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lbfgs.lua
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lbfgs.lua
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--[[ An implementation of L-BFGS, heavily inspired by minFunc (Mark Schmidt)
This implementation of L-BFGS relies on a user-provided line
search function (state.lineSearch). If this function is not
provided, then a simple learningRate is used to produce fixed
size steps. Fixed size steps are much less costly than line
searches, and can be useful for stochastic problems.
The learning rate is used even when a line search is provided.
This is also useful for large-scale stochastic problems, where
opfunc is a noisy approximation of f(x). In that case, the learning
rate allows a reduction of confidence in the step size.
ARGS:
- `opfunc` : a function that takes a single input (X), the point of
evaluation, and returns f(X) and df/dX
- `x` : the initial point
- `state` : a table describing the state of the optimizer; after each
call the state is modified
- `state.maxIter` : Maximum number of iterations allowed
- `state.maxEval` : Maximum number of function evaluations
- `state.tolFun` : Termination tolerance on the first-order optimality
- `state.tolX` : Termination tol on progress in terms of func/param changes
- `state.lineSearch` : A line search function
- `state.learningRate` : If no line search provided, then a fixed step size is used
RETURN:
- `x*` : the new `x` vector, at the optimal point
- `f` : a table of all function values:
`f[1]` is the value of the function before any optimization and
`f[#f]` is the final fully optimized value, at `x*`
(Clement Farabet, 2012)
]]
function optim.lbfgs(opfunc, x, config, state)
-- get/update state
local config = config or {}
local state = state or config
local maxIter = tonumber(config.maxIter) or 20
local maxEval = tonumber(config.maxEval) or maxIter*1.25
local tolFun = config.tolFun or 1e-5
local tolFunRelative = tonumber(config.tolFunRelative) or 0
local tolFunRelativeInterval = tonumber(config.tolFunRelativeInterval) or 100
local tolX = config.tolX or 1e-9
local nCorrection = config.nCorrection or 100
local lineSearch = config.lineSearch
local lineSearchOpts = config.lineSearchOptions
local learningRate = config.learningRate or 1
local isverbose = config.verbose or false
state.funcEval = state.funcEval or 0
state.nIter = state.nIter or 0
-- verbose function
local verbose
if isverbose then
verbose = function(...) print('<optim.lbfgs> ', ...) end
else
verbose = function() end
end
-- import some functions
local abs = math.abs
local min = math.min
-- evaluate initial f(x) and df/dx
local f,g = opfunc(x)
local f_hist = {f}
local currentFuncEval = 1
state.funcEval = state.funcEval + 1
local p = g:size(1)
-- check optimality of initial point
state.tmp1 = state.tmp1 or g.new(g:size()):zero(); local tmp1 = state.tmp1
tmp1:copy(g):abs()
if tmp1:sum() <= tolFun then
-- optimality condition below tolFun
verbose('optimality condition below tolFun')
return x,f_hist
end
if not state.dir_bufs then
-- reusable buffers for y's and s's, and their histories
verbose('creating recyclable direction/step/history buffers')
state.dir_bufs = state.dir_bufs or g.new(nCorrection+1, p):split(1)
state.stp_bufs = state.stp_bufs or g.new(nCorrection+1, p):split(1)
for i=1,#state.dir_bufs do
state.dir_bufs[i] = state.dir_bufs[i]:squeeze(1)
state.stp_bufs[i] = state.stp_bufs[i]:squeeze(1)
end
end
-- variables cached in state (for tracing)
local d = state.d
local t = state.t
local old_dirs = state.old_dirs
local old_stps = state.old_stps
local Hdiag = state.Hdiag
local g_old = state.g_old
local f_old = state.f_old
local f_past = nil
-- optimize for a max of maxIter iterations
local nIter = 0
while nIter < maxIter do
-- keep track of nb of iterations
nIter = nIter + 1
state.nIter = state.nIter + 1
------------------------------------------------------------
-- compute gradient descent direction
------------------------------------------------------------
if state.nIter == 1 then
d = g:clone():mul(-1) -- -g
old_dirs = {}
old_stps = {}
Hdiag = 1
else
-- do lbfgs update (update memory)
local y = table.remove(state.dir_bufs) -- pop
local s = table.remove(state.stp_bufs)
y:add(g, -1, g_old) -- g - g_old
s:mul(d, t) -- d*t
local ys = y:dot(s) -- y*s
if ys > 1e-10 then
-- updating memory
if #old_dirs == nCorrection then
-- shift history by one (limited-memory)
local removed1 = table.remove(old_dirs, 1)
local removed2 = table.remove(old_stps, 1)
table.insert(state.dir_bufs, removed1)
table.insert(state.stp_bufs, removed2)
end
-- store new direction/step
table.insert(old_dirs, s)
table.insert(old_stps, y)
-- update scale of initial Hessian approximation
Hdiag = ys / y:dot(y) -- (y*y)
else
-- put y and s back into the buffer pool
table.insert(state.dir_bufs, y)
table.insert(state.stp_bufs, s)
end
-- compute the approximate (L-BFGS) inverse Hessian
-- multiplied by the gradient
local k = #old_dirs
-- need to be accessed element-by-element, so don't re-type tensor:
state.ro = state.ro or torch.Tensor(nCorrection); local ro = state.ro
for i = 1,k do
ro[i] = 1 / old_stps[i]:dot(old_dirs[i])
end
-- iteration in L-BFGS loop collapsed to use just one buffer
local q = tmp1 -- reuse tmp1 for the q buffer
-- need to be accessed element-by-element, so don't re-type tensor:
state.al = state.al or torch.zeros(nCorrection) local al = state.al
q:mul(g, -1) -- -g
for i = k,1,-1 do
al[i] = old_dirs[i]:dot(q) * ro[i]
q:add(-al[i], old_stps[i])
end
-- multiply by initial Hessian
r = d -- share the same buffer, since we don't need the old d
r:mul(q, Hdiag) -- q[1] * Hdiag
for i = 1,k do
local be_i = old_stps[i]:dot(r) * ro[i]
r:add(al[i]-be_i, old_dirs[i])
end
-- final direction is in r/d (same object)
end
g_old = g_old or g:clone()
g_old:copy(g)
f_old = f
------------------------------------------------------------
-- compute step length
------------------------------------------------------------
-- directional derivative
local gtd = g:dot(d) -- g * d
-- check that progress can be made along that direction
if gtd > -tolX then
break
end
-- reset initial guess for step size
if state.nIter == 1 then
tmp1:copy(g):abs()
t = min(1,1/tmp1:sum()) * learningRate
else
t = learningRate
end
-- optional line search: user function
local lsFuncEval = 0
if lineSearch and type(lineSearch) == 'function' then
-- perform line search, using user function
f,g,x,t,lsFuncEval = lineSearch(opfunc,x,t,d,f,g,gtd,lineSearchOpts)
table.insert(f_hist, f)
else
-- no line search, simply move with fixed-step
x:add(t,d)
if nIter ~= maxIter then
-- re-evaluate function only if not in last iteration
-- the reason we do this: in a stochastic setting,
-- no use to re-evaluate that function here
f,g = opfunc(x)
lsFuncEval = 1
table.insert(f_hist, f)
end
end
-- update func eval
currentFuncEval = currentFuncEval + lsFuncEval
state.funcEval = state.funcEval + lsFuncEval
------------------------------------------------------------
-- check conditions
------------------------------------------------------------
if nIter == maxIter then
-- no use to run tests
verbose('reached max number of iterations')
break
end
if currentFuncEval >= maxEval then
-- max nb of function evals
verbose('max nb of function evals')
break
end
tmp1:copy(g):abs()
if tmp1:sum() <= tolFun then
-- check optimality
verbose('optimality condition below tolFun')
break
end
tmp1:copy(d):mul(t):abs()
if tmp1:sum() <= tolX then
-- step size below tolX
verbose('step size below tolX')
break
end
if abs(f-f_old) < tolX then
-- function value changing less than tolX
verbose('function value changing less than tolX')
break
end
if nIter % tolFunRelativeInterval == 0 then
if f_past ~= nil and (abs(f-f_past) / f_past) < tolFunRelative then
verbose('relative change in function value is less than tolFunRelative')
break
end
f_past = f
end
end
-- save state
state.old_dirs = old_dirs
state.old_stps = old_stps
state.Hdiag = Hdiag
state.g_old = g_old
state.f_old = f_old
state.t = t
state.d = d
-- return optimal x, and history of f(x)
return x,f_hist,currentFuncEval
end
return {
optimize = optim.lbfgs
}