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gui: clean up file

time-shift
Houtan Bastani 2019-02-05 15:46:57 +01:00
parent ce3be98aa0
commit 0ad8bfbd16
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GPG Key ID: 000094FB955BE169
1 changed files with 98 additions and 124 deletions
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222
matlab/+gui/+perfect-foresight/run.m
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@ -11,7 +11,7 @@ function varargout = run(json)
% varargout{1} [string] if desired, return output as JSON string
%
% SPECIAL REQUIREMENTS
% dynare must have been run with the option: json=compute
% none
% Copyright (C) 2019 Dynare Team
%
@ -32,6 +32,7 @@ function varargout = run(json)
global M_ options_ oo_ ys0_ ex0_
%% Check Inputs
if nargin ~= 1 || ~ischar(json)
error('function takes one string input argument')
end
@ -40,14 +41,11 @@ if nargout > 1
error('function provides up to one output argument')
end
%loading JSON
jm = loadjson(json,'SimplifyCell',0);
%% Read JSON
jm = loadjson(json, 'SimplifyCell', 0);
%We test if jsonload loads string or char
% jsl=length(class(jm.jsontest{1,1}));
% INITVAL instructions
%we initialize exogenous shocks to zero and compute initial ss
%% INITVAL instructions
% initialize exogenous shocks to zero and compute initial steady state
options_.initval_file = 0;
oo_.exo_steady_state(1:jm.exonum) = 0;
if M_.exo_nbr > 0
@ -58,199 +56,175 @@ if M_.exo_det_nbr > 0
end
steady;
if nargout == 1
data2json=struct();
data2json.steady_state1=oo_.steady_state;
data2json = struct();
data2json.steady_state1 = oo_.steady_state;
end
% ENDVAL instructions
%we initialize exogenous shocks to zero and compute final ss unless there is a permanent shock
%% ENDVAL instructions
% initialize exogenous shocks to zero and compute final ss unless there is a permanent shock
ys0_= oo_.steady_state;
ex0_ = oo_.exo_steady_state;
if jm.permanentshockexist==0
if jm.permanentshockexist == 0
oo_.exo_steady_state(1:jm.exonum) = 0;
else
for exoiter = 1:length(jm.permanentshocksdescription)
currentshock=jm.permanentshocksdescription(exoiter);
currentshock = jm.permanentshocksdescription(exoiter);
oo_.exo_steady_state(currentshock{1}.shockindex+1) = currentshock{1}.shockvalue;
if (currentshock{1}.shockstartperiod)>1
if currentshock{1}.shockstartperiod > 1
%in case the permanent shock does not start at the initial period, we add a shocks block to mask the unnecessary periods
M_.det_shocks = [ M_.det_shocks;struct('exo_det',0,'exo_id',(currentshock{1}.shockindex+1),'multiplicative',0,'periods',1:(currentshock{1}.shockstartperiod-1),'value',0.0) ];
end
end
end
steady;
savedpermanentSS=oo_.steady_state;
savedpermanentSS = oo_.steady_state;
if nargout == 1
data2json.steady_state2=oo_.steady_state;
data2json.steady_state2 = oo_.steady_state;
end
if jm.transitoryshockexist==1
% SHOCKS instructions (for transitory shocks)
%% SHOCKS instructions (for transitory shocks)
if jm.transitoryshockexist == 1
for exotriter = 1:length(jm.shocksdescription)
currenttrshock=jm.shocksdescription(exotriter);
% disp(currenttrshock{1}.shockname);
% disp(class(currenttrshock{1}.shockstartperiod));
currenttrshock = jm.shocksdescription(exotriter);
M_.det_shocks = [ M_.det_shocks;struct('exo_det',0,'exo_id',(currenttrshock{1}.shockindex+1),'multiplicative',0,'periods',currenttrshock{1}.shockstartperiod:currenttrshock{1}.shockendperiod,'value',currenttrshock{1}.shockvalue) ];
%oo_.exo_steady_state(str2num(currentshock{1}.shockindex)+1) = currentshock{1}.shockvalue;
end
M_.exo_det_length = 0;
end
if ((jm.nonanticipatedshockexist==1) || (jm.delayexist==1))
nonanticip=jm.nonanticipmatrix;
rowindex=1;
firstsimul=0;
while nonanticip{rowindex}{1}>0
if jm.nonanticipatedshockexist == 1 || jm.delayexist == 1
nonanticip = jm.nonanticipmatrix;
rowindex = 1;
firstsimul = 0;
while nonanticip{rowindex}{1} > 0
currentperiod=nonanticip{rowindex}{1};
if currentperiod==1
%there are nonanticipated shocks to add at first period
if nonanticip{rowindex}{4}==0
%this is a current nonanticipated shock
if currentperiod == 1
% there are nonanticipated shocks to add at first period
if nonanticip{rowindex}{4} == 0
% this is a current nonanticipated shock
M_.det_shocks = [ M_.det_shocks;struct('exo_det',0,'exo_id',(nonanticip{rowindex}{2}+1),'multiplicative',0,'periods',1:1,'value',nonanticip{rowindex}{7}) ];
else
%this is a delayed nonanticipated shock
% this is a delayed nonanticipated shock
M_.det_shocks = [ M_.det_shocks;struct('exo_det',0,'exo_id',(nonanticip{rowindex}{2}+1),'multiplicative',0,'periods',(nonanticip{rowindex}{5}):(nonanticip{rowindex}{6}),'value',nonanticip{rowindex}{7}) ];
end
if nonanticip{rowindex+1}{1}~=currentperiod
%when we have tracked all first period shocks we can simulate
if nonanticip{rowindex+1}{1} ~= currentperiod
% when we have tracked all first period shocks we can simulate
options_.periods = jm.simperiods;
yy=oo_.steady_state;
yy = oo_.steady_state;
perfect_foresight_setup;
[rowexo,colexo]=size(oo_.exo_simul);
[rowexo, colexo] = size(oo_.exo_simul);
perfect_foresight_solver;
if nonanticip{rowindex+1}{1}>0
%we collect all the path from ooendo period 1 to just before the next shock...
yy=[yy,oo_.endo_simul(:,2:(2+(nonanticip{rowindex+1}{1}-currentperiod-1)))];
if nonanticip{rowindex+1}{1} > 0
% we collect all the path from ooendo period 1 to just before the next shock...
yy = [yy oo_.endo_simul(:,2:(2+(nonanticip{rowindex+1}{1}-currentperiod-1)))];
else
%... or if there are no more shocks we collect the whole path
yy=[yy,oo_.endo_simul(:,2:end)];
% or if there are no more shocks we collect the whole path
yy = [yy oo_.endo_simul(:,2:end)];
end
ooexosaved=oo_.exo_simul;
firstsimul=1;
ooexosaved = oo_.exo_simul;
firstsimul = 1;
end
else
%currentperiod is larger than one: we first perform perfect foresight simulation with initial period 1 conditions
if firstsimul==0
%Initializing the first simulation
% currentperiod is larger than one: we first perform perfect foresight simulation with initial period 1 conditions
if firstsimul == 0
% Initializing the first simulation
options_.periods = jm.simperiods;
yy=oo_.steady_state;
yy = oo_.steady_state;
perfect_foresight_setup;
[rowexo,colexo]=size(oo_.exo_simul);
[rowexo, colexo] = size(oo_.exo_simul);
perfect_foresight_solver;
%In this because there is at least one shock we did not consider yet in the first period, we only save the path from the beginning up the period just before the current
yy=[yy,oo_.endo_simul(:,2:currentperiod)];
ooexosaved=oo_.exo_simul;
firstsimul=1;
% In this because there is at least one shock we did not consider yet in the first period, we only save the path from the beginning up the period just before the current
yy = [yy oo_.endo_simul(:,2:currentperiod)];
ooexosaved = oo_.exo_simul;
firstsimul = 1;
end
if nonanticip{rowindex}{3}==1
%this is a permanent shock
oo_.exo_steady_state((nonanticip{rowindex}{2}+1)) = nonanticip{rowindex}{7};
if nonanticip{rowindex}{3} == 1
% permanent shock
oo_.exo_steady_state(nonanticip{rowindex}{2}+1) = nonanticip{rowindex}{7};
steady;
savedpermanentSS=oo_.steady_state;
savedpermanentSS = oo_.steady_state;
if nargout == 1
data2json.steady_state2=oo_.steady_state;
data2json.steady_state2 = oo_.steady_state;
end
if nonanticip{rowindex}{4}==0
%this is a current permanent nonanticipated shock
ooexosaved((currentperiod+1):end,(nonanticip{rowindex}{2}+1))=nonanticip{rowindex}{7};
if nonanticip{rowindex}{4} == 0
% current permanent nonanticipated shock
ooexosaved(currentperiod+1:end, nonanticip{rowindex}{2}+1) = nonanticip{rowindex}{7};
else
%this is a delayed permanent nonanticipated shock
ooexosaved((nonanticip{rowindex}{5}+1):end,(nonanticip{rowindex}{2}+1))=nonanticip{rowindex}{7};
% delayed permanent nonanticipated shock
ooexosaved(nonanticip{rowindex}{5}+1:end, nonanticip{rowindex}{2}+1) = nonanticip{rowindex}{7};
end
else
%this is not a permanent shock
%we add new shocks in the saved timepath with original time indexes
if nonanticip{rowindex}{4}==0
%this is a single current nonanticipated shock
ooexosaved(currentperiod+1,(nonanticip{rowindex}{2}+1))=nonanticip{rowindex}{7};
%oo_.exo_simul(2,(nonanticip{rowindex}{2}+1))=nonanticip{rowindex}{7};
% not a permanent shock
% add new shocks in the saved timepath with original time indexes
if nonanticip{rowindex}{4} == 0
% this is a single current nonanticipated shock
ooexosaved(currentperiod+1, nonanticip{rowindex}{2}+1) = nonanticip{rowindex}{7};
else
%this is a delayed nonanticipated shock
ooexosaved((nonanticip{rowindex}{5}+1):(nonanticip{rowindex}{6}+1),(nonanticip{rowindex}{2}+1))=nonanticip{rowindex}{7};
%oo_.exo_simul((nonanticip{rowindex}{5}+1):(nonanticip{rowindex}{6}+1),(nonanticip{rowindex}{2}+1))=nonanticip{rowindex}{7};
% this is a delayed nonanticipated shock
ooexosaved(nonanticip{rowindex}{5}+1:nonanticip{rowindex}{6}+1, nonanticip{rowindex}{2}+1) = nonanticip{rowindex}{7};
end
end
%we copy only the necessary window in oo_.exo_simul
%oo_.exo_simul=ooexosaved((currentperiod+1):end,:);
oo_.exo_simul=[zeros(1,colexo);ooexosaved((currentperiod+1):end,:)];
% copy only the necessary window in oo_.exo_simul
oo_.exo_simul = [zeros(1, colexo); ooexosaved(currentperiod+1:end, :)];
%we fill oo_.exo_simul until it has the correct size depending on of there are permanent shocks or not
% fill oo_.exo_simul until it has the correct size depending on of there are permanent shocks or not
if jm.permanentshockexist==1
%if there is a permanent shock we fill with last value of ooexosaved
%oo_.exo_simul((length(ooexosaved((currentperiod+1):end,:))+1):rowexo,:)=ones(rowexo-(length(ooexosaved((currentperiod+1):end,:))+1)+1,1)*ooexosaved(end,:);
%oo_.exo_simul((ooexolength+1):rowexo,:)=ones(rowexo-ooexolength,1)*ooexosaved(end,:);
oo_.exo_simul=[oo_.exo_simul;ones(rowexo-size(oo_.exo_simul, 1),1)*ooexosaved(end,:)];
% if there is a permanent shock, fill with last value of ooexosaved
oo_.exo_simul = [oo_.exo_simul; ones(rowexo-size(oo_.exo_simul, 1), 1)*ooexosaved(end, :)];
else
%otherwise we fill with zeros
%oo_.exo_simul((length(ooexosaved((currentperiod+1):end,:))+1):rowexo,:)=zeros(rowexo-(length(ooexosaved((currentperiod+1):end,:))+1)+1,colexo);
%oo_.exo_simul((ooexolength+1):rowexo,:)=zeros(rowexo-ooexolength,colexo);
oo_.exo_simul=[oo_.exo_simul;zeros(rowexo-size(oo_.exo_simul, 1),colexo)];
% otherwise fill with zeros
oo_.exo_simul = [oo_.exo_simul; zeros(rowexo-size(oo_.exo_simul, 1), colexo)];
end
if nonanticip{rowindex+1}{1}~=currentperiod
%when we have tracked all the non-anticipated/delayed shocks for the current period, we can simulate
if jm.permanentshockexist==1
%if there are permanent shocks we fill oo_.endo with finalSS
oo_.endo_simul=savedpermanentSS*ones(1,options_.periods+2);
if nonanticip{rowindex+1}{1} ~= currentperiod
% when we have tracked all the non-anticipated/delayed shocks for the current period, we can simulate
if jm.permanentshockexist == 1
% if there are permanent shocks, fill oo_.endo with finalSS
oo_.endo_simul = savedpermanentSS*ones(1, options_.periods+2);
else
%no permanent shocks we fill oo_.endo with initialSS
oo_.endo_simul=oo_.steady_state*ones(1,options_.periods+2);
% no permanent shocks, fill oo_.endo with initialSS
oo_.endo_simul = oo_.steady_state*ones(1, options_.periods+2);
end
%we need to change oo_.endo_simul first value that gives the initial state of the economy
oo_.endo_simul(:,1)=yy(:,end);
% change oo_.endo_simul first value that gives the initial state of the economy
oo_.endo_simul(:, 1) = yy(:,end);
perfect_foresight_solver;
if nonanticip{rowindex+1}{1}>0
%we collect all the path from ooendo period 1 to just before the next shock...
yy=[yy,oo_.endo_simul(:,2:(2+(nonanticip{rowindex+1}{1}-currentperiod-1)))];
if nonanticip{rowindex+1}{1} > 0
% collect all the path from ooendo period 1 to just before the next shock...
yy = [yy oo_.endo_simul(:, 2:2+nonanticip{rowindex+1}{1}-currentperiod-1)];
else
%... or if there are no more shocks we collect the whole path
yy=[yy,oo_.endo_simul(:,2:end)];
% or if there are no more shocks we collect the whole path
yy = [yy oo_.endo_simul(:, 2:end)];
end
end
end
rowindex=rowindex+1;
end % while jm.nonanticipmatrix{rowindex}{1}>0
%we copy the endo path back
oo_.endo_simul=yy;
rowindex = rowindex+1;
end
% copy the endo path back
oo_.endo_simul = yy;
else
%if there are no unanticipated shocks we perform the simulation
% if there are no unanticipated shocks we perform the simulation
options_.periods = jm.simperiods;
perfect_foresight_setup;
perfect_foresight_solver;
end
if nargout == 1
plotlgt=length(oo_.endo_simul);
data2json.endosimul_length=plotlgt;
data2json.endo_names=char(M_.endo_names);
data2json.endo_nbr=M_.endo_nbr;
plotlgt = length(oo_.endo_simul);
data2json.endosimul_length = plotlgt;
data2json.endo_names = char(M_.endo_names);
data2json.endo_nbr = M_.endo_nbr;
for nendo = 1:M_.endo_nbr
data2json.endo_simul.(strtrim(char(M_.endo_names(nendo,:))))=oo_.endo_simul(nendo,:);
data2json.endo_simul.(strtrim(char(M_.endo_names(nendo, :)))) = oo_.endo_simul(nendo, :);
end
data2json.endo_simul.plotx=[0:1:plotlgt];
varargout{1} = savejson('',data2json,'');
data2json.endo_simul.plotx = 0:plotlgt;
varargout{1} = savejson('', data2json, '');
end
end