Low clock-power integrated clock gating cell

What is claimed is: 1. An integrated clock gating cell comprising: a NOR gate receiving an enable signal; a latch coupled to an output of the NOR gate, the latch configured to generate a latch output in response to a state of the enable signal, the latch comprising a tri-state inverter; and a NAND gate coupled to an output of the latch, the NAND gate configured to generate an inverted clock signal in response to the latch output and a clock input received directly to the NAND gate, the inverted clock signal being generated without using an inverter. 2. The integrated clock gating cell of claim 1 , wherein the latch comprises a plurality of back-to-back connected inverters coupled to the tri-state inverter. 3. The integrated clock gating cell of claim 1 , wherein the latch generates the latch output in response to receiving the output of the NOR gate, the clock input and the inverted clock signal. 4. The integrated clock gating cell of claim 1 , wherein the NOR gate receives a test enable signal in addition to the enable signal. 5. The integrated clock gating cell of claim 1 further comprising: an inverter coupled to the NAND gate, wherein a clock output is generated at an output of the inverter in response to the inverted clock signal generated from the NAND gate. 6. An integrated clock gating cell comprising: a NOR gate receiving an enable signal; a latch coupled to an output of the NOR gate, the latch configured to generate a latch output in response to a state of the enable signal, the latch comprising a tri-state inverter; and a NAND gate coupled to the latch, the NAND gate configured to generate an inverted clock signal in response to the latch output and a clock input received directly to the NAND gate, the inverted clock signal being generated without using an inverter; wherein the latch comprises a plurality of back-to-back connected inverters coupled to the tri-state inverter, and wherein the latch receives the output of the NOR gate, the clock input and the inverted clock signal and generates the latch output. 7. The integrated clock gating cell of claim 6 further comprising: an inverter coupled to the NAND gate, wherein a clock output is generated at an output of the inverter in response to the inverted clock signal generated from the NAND gate. 8. An apparatus comprising: a clock input; and a plurality of integrated clock gating cells configured to receive the clock input; and a plurality of flip flops coupled to each of the plurality of integrated clock gating cells, wherein each of the plurality of integrated clock gating cells comprises: a NOR gate receiving an enable signal; a latch coupled to an output of the NOR gate, the latch configured to generate a latch output in response to a state of the enable signal, the latch comprising a tri-state inverter; and a NAND gate coupled to the latch, the NAND gate configured to generate an inverted clock signal in response to the latch output and the clock input received directly to the NAND gate, the inverted clock signal being generated without using an inverter. 9. The apparatus of claim 8 further comprising a combinational logic coupled to the plurality of flip flops for generating an output. 10. The apparatus of claim 8 , wherein the latch comprises a plurality of back-to-back connected inverters coupled to the tri-state inverter. 11. The apparatus of claim 8 , wherein the latch generates the latch output in response to receiving the output of the NOR gate, the clock input and the inverted clock signal. 12. The apparatus of claim 8 , wherein the NOR gate receives a test enable signal in addition to the enable signal. 13. The apparatus of claim 8 further comprising: an inverter coupled to the NAND gate, wherein a clock output is generated at an output of the inverter in response to the inverted clock signal generated from the NAND gate.