Virtually indexed and virtually tagged (VIVT) caches are an attractive option for micro-processor level-1 caches, because of their fast response time and because they are cheaper to implement than more complex caches such as virtually-indexed physical-tagged (VIPT) caches. The level-1 VIVT cache becomes even simpler to construct if it is implemented as a direct-mapped cache (VIVT-DM cache). However, VIVT and VIVT-DM caches have some drawbacks. When the number of sets in the cache is larger than the smallest page size, there is a possibility of synonyms (two or more virtual addresses mapped to the same physical address) existing in the cache. Further, maintenance of cache coherence across multiple processors requires a physical to virtual translation mechanism in the hardware. We describe a simple, efficient reverse lookup table based approach to address the synonym and the coherence problems in VIVT (both set associative and direct-mapped) caches. In particular, the proposed scheme does not disturb the critical memory access paths in a typical micro-processor, and requires a low overhead for its implementation. We have implemented and validated the scheme in the AJIT 32-bit microprocessor core (an implementation of the SPARC-V8 ISA) and the implementation uses approximately 2% of the gates and 5.3% of the memory bits in the processor core.