounding the portion of the wellbore. 2. The method of claim 1 , wherein the downhole operating conditions are selected from the group consisting of: a downhole temperature; a downhole pressure; a relative density difference between formation fluid and at least one of a drilling mud or a completion fluid; a contamination profile of the formation fluid and mud filtrate over time; a fracturing fluid efficiency; a downhole density of the fracturing fluid; a downhole viscosity of the fracturing fluid; a downhole concentration of the fracturing fluid; and a leak-off coefficient of at least one of the fracturing fluid or the one or more fluid additives. 3. The method of claim 1 , wherein monitoring downhole operating conditions further comprises: performing a series of fluid injection tests along the portion of the wellbore using at least one of the fracturing fluid, the one or more fluid additives or a drilling fluid in the wellbore, and wherein the downhole operating conditions include a fracture closure stress and an instantaneous shut-in pressure based on pressure fall-off measurements collected during the series of fluid injection tests. 4. The method of claim 1 , wherein the one or more fluid additives are selected from the group consisting of: proppant; a breaker fluid; a friction reducer; an oxidizing agent; an acid; a corrosion inhibitor; an anti-bacterial agent; a scale inhibitor; a surfactant; a gelling agent; a crosslinker; a salt; a clay control agent; and a polymer. 5. The method of claim 1 , wherein the injection parameters of the fracturing fluid include a flow rate and a viscosity of the fracturing fluid to be injected into the area of the subterranean formation, and the fracturing fluid is customized by varying a composition of the fracturing fluid using the one or more fluid additives. 6. The method of claim 1 , wherein the customization of the fracturing fluid includes mixing, within a mixing chamber of the downhole formation tester, a portion of the fracturing fluid from the bulk storage chamber with a predetermined amount of each of the one or more fluid additives from the corresponding fluid storage chambers. 7. The method of claim 1 , wherein the customization of the fracturing fluid includes selecting the one or more fluid additives to be injected into the area of the subterranean formation along with the fracturing fluid, and controlling the injection of the customized fracturing fluid includes varying a sequence in which the fracturing fluid and the one or more selected fluid additives are injected into the area of the subterranean formation. 8. A system for real-time optimization of micro-fracturing operations, the system comprising: at least one processor; and a memory coupled to the processor having instructions stored therein, which when executed by the processor, cause the processor to perform functions including functions to: monitor downhole operating conditions during a micro-fracturing operation along a portion of a wellbore within a subterranean formation, based on downhole measurements collected by sensors of a downhole formation tester communicatively coupled to the computer system and disposed within the wellbore; determine injection parameters for a fracturing fluid to be injected from a bulk storage chamber of the downhole formation tester into the subterranean formation, based on the downhole operating conditions; transmit to a controller of the downhole formation tester, signals for customizing the fracturing fluid using one or more fluid additives stored within corresponding fluid storage chambers of the downhole formation tester, based on the injection parameters; and control, using control signals transmitted to the controller of the downhole formation tester during the micro-fracturing operation, injection of the customized fracturing fluid from the downhole formation tester into an area of the subterranean formation surrounding the portion of the wellbore. 9. The system of claim 8 , wherein the downhole operating conditions are selected from the group consisting of: a downhole temperature; a downhole pressure; a relative density difference between formation fluid and at least one of a drilling mud or a completion fluid; a contamination profile of the formation fluid and mud filtrate over time; a fracturing fluid efficiency; a downhole density of the fracturing fluid; a downhole viscosity of the fracturing fluid; a downhole concentration of the fracturing fluid; and a leak-off coefficient of at least one of the fracturing fluid or the one or more fluid additives. 10. The system of claim 8 , wherein the functions performed by the processor further include functions to perform a series of fluid injection tests along the portion of the wellbore using at least one of the fracturing fluid, the one or more fluid additives or a drilling fluid in the wellbore, and wherein the downhole operating conditions include a fracture closure stress and an instantaneous shut-in pressure based on pressure fall-off measurements collected during the series of fluid injection tests. 11. The system of claim 8 , wherein the one or more fluid additives are selected from the group consisting of: proppant; a breaker fluid; a friction reducer; an oxidizing agent; an acid; a corrosion inhibitor; an anti-bacterial agent; a scale inhibitor; a surfactant; a gelling agent; a crosslinker; a salt; a clay control agent; and a polymer. 12. The system of claim 8 , wherein the injection parameters of the fracturing fluid include a flow rate and a viscosity of the fracturing fluid to be injected into the area of the subterranean formation, and the fracturing fluid is customized by varying a composition of the fracturing fluid using the one or more fluid additives. 13. The system of claim 8 , wherein the customization of the fracturing fluid includes mixing, within a mixing chamber of the downhole formation tester, a portion of the fracturing fluid from the bulk storage chamber with a predetermined amount of each of the one or more fluid additives from the corresponding fluid storage chambers. 14. The system of claim 8 , wherein the customization of the fracturing fluid includes selecting the one or more fluid additives to be injected into the area of the subterranean formation along with the fracturing fluid, and the injection of the customiz