An attacker will want to try all 216,553 english words.

Plus another 12 bits of effort for the common variations, which lets say gives a list of 887,001,088 (2^{29}) possible passwords.

BCrypt takes about 4,342,912 (i.e. 2^{22}) operations to calculate one hash (at cost=12).

A core today provides about 2^{31} cycles/sec; the state of the art is 8 = 2^{3} cores per processor for a total of 2^{3} * 231 = 2^{34} cycles/sec. A server typically has 4 processors, increasing the total to 2^{2} * 2^{34} = 2^{36} cycles/sec.
2^{22} cycles to calculate one hash * 2^{29} possible (common) passwords = 2^{51} cycles to run through all (common) passwords.

This means that it would take a 4-processor, octo-core, server about 2^{51} / 2^{36} = 2^{15} seconds (9 hours) to run through all common passwords.

In reality my password is not common, and uses about 44-bits. 2^{44} passwords * 2^{22} cycles per password = 2^{66} cycles to try all uncommon passwords. 2^{66} / 2^{36} cycles/second = 2^{30} seconds (34 years) to find my password.

Moore's Law's says the processing power doubles every 18 months.

- today: 34 years to find my uncommon password
- 1.5 years: 17 years
- 3 years: 8.5 years
- 4.5: 4.25 years
- 6 years: 2.125 years
- 7.5 years: 1 year
- 9 years: 6 months
- 10.5 years: 3 months
- 12 years: 6 weeks
- 13.5 years: 3 weeks
- 15 years: 10 days
- 17.5 years: 5 days
- 19 years: 63 hours
- 20.5 years: 31 hours

That's now **bcrypt** holds up against Moore's Law.

Increase the **cost** factor from **12** to **13** and that will *double* the times involved.