https://gitlab.inria.fr/cado-nfs/cado-nfs
Tip revision: 88c4751ca1fe4677d6b83efa348d4a7b4d15d1fa authored by Emmanuel Thomé on 21 July 2014, 14:19:06 UTC
changes in 2.0.1
changes in 2.0.1
Tip revision: 88c4751
params.c79
###########################################################################
# Parameter file for Cado-NFS
###########################################################################
# See params/params.c91 for an example which contains some documentation.
# Anything after a # is a comment, until end of line.
# Any empty line is ignored
#
#
# Each parameter should be on an individual line, like
# param0=42.17
#
###########################################################################
# General parameters
###########################################################################
# Sample parameter file for a 79-digit gnfs input
# Warning: the parameters here are not claimed to be optimal!
# Example: cadofactor.pl wdir=... name=... n=...
name=c79
parallel=1 # do we use parallel computation?
delay=30 # time in seconds between two checks
machines=mach_desc # file describing available computers for parallel
# computation
###########################################################################
# Polynomial selection with Kleinjung's algorithm
###########################################################################
degree=4 # degree of the algebraic polynomial
polsel_delay=30 # time between two checks
polsel_nice=4 # nice level for selection
# one can expect
# MurphyE(Bf=10000000,Bg=5000000,area=1.00e+16)=1.51e-07-1.86e-07
## Parameters of polyselect
polsel_admax=125e3 # max value for lc(f)
polsel_adrange=1000 # individual tasks
polsel_incr=60 # forced divisor of lc(f)
polsel_P=10000 # choose lc(g) with two prime factors in [P,2P]
polsel_maxnorm=29.5 # maximal lognorm before rootsieve
###########################################################################
# Sieve
###########################################################################
# (r,a) means rational or algebraic side
# rlim/alim is the bound for sieving
# lpbr/lpba is the (base 2 log of the) large prime bound
# mfbr/mfba is the (base 2 log of the) limit for the cofactor we try to
# split into large primes.
# rlambda/alambda is the early-abort ratio: if after sieving the
# approximate norm is more than
# lambda times lpb, we reject.
rlim=100000
alim=200000
lpbr=23
lpba=23
mfbr=46
mfba=46
rlambda=2.1
alambda=2.2
I=11 # Sieving range in lattice siever
qmin=200000 # Start of the special-q range
qrange=10000 # The size of an elementary sieving task
firstcheck=763000 # Try filtering only up from that many relations
sievenice=10 # nice level for the sieving jobs
sieve_max_threads=2
###########################################################################
# Filtering
###########################################################################
keeppurge=160 # maximal excess wanted after purge
# (purge shrinks if needed)
maxlevel=15
ratio=1.1
bwstrat=3
###########################################################################
# Linear algebra
###########################################################################
bwmt=2x2 # Multithreading level of Block-Wiedemann ; Use
# <m>x<n> for bwc, or only one integer for bw.
bwc_interval=100 # checkpointing interval for bwc.
###########################################################################
# Characters
###########################################################################
nkermax=30 # maximal size of computed kernel
nchar=50 # number of characters