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#!/usr/bin/python
# -*- coding: utf-8 -*-
##################################################################################################
# module for the eigenvalue problem
# Copyright 2013 Timo Hartmann (thartmann15 at gmail.com)
#
# todo:
# - implement balancing
# - agressive early deflation
#
##################################################################################################
"""
The eigenvalue problem
----------------------
This file contains routines for the eigenvalue problem.
high level routines:
 hessenberg : reduction of a real or complex square matrix to upper Hessenberg form
 schur : reduction of a real or complex square matrix to upper Schur form
 eig : eigenvalues and eigenvectors of a real or complex square matrix
low level routines:
 hessenberg_reduce_0 : reduction of a real or complex square matrix to upper Hessenberg form
 hessenberg_reduce_1 : auxiliary routine to hessenberg_reduce_0
 qr_step : a single implicitly shifted QR step for an upper Hessenberg matrix
 hessenberg_qr : Schur decomposition of an upper Hessenberg matrix
 eig_tr_r : right eigenvectors of an upper triangular matrix
 eig_tr_l : left eigenvectors of an upper triangular matrix
"""
from ..libmp.backend import xrange
class Eigen(object):
 pass
def defun(f):
 setattr(Eigen, f.__name__, f)
 return f
def hessenberg_reduce_0(ctx, A, T):
 """
 This routine computes the (upper) Hessenberg decomposition of a square matrix A.
 Given A, an unitary matrix Q is calculated such that
 Q' A Q = H and Q' Q = Q Q' = 1
 where H is an upper Hessenberg matrix, meaning that it only contains zeros
 below the first subdiagonal. Here ' denotes the hermitian transpose (i.e.
 transposition and conjugation).
 parameters:
 A (input/output) On input, A contains the square matrix A of
 dimension (n,n). On output, A contains a compressed representation
 of Q and H.
 T (output) An array of length n containing the first elements of
 the Householder reflectors.
 """
# internally we work with householder reflections from the right.
 # let u be a row vector (i.e. u[i]=A[i,:i]). then
 # Q is build up by reflectors of the type (1-v'v) where v is a suitable
 # modification of u. these reflectors are applyed to A from the right.
 # because we work with reflectors from the right we have to start with
 # the bottom row of A and work then upwards (this corresponds to
 # some kind of RQ decomposition).
 # the first part of the vectors v (i.e. A[i,:(i-1)]) are stored as row vectors
 # in the lower left part of A (excluding the diagonal and subdiagonal).
 # the last entry of v is stored in T.
 # the upper right part of A (including diagonal and subdiagonal) becomes H.
n = A.rows
 if n <= 2: return
for i in xrange(n-1, 1, -1):
# scale the vector
scale = 0
 for k in xrange(0, i):
 scale += abs(ctx.re(A[i,k])) + abs(ctx.im(A[i,k]))
scale_inv = 0
 if scale != 0:
 scale_inv = 1 / scale
if scale == 0 or ctx.isinf(scale_inv):
 # sadly there are floating point numbers not equal to zero whose reciprocal is infinity
 T[i] = 0
 A[i,i-1] = 0
 continue
# calculate parameters for housholder transformation
H = 0
 for k in xrange(0, i):
 A[i,k] *= scale_inv
 rr = ctx.re(A[i,k])
 ii = ctx.im(A[i,k])
 H += rr * rr + ii * ii
F = A[i,i-1]
 f = abs(F)
 G = ctx.sqrt(H)
 A[i,i-1] = - G * scale
if f == 0:
 T[i] = G
 else:
 ff = F / f
 T[i] = F + G * ff
 A[i,i-1] *= ff
H += G * f
 H = 1 / ctx.sqrt(H)
T[i] *= H
 for k in xrange(0, i - 1):
 A[i,k] *= H
for j in xrange(0, i):
 # apply housholder transformation (from right)
G = ctx.conj(T[i]) * A[j,i-1]
 for k in xrange(0, i-1):
 G += ctx.conj(A[i,k]) * A[j,k]
A[j,i-1] -= G * T[i]
 for k in xrange(0, i-1):
 A[j,k] -= G * A[i,k]
for j in xrange(0, n):
 # apply housholder transformation (from left)
G = T[i] * A[i-1,j]
 for k in xrange(0, i-1):
 G += A[i,k] * A[k,j]
A[i-1,j] -= G * ctx.conj(T[i])
 for k in xrange(0, i-1):
 A[k,j] -= G * ctx.conj(A[i,k])
def hessenberg_reduce_1(ctx, A, T):
 """
 This routine forms the unitary matrix Q described in hessenberg_reduce_0.
 parameters:
 A (input/output) On input, A is the same matrix as delivered by
 hessenberg_reduce_0. On output, A is set to Q.
 T (input) On input, T is the same array as delivered by hessenberg_reduce_0.
 """
n = A.rows
if n == 1:
 A[0,0] = 1
 return
A[0,0] = A[1,1] = 1
 A[0,1] = A[1,0] = 0
for i in xrange(2, n):
 if T[i] != 0:
for j in xrange(0, i):
 G = T[i] * A[i-1,j]
 for k in xrange(0, i-1):
 G += A[i,k] * A[k,j]
A[i-1,j] -= G * ctx.conj(T[i])
 for k in xrange(0, i-1):
 A[k,j] -= G * ctx.conj(A[i,k])
A[i,i] = 1
 for j in xrange(0, i):
 A[j,i] = A[i,j] = 0
@defun
def hessenberg(ctx, A, overwrite_a = False):
 """
 This routine computes the Hessenberg decomposition of a square matrix A.
 Given A, an unitary matrix Q is determined such that
 Q' A Q = H and Q' Q = Q Q' = 1
 where H is an upper right Hessenberg matrix. Here ' denotes the hermitian
 transpose (i.e. transposition and conjugation).
 input:
 A : a real or complex square matrix
 overwrite_a : if true, allows modification of A which may improve
 performance. if false, A is not modified.
 output:
 Q : an unitary matrix
 H : an upper right Hessenberg matrix
 example:
 >>> from mpmath import mp
 >>> A = mp.matrix([[3, -1, 2], [2, 5, -5], [-2, -3, 7]])
 >>> Q, H = mp.hessenberg(A)
 >>> mp.nprint(H, 3) # doctest:+SKIP
 [ 3.15 2.23 4.44]
 [-0.769 4.85 3.05]
 [ 0.0 3.61 7.0]
 >>> print(mp.chop(A - Q * H * Q.transpose_conj()))
 [0.0 0.0 0.0]
 [0.0 0.0 0.0]
 [0.0 0.0 0.0]
 return value: (Q, H)
 """
n = A.rows
if n == 1:
 return (ctx.matrix([[1]]), A)
if not overwrite_a:
 A = A.copy()
T = ctx.matrix(n, 1)
hessenberg_reduce_0(ctx, A, T)
 Q = A.copy()
 hessenberg_reduce_1(ctx, Q, T)
for x in xrange(n):
 for y in xrange(x+2, n):
 A[y,x] = 0
return Q, A
###########################################################################
def qr_step(ctx, n0, n1, A, Q, shift):
 """
 This subroutine executes a single implicitly shifted QR step applied to an
 upper Hessenberg matrix A. Given A and shift as input, first an QR
 decomposition is calculated:
 Q R = A - shift * 1 .
 The output is then following matrix:
 R Q + shift * 1
 parameters:
 n0, n1 (input) Two integers which specify the submatrix A[n0:n1,n0:n1]
 on which this subroutine operators. The subdiagonal elements
 to the left and below this submatrix must be deflated (i.e. zero).
 following restriction is imposed: n1>=n0+2
 A (input/output) On input, A is an upper Hessenberg matrix.
 On output, A is replaced by "R Q + shift * 1"
 Q (input/output) The parameter Q is multiplied by the unitary matrix
 Q arising from the QR decomposition. Q can also be false, in which
 case the unitary matrix Q is not computated.
 shift (input) a complex number specifying the shift. idealy close to an
 eigenvalue of the bottemmost part of the submatrix A[n0:n1,n0:n1].
 references:
 Stoer, Bulirsch - Introduction to Numerical Analysis.
 Kresser : Numerical Methods for General and Structured Eigenvalue Problems
 """
# implicitly shifted and bulge chasing is explained at p.398/399 in "Stoer, Bulirsch - Introduction to Numerical Analysis"
 # for bulge chasing see also "Watkins - The Matrix Eigenvalue Problem" sec.4.5,p.173
# the Givens rotation we used is determined as follows: let c,s be two complex
 # numbers. then we have following relation:
 #
 # v = sqrt(|c|^2 + |s|^2)
 #
 # 1/v [ c~ s~] [c] = [v]
 # [-s c ] [s] [0]
 #
 # the matrix on the left is our Givens rotation.
n = A.rows
# first step
# calculate givens rotation
 c = A[n0 ,n0] - shift
 s = A[n0+1,n0]
v = ctx.hypot(ctx.hypot(ctx.re(c), ctx.im(c)), ctx.hypot(ctx.re(s), ctx.im(s)))
if v == 0:
 v = 1
 c = 1
 s = 0
 else:
 c /= v
 s /= v
cc = ctx.conj(c)
 cs = ctx.conj(s)
for k in xrange(n0, n):
 # apply givens rotation from the left
 x = A[n0 ,k]
 y = A[n0+1,k]
 A[n0 ,k] = cc * x + cs * y
 A[n0+1,k] = c * y - s * x
for k in xrange(min(n1, n0+3)):
 # apply givens rotation from the right
 x = A[k,n0 ]
 y = A[k,n0+1]
 A[k,n0 ] = c * x + s * y
 A[k,n0+1] = cc * y - cs * x
if not isinstance(Q, bool):
 for k in xrange(n):
 # eigenvectors
 x = Q[k,n0 ]
 y = Q[k,n0+1]
 Q[k,n0 ] = c * x + s * y
 Q[k,n0+1] = cc * y - cs * x
# chase the bulge
for j in xrange(n0, n1 - 2):
 # calculate givens rotation
c = A[j+1,j]
 s = A[j+2,j]
v = ctx.hypot(ctx.hypot(ctx.re(c), ctx.im(c)), ctx.hypot(ctx.re(s), ctx.im(s)))
if v == 0:
 A[j+1,j] = 0
 v = 1
 c = 1
 s = 0
 else:
 A[j+1,j] = v
 c /= v
 s /= v
A[j+2,j] = 0
cc = ctx.conj(c)
 cs = ctx.conj(s)
for k in xrange(j+1, n):
 # apply givens rotation from the left
 x = A[j+1,k]
 y = A[j+2,k]
 A[j+1,k] = cc * x + cs * y
 A[j+2,k] = c * y - s * x
for k in xrange(0, min(n1, j+4)):
 # apply givens rotation from the right
 x = A[k,j+1]
 y = A[k,j+2]
 A[k,j+1] = c * x + s * y
 A[k,j+2] = cc * y - cs * x
if not isinstance(Q, bool):
 for k in xrange(0, n):
 # eigenvectors
 x = Q[k,j+1]
 y = Q[k,j+2]
 Q[k,j+1] = c * x + s * y
 Q[k,j+2] = cc * y - cs * x
def hessenberg_qr(ctx, A, Q):
 """
 This routine computes the Schur decomposition of an upper Hessenberg matrix A.
 Given A, an unitary matrix Q is determined such that
 Q' A Q = R and Q' Q = Q Q' = 1
 where R is an upper right triangular matrix. Here ' denotes the hermitian
 transpose (i.e. transposition and conjugation).
 parameters:
 A (input/output) On input, A contains an upper Hessenberg matrix.
 On output, A is replace by the upper right triangluar matrix R.
 Q (input/output) The parameter Q is multiplied by the unitary
 matrix Q arising from the Schur decomposition. Q can also be
 false, in which case the unitary matrix Q is not computated.
 """
n = A.rows
norm = 0
 for x in xrange(n):
 for y in xrange(min(x+2, n)):
 norm += ctx.re(A[y,x]) ** 2 + ctx.im(A[y,x]) ** 2
 norm = ctx.sqrt(norm) / n
if norm == 0:
 return
n0 = 0
 n1 = n
eps = ctx.eps / (100 * n)
 maxits = ctx.dps * 4
its = totalits = 0
while 1:
 # kressner p.32 algo 3
 # the active submatrix is A[n0:n1,n0:n1]
k = n0
while k + 1 < n1:
 s = abs(ctx.re(A[k,k])) + abs(ctx.im(A[k,k])) + abs(ctx.re(A[k+1,k+1])) + abs(ctx.im(A[k+1,k+1]))
 if s < eps * norm:
 s = norm
 if abs(A[k+1,k]) < eps * s:
 break
 k += 1
if k + 1 < n1:
 # deflation found at position (k+1, k)
A[k+1,k] = 0
 n0 = k + 1
its = 0
if n0 + 1 >= n1:
 # block of size at most two has converged
 n0 = 0
 n1 = k + 1
 if n1 < 2:
 # QR algorithm has converged
 return
 else:
 if (its % 30) == 10:
 # exceptional shift
 shift = A[n1-1,n1-2]
 elif (its % 30) == 20:
 # exceptional shift
 shift = abs(A[n1-1,n1-2])
 elif (its % 30) == 29:
 # exceptional shift
 shift = norm
 else:
 # A = [ a b ] det(x-A)=x*x-x*tr(A)+det(A)
 # [ c d ]
 #
 # eigenvalues bad: (tr(A)+sqrt((tr(A))**2-4*det(A)))/2
 # bad because of cancellation if |c| is small and |a-d| is small, too.
 #
 # eigenvalues good: (a+d+sqrt((a-d)**2+4*b*c))/2
t = A[n1-2,n1-2] + A[n1-1,n1-1]
 s = (A[n1-1,n1-1] - A[n1-2,n1-2]) ** 2 + 4 * A[n1-1,n1-2] * A[n1-2,n1-1]
 if ctx.re(s) > 0:
 s = ctx.sqrt(s)
 else:
 s = ctx.sqrt(-s) * 1j
 a = (t + s) / 2
 b = (t - s) / 2
 if abs(A[n1-1,n1-1] - a) > abs(A[n1-1,n1-1] - b):
 shift = b
 else:
 shift = a
its += 1
 totalits += 1
qr_step(ctx, n0, n1, A, Q, shift)
if its > maxits:
 raise RuntimeError("qr: failed to converge after %d steps" % its)
@defun
def schur(ctx, A, overwrite_a = False):
 """
 This routine computes the Schur decomposition of a square matrix A.
 Given A, an unitary matrix Q is determined such that
 Q' A Q = R and Q' Q = Q Q' = 1
 where R is an upper right triangular matrix. Here ' denotes the
 hermitian transpose (i.e. transposition and conjugation).
 input:
 A : a real or complex square matrix
 overwrite_a : if true, allows modification of A which may improve
 performance. if false, A is not modified.
 output:
 Q : an unitary matrix
 R : an upper right triangular matrix
 return value: (Q, R)
 example:
 >>> from mpmath import mp
 >>> A = mp.matrix([[3, -1, 2], [2, 5, -5], [-2, -3, 7]])
 >>> Q, R = mp.schur(A)
 >>> mp.nprint(R, 3) # doctest:+SKIP
 [2.0 0.417 -2.53]
 [0.0 4.0 -4.74]
 [0.0 0.0 9.0]
 >>> print(mp.chop(A - Q * R * Q.transpose_conj()))
 [0.0 0.0 0.0]
 [0.0 0.0 0.0]
 [0.0 0.0 0.0]
 warning: The Schur decomposition is not unique.
 """
n = A.rows
if n == 1:
 return (ctx.matrix([[1]]), A)
if not overwrite_a:
 A = A.copy()
T = ctx.matrix(n, 1)
hessenberg_reduce_0(ctx, A, T)
 Q = A.copy()
 hessenberg_reduce_1(ctx, Q, T)
for x in xrange(n):
 for y in xrange(x + 2, n):
 A[y,x] = 0
hessenberg_qr(ctx, A, Q)
return Q, A
def eig_tr_r(ctx, A):
 """
 This routine calculates the right eigenvectors of an upper right triangular matrix.
 input:
 A an upper right triangular matrix
 output:
 ER a matrix whose columns form the right eigenvectors of A
 return value: ER
 """
# this subroutine is inspired by the lapack routines ctrevc.f,clatrs.f
n = A.rows
ER = ctx.eye(n)
eps = ctx.eps
unfl = ctx.ldexp(ctx.one, -ctx.prec * 30)
 # since mpmath effectively has no limits on the exponent, we simply scale doubles up
 # original double has prec*20
smlnum = unfl * (n / eps)
 simin = 1 / ctx.sqrt(eps)
rmax = 1
for i in xrange(1, n):
 s = A[i,i]
smin = max(eps * abs(s), smlnum)
for j in xrange(i - 1, -1, -1):
r = 0
 for k in xrange(j + 1, i + 1):
 r += A[j,k] * ER[k,i]
t = A[j,j] - s
 if abs(t) < smin:
 t = smin
r = -r / t
 ER[j,i] = r
rmax = max(rmax, abs(r))
 if rmax > simin:
 for k in xrange(j, i+1):
 ER[k,i] /= rmax
 rmax = 1
if rmax != 1:
 for k in xrange(0, i + 1):
 ER[k,i] /= rmax
return ER
def eig_tr_l(ctx, A):
 """
 This routine calculates the left eigenvectors of an upper right triangular matrix.
 input:
 A an upper right triangular matrix
 output:
 EL a matrix whose rows form the left eigenvectors of A
 return value: EL
 """
n = A.rows
EL = ctx.eye(n)
eps = ctx.eps
unfl = ctx.ldexp(ctx.one, -ctx.prec * 30)
 # since mpmath effectively has no limits on the exponent, we simply scale doubles up
 # original double has prec*20
smlnum = unfl * (n / eps)
 simin = 1 / ctx.sqrt(eps)
rmax = 1
for i in xrange(0, n - 1):
 s = A[i,i]
smin = max(eps * abs(s), smlnum)
for j in xrange(i + 1, n):
r = 0
 for k in xrange(i, j):
 r += EL[i,k] * A[k,j]
t = A[j,j] - s
 if abs(t) < smin:
 t = smin
r = -r / t
 EL[i,j] = r
rmax = max(rmax, abs(r))
 if rmax > simin:
 for k in xrange(i, j + 1):
 EL[i,k] /= rmax
 rmax = 1
if rmax != 1:
 for k in xrange(i, n):
 EL[i,k] /= rmax
return EL
@defun
def eig(ctx, A, left = False, right = True, overwrite_a = False):
 """
 This routine computes the eigenvalues and optionally the left and right
 eigenvectors of a square matrix A. Given A, a vector E and matrices ER
 and EL are calculated such that
 A ER[:,i] = E[i] ER[:,i]
 EL[i,:] A = EL[i,:] E[i]
 E contains the eigenvalues of A. The columns of ER contain the right eigenvectors
 of A whereas the rows of EL contain the left eigenvectors.
 input:
 A : a real or complex square matrix of shape (n, n)
 left : if true, the left eigenvectors are calculated.
 right : if true, the right eigenvectors are calculated.
 overwrite_a : if true, allows modification of A which may improve
 performance. if false, A is not modified.
 output:
 E : a list of length n containing the eigenvalues of A.
 ER : a matrix whose columns contain the right eigenvectors of A.
 EL : a matrix whose rows contain the left eigenvectors of A.
 return values:
 E if left and right are both false.
 (E, ER) if right is true and left is false.
 (E, EL) if left is true and right is false.
 (E, EL, ER) if left and right are true.
 examples:
 >>> from mpmath import mp
 >>> A = mp.matrix([[3, -1, 2], [2, 5, -5], [-2, -3, 7]])
 >>> E, ER = mp.eig(A)
 >>> print(mp.chop(A * ER[:,0] - E[0] * ER[:,0]))
 [0.0]
 [0.0]
 [0.0]
 >>> E, EL, ER = mp.eig(A,left = True, right = True)
 >>> E, EL, ER = mp.eig_sort(E, EL, ER)
 >>> mp.nprint(E)
 [2.0, 4.0, 9.0]
 >>> print(mp.chop(A * ER[:,0] - E[0] * ER[:,0]))
 [0.0]
 [0.0]
 [0.0]
 >>> print(mp.chop( EL[0,:] * A - EL[0,:] * E[0]))
 [0.0 0.0 0.0]
 warning:
 - If there are multiple eigenvalues, the eigenvectors do not necessarily
 span the whole vectorspace, i.e. ER and EL may have not full rank.
 Furthermore in that case the eigenvectors are numerical ill-conditioned.
 - In the general case the eigenvalues have no natural order.
 see also:
 - eigh (or eigsy, eighe) for the symmetric eigenvalue problem.
 - eig_sort for sorting of eigenvalues and eigenvectors
 """
n = A.rows
if n == 1:
 if left and (not right):
 return ([A[0]], ctx.matrix([[1]]))
if right and (not left):
 return ([A[0]], ctx.matrix([[1]]))
return ([A[0]], ctx.matrix([[1]]), ctx.matrix([[1]]))
if not overwrite_a:
 A = A.copy()
T = ctx.zeros(n, 1)
hessenberg_reduce_0(ctx, A, T)
if left or right:
 Q = A.copy()
 hessenberg_reduce_1(ctx, Q, T)
 else:
 Q = False
for x in xrange(n):
 for y in xrange(x + 2, n):
 A[y,x] = 0
hessenberg_qr(ctx, A, Q)
E = [0 for i in xrange(n)]
 for i in xrange(n):
 E[i] = A[i,i]
if not (left or right):
 return E
if left:
 EL = eig_tr_l(ctx, A)
 EL = EL * Q.transpose_conj()
if right:
 ER = eig_tr_r(ctx, A)
 ER = Q * ER
if left and (not right):
 return (E, EL)
if right and (not left):
 return (E, ER)
return (E, EL, ER)
@defun
def eig_sort(ctx, E, EL = False, ER = False, f = "real"):
 """
 This routine sorts the eigenvalues and eigenvectors delivered by ``eig``.
 parameters:
 E : the eigenvalues as delivered by eig
 EL : the left eigenvectors as delivered by eig, or false
 ER : the right eigenvectors as delivered by eig, or false
 f : either a string ("real" sort by increasing real part, "imag" sort by
 increasing imag part, "abs" sort by absolute value) or a function
 mapping complexs to the reals, i.e. ``f = lambda x: -mp.re(x) ``
 would sort the eigenvalues by decreasing real part.
 return values:
 E if EL and ER are both false.
 (E, ER) if ER is not false and left is false.
 (E, EL) if EL is not false and right is false.
 (E, EL, ER) if EL and ER are not false.
 example:
 >>> from mpmath import mp
 >>> A = mp.matrix([[3, -1, 2], [2, 5, -5], [-2, -3, 7]])
 >>> E, EL, ER = mp.eig(A,left = True, right = True)
 >>> E, EL, ER = mp.eig_sort(E, EL, ER)
 >>> mp.nprint(E)
 [2.0, 4.0, 9.0]
 >>> E, EL, ER = mp.eig_sort(E, EL, ER,f = lambda x: -mp.re(x))
 >>> mp.nprint(E)
 [9.0, 4.0, 2.0]
 >>> print(mp.chop(A * ER[:,0] - E[0] * ER[:,0]))
 [0.0]
 [0.0]
 [0.0]
 >>> print(mp.chop( EL[0,:] * A - EL[0,:] * E[0]))
 [0.0 0.0 0.0]
 """
if isinstance(f, str):
 if f == "real":
 f = ctx.re
 elif f == "imag":
 f = ctx.im
 elif f == "abs":
 f = abs
 else:
 raise RuntimeError("unknown function %s" % f)
n = len(E)
# Sort eigenvalues (bubble-sort)
for i in xrange(n):
 imax = i
 s = f(E[i]) # s is the current maximal element
for j in xrange(i + 1, n):
 c = f(E[j])
 if c < s:
 s = c
 imax = j
if imax != i:
 # swap eigenvalues
z = E[i]
 E[i] = E[imax]
 E[imax] = z
if not isinstance(EL, bool):
 for j in xrange(n):
 z = EL[i,j]
 EL[i,j] = EL[imax,j]
 EL[imax,j] = z
if not isinstance(ER, bool):
 for j in xrange(n):
 z = ER[j,i]
 ER[j,i] = ER[j,imax]
 ER[j,imax] = z
if isinstance(EL, bool) and isinstance(ER, bool):
 return E
if isinstance(EL, bool) and not(isinstance(ER, bool)):
 return (E, ER)
if isinstance(ER, bool) and not(isinstance(EL, bool)):
 return (E, EL)
return (E, EL, ER)

Xet Storage Details

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Xet hash:
0ff6af5fc6680a8cb1f7e6e1e9a00747d86b98868c23fdd449e183971810928b

Xet efficiently stores files, intelligently splitting them into unique chunks and accelerating uploads and downloads. More info.