Title: Perspective on Lower Bounds: Diagonalization
1Perspective on Lower Bounds Diagonalization
- Lance Fortnow
- NEC Research Institute
2A Theorem
- Permanent is not in uniform TC0.
- Papers
- Allender 96.
- Caussinus-McKenzie-Thérien-Vollmer 96.
- Allender-Gore 94.
3Counting Hierarchy
- PP Class of languages accepted by probabilistic
machines with unbounded error. - Counting Hierarchy
4Counting Hierarchy in TC0
- If Permanent is in uniform TC0 then Permanent is
in P and PP in P. - Counting Hierarchy collapses to P.
- Permanent is AC0-hard for P.
- All of P and thus the entire counting hierarchy
collapses to uniform TC0.
5Threshold Machines
- Alternating machines that ask Do a majority of
my paths accept? - Polynomial-time unbounded thresholds is
equivalent to PSPACE. - Polynomial-time constant thresholds is the
counting hierarchy. - Log-time constant thresholds is uniform-TC0.
6Almost done
- For any k, there exists a language L accepted by
a polynomial-time k-threshold machine that is not
accepted by any log-time k-threshold machine. - Not yet done
- Could be that L is accepted by a log
timer-threshold machine for some r gt k.
7Finishing Up
- SAT is accepted by log-time k-threshold machine.
- All of NP is accepted by some log-time
k-threshold machine. - All of the counting hierarchy is accepted by some
log-time k-threshold machine. - Contradiction!
8Diagonalization
- Want to prove separation.
- Assume collapse.
- Get other collapses.
- Keep collapsing until we have collapsed two
classes that can be separated by diagonalization.
9Diagonalization - Positives
- Diagonalization works!
- Diagonalization is not natural or at least it
avoids the Razborov-Rudich natural proof issues. - Proofs are simplesometimes require clever ideas
but rarely hard combinatorics.
10Diagonalization - Negatives
- Only weak separations so far.
- Relativization
- Probably will not settle P NP.
- Can only get nonrelativizing separations by using
nonrelativizing collapses. - Hard to diagonalize against nonuniform models of
computation.
11Diagonalization
- Cantor (1874) There is no one-to-one function
from the power set of the integers to the
integers. - Proof Suppose there was. Then we could enumerate
the power set of the integers S1, S2, S3,
12Proof of Cantors Theorem
1 2 3 4 5 6 ?
S1 In Out In Out In In ?
S2 Out In Out Out In Out ?
S3 Out Out Out Out Out Out ?
S4 In Out In Out In Out ?
S5 In In In In In In ?
S6 Out In Out Out Out In ?
? ? ? ? ? ? ? ?
13Proof of Cantors Theorem
1 2 3 4 5 6 ?
S1 In Out In Out In In ?
S2 Out In Out Out In Out ?
S3 Out Out Out Out Out Out ?
S4 In Out In Out In Out ?
S5 In In In In In In ?
S6 Out In Out Out Out In ?
? ? ? ? ? ? ? ?
14Proof of Cantors Theorem
1 2 3 4 5 6 ?
S1 Out Out In Out In In ?
S2 Out Out Out Out In Out ?
S3 Out Out In Out Out Out ?
S4 In Out In In In Out ?
S5 In In In In Out In ?
S6 Out In Out Out Out Out ?
? ? ? ? ? ? ? ?
15A Brief History
- 600 BC - Epimenides Paradox.
- All cretans are liarsOne of their own poets has
said so. - 400 BC - Eubulides Paradox.
- This statement is false.
- 1200 AD Medieval Study of Insolubia.
- I am a liar.
16A Brief History
- 1874 Cantor.
- The set of reals is not countable.
- 1901 - Russells Paradox.
- The set of all sets that does not contain itself
as a member. - 1931 - Gödels Incompleteness.
- This statement does not have a proof.
17A Brief History
- 1936 Turing.
- The halting problem is undecidable.
- 1956 Friedberg-Muchnik.
- There exist incomplete Turing degrees.
- 1965 Hartmanis-Stearns.
- More time gives more languages.
18Time and Space Hierarchies
- Nondeterministic Space Hierarchy.
- Ibarra (1972), IS (1988).
- First to use multiple collapses.
- Nondeterministic Time Hierarchy.
- Cook (1973), SFM (1978), Žàk (1983).
- Unbounded collapses necessary.
- Almost-everywhere Hierarchies.
- Open Probabilistic, Quantum.
19Delayed Diagonalization
- Ladner 75
- If P ? NP then there exists a set in NP that is
not in P and not complete. - To keep the language in NP we wait until we have
fulfilled the previous diagonalization step.
20Diagonalization is it!
- Kozen (1980)
- Any proof that P is different from NP is a
diagonalization proof. - Says more about the difficulty of formalizing the
notion of diagonalization than of the possibility
of other types of proofs.
21Nonrelativizing Separations
- Buhrman-Fortnow-Thierauf (1998).
- Exponential version of MA does not have
polynomial size circuits. - Relativized world where it does have polynomial
size circuits. - Proof uses EXP in P/poly implies EXP in MA
(Babai-Fortnow-Lund).
22The Next Great Result
- Logspace is strictly contained in NP.
- No good reason to think this is hard.
- Several possible approaches.
- Four ways to separate NP from L.
- 1. Autoreducibility.
- 2. Intersections of Finite Automata.
- 3. Anti-Impagliazzo-Wigderson.
- 4. Trading Alternation, Time and Space.
231. Autoreducibility
- Autoredubile sets are sets with a certain amount
of redundacy in them. - Whether certain complete problems are
autoreducible can separate complexity classes. - Burhman, Fortnow, van Melkebeek and Torenvliet 95
24Reducibility
- A set A (Turing) reduces to B if we can answer
questions to A by asking arbitrary adaptive
questions to B.
A
...
...
B
25Autoreducibility
- A set A is autoreducible if we can answer
questions to A by asking arbitrary adaptive
questions to A.
A
...
...
A
26Autoreducibility
- A set A is autoreducible if we can answer
questions to A by asking arbitrary adaptive
questions to A except for the original question.
A
...
...
A
27Autoreducibility and NL ? NP
- If EXPSPACE-complete sets are all autoreducible
then NL ? NP. - If PSPACE-complete sets are all nonadaptively
autoreducible then NL also differs from NP.
28Diagonalization Helps!
- Assume NP NL.
- We then create a set in A such that
- A is in EXPSPACE.
- A is hard for EXPSPACE.
- A diagonalizes against all autoreductions.
- NP NL implies a EXPSPACE-complete sets that is
not autoreducible.
292. Intersecting Finite Automata
- Finite automata can capture pieces of a
computation. - Intersecting them can capture the whole
computation. - Karakostas-Lipton-Viglas 2000.
30Intersecting Finite Automata
- Does a given automata ever accept?
- Check in time linear in size.
- Do a given collection of k automata of size s
have a non-empty intersection? - Can do in time sk.
- If one can do substantially better, complexity
separation occurs.
31Simulating Computation
Input Tape
Finite Control
Work Tape
32Simulating Computation
Input Tape
Finite Control
F1
F2
F3
Work Tape
33Simulating Computation
Input Tape
G
Finite Control
F1
F2
F3
Work Tape
34Results
- Given k finite automata with s states and one
finite automata with t states. - If we can determine if there is a common
intersection in time - so(k)t
- then P is different from L.
35Results
- Given k finite automata with s states and one
finite automata with t states. - If we can determine if there is a common
intersection by a circuit of size - so(k)t
- then NP is different from L.
36Diagonalization Helps
- Quick simulations of the intersections of finite
automata allow us to solve logarithmic space in
time n1? which is strictly contained in P.
373. Anti-Impagliazzo-Wigderson
- Impagliazzo-Wigderson 97.
- If deterministic 2O(n) time (E) does not have
2o(n) size circuits then P BPP. - Assumption very strong We are allowed to use
huge amounts to nonuniformity to save a little
time. - To prove assumption false would separate P from
NP.
38P NP and Small Circuits for E
- P NP implies P PH.
- P PH implies E EH.
- Kannan 81 EH contains languages that do not
have 2o(n) size circuits. - E does not have 2o(n) size circuits.
39L NP and Linear Space
- If every language in linear space has 2o(n) size
circuits then L is different than NP. - We dont even know if SAT has 2o(n) size
circuits. - If SAT does not have 2o(n) size circuits than L
is different from NP.
40How to show L ? NP
- Assuming SAT has very small, low-depth circuits
show that Linear Space has slightly small
circuits.
414. Alternation, Time and Space
- Use relationships between alternation, time and
space to get the collapses needed for a
contradiction. - Kannan 84.
- Fortnow 97.
- Lipton-Viglas 99.
- Fortnow-van Melkebeek 00.
- Tourlakis 00.
42Lower Bounds on ?2
- ?2-Linear time cannot be simulated by a machine
using n1.99 time and polylogarithmic space.
43Suppose it could
logc n
n1.99
44Suppose it could
logc n
n0.995
n0.995
n1.99
n0.995
n0.995
45Suppose it could
logc n
n0.995
n0.995
n1.99
n0.995
n0.995
46Separations
- Generalize ?j-linear time requires nearly nj
time on small space machines. - If one could show ?j-linear time requires nk time
with small space for all k then NP is different
from L.
47Lower Bounds on SAT
- Satisfiability cannot be solved by any machine
using no(1) space and na time for any a less than
the golden ratio, about 1.618. - Various time-space tradeoffs.
48Razborov Its not dead yet
- Circuit Complexity 5 years
- Diagonalization
- Complexity Theory 35 years
- Computability 65 years
- Proof Technique 125 years
- Concept 2600 years
- and Its not dead yet
49Steve Mahaney
- Diagonalization is a tool for showing separation
results, but not a power tool.
50Steve Mahaney
- Diagonalization is a tool for showing separation
results, but not a power tool.
51Conclusions
- Diagonalization still produces new lower bounds
and possibilities for the future. - The actual diagonalization step is easy.
- The trick is doing the collapses to get the
diagonalization. - Hard combinatorics not required.
- Is NP ? L just around the corner?