neuropercolation/evaluation/2Layer Suscept.py

# -*- coding: utf-8 -*-
"""
Created on Tue Aug 30 14:25:12 2022

@author: timof
"""

import sys
import os
import json

from plot import qtplot


import math as m
import numpy as np


vect = np.vectorize

@vect
def log2(x):
    try:
        return m.log2(x)
    except ValueError:
        if x==0:
            return float(0)
        else:
            raise
            
path = '/cloud/Public/_data/neuropercolation/2lay/steps=100100/'
suspath = path + 'suscepts_euk/'
kurpath = path + 'kurts_euk/'
chi = chr(967)
vareps = chr(949)
kappa = chr(954)
rho=chr(961)

vals = [[],[]]

runsteps = 100000

#eps_space = np.linspace(0.005, 0.1, 20)
eps_space = np.linspace(0.005, 0.5, 100)

epses=20

dims = list(range(3,27,2))#+[16]

def __calc_chi(mode='density'):
    ma=[]
    s=[]
    k=[]
    
    suffix = mode

    for dim in dims:
        try:
            with open(suspath+f"radium_{suffix}_dim={dim:02}.txt", 'r', encoding='utf-8') as f:
                magnet = json.load(f)
            with open(suspath+f"susceptibility_{suffix}_dim={dim:02}.txt", 'r', encoding='utf-8') as f:
                suscept = json.load(f)
            with open(kurpath+f"kurtosis_{suffix}_dim={dim:02}.txt", 'r', encoding='utf-8') as f:
                kurt = []+json.load(f)
        except:
            magnet=[]
            suscept = []
            kurt = []
            jumped = False
            print('suscept or kurt file not found')
            if not os.path.exists(suspath):
                os.makedirs(suspath)
            if not os.path.exists(kurpath):
                os.makedirs(kurpath)
            for epsilon in eps_space:
                try:
                    with open(path+f"dim={dim:02}/eps={round(epsilon,3):.3f}_activation.txt", 'r', encoding='utf-8') as f:
                        activation = np.array(json.load(f)[100:])
                    
                    if mode=='density':
                        mag = np.sum(np.linalg.norm(activation,axis=1))/len(activation)                  # density
                        mag2 = np.sum(np.linalg.norm(activation,axis=1)**2)/len(activation)              # density
                        mag4 = np.sum(np.linalg.norm(activation,axis=1)**4)/len(activation)              # density
                    elif mode=='absolute':
                        mag = np.sum(np.linalg.norm(activation*dim**2,axis=1))/len(activation)                 # density
                        mag2 = np.sum(np.linalg.norm(activation*dim**2,axis=1)**2)/len(activation)              # density
                        mag4 = np.sum(np.linalg.norm(activation*dim**2,axis=1)**4)/len(activation)              # density
                    
                        
                    mag = round(mag,6)
                    fluct = round(mag2-mag**2,6)
                    tail = round(mag4/mag2**2,6)
                    
                    magnet.append(mag)
                    suscept.append(fluct)
                    kurt.append(tail)
                    print(f"Done dim={dim:02} eps={round(epsilon,3):.3f}: mag={mag}")
                    print(f"Done dim={dim:02} eps={round(epsilon,3):.3f}: fluct={fluct}")
                    print(f"Done dim={dim:02} eps={round(epsilon,3):.3f}: tail ={tail}")
                    print(f"===========================================================")
                    jumped=True
                except:
                    suscept.append(0)
                    if not jumped:
                        kurt.append(1)
                    elif jumped:
                        kurt.append(3)
                    print(f"Missing dim={dim:02} eps={round(epsilon,3):.3f}")
            with open(suspath+f"radium_{suffix}_dim={dim:02}.txt", 'w', encoding='utf-8') as f:
                json.dump(magnet, f, ensure_ascii=False, indent=1)
            with open(suspath+f"susceptibility_{suffix}_dim={dim:02}.txt", 'w', encoding='utf-8') as f:
                json.dump(suscept, f, ensure_ascii=False, indent=1)
            with open(kurpath+f"kurtosis_{suffix}_dim={dim:02}.txt", 'w', encoding='utf-8') as f:
                json.dump(kurt, f, ensure_ascii=False, indent=1)
                
        ma.append([1]+magnet[:epses])
        s.append([0]+suscept[:epses])
        k.append([1]+kurt[:epses])
    
    return ma,s,k

ma,s,k = __calc_chi()
#%%
qtplot(f"Magnetisation evolution for different automaton sizes",
        [[0]+list(eps_space[:epses])]*len(ma),
        [[dims[len(dims)-1-d]**2]+list(dims[len(dims)-1-d]**2*np.array(ls[1:])) for d,ls in enumerate(ma[::-1])],
        [f'dim={dim}x{dim}' for dim in dims[::-1]],
        y_tag = f'mean cycle {kappa}',
        export=True,
        path=path+"magnets/",
        filename=f'ep_radius_density_dims=3-9_steps={runsteps}_extra.png',
        close=False)

qtplot(f"Susceptibility evolution for different automaton sizes",
        [[0]+list(eps_space[:epses])]*len(ma),
        [[0]+list(np.array(sus[1:])*dims[len(dims)-1-i]**2) for i,sus in enumerate(s[::-1])],
        [f'dim={dim}x{dim}' for dim in dims[::-1]],
        y_tag = f'susceptibility {chi}',
        export=True,
        path=suspath,
        filename=f'eps+0_susceptibility_density_dims=3-15_odd_steps={runsteps}_extra.png',
        close=False)

qtplot("Kurtosis evolution for different automaton sizes",
        [[0]+list(eps_space[:epses])]*len(k),
        k[::-1],
        [f'dim={dim}x{dim}' for dim in dims[::-1]],
        y_tag = f'kurtosis U',
        y_range = (1,2),
        y_log=True,
        export=True,
        path=kurpath,
        filename=f'eps+0_kurtosis_density_dims=3-15_odd_steps={runsteps}_extra.png',
        close=False)
more evaluations 2023-09-30 17:53:06 +00:00			`# -- coding: utf-8 --`
			`"""`
			`Created on Tue Aug 30 14:25:12 2022`

			`@author: timof`
			`"""`

			`import sys`
			`import os`
			`import json`

			`from plot import qtplot`


			`import math as m`
			`import numpy as np`


			`vect = np.vectorize`

			`@vect`
			`def log2(x):`
			`try:`
			`return m.log2(x)`
			`except ValueError:`
			`if x==0:`
			`return float(0)`
			`else:`
			`raise`

			`path = '/cloud/Public/_data/neuropercolation/2lay/steps=100100/'`
			`suspath = path + 'suscepts_euk/'`
			`kurpath = path + 'kurts_euk/'`
			`chi = chr(967)`
			`vareps = chr(949)`
			`kappa = chr(954)`
			`rho=chr(961)`

			`vals = [[],[]]`

			`runsteps = 100000`

			`#eps_space = np.linspace(0.005, 0.1, 20)`
			`eps_space = np.linspace(0.005, 0.5, 100)`

			`epses=20`

			`dims = list(range(3,27,2))#+[16]`

			`def __calc_chi(mode='density'):`
			`ma=[]`
			`s=[]`
			`k=[]`

			`suffix = mode`

			`for dim in dims:`
			`try:`
			`with open(suspath+f"radium_{suffix}_dim={dim:02}.txt", 'r', encoding='utf-8') as f:`
			`magnet = json.load(f)`
			`with open(suspath+f"susceptibility_{suffix}_dim={dim:02}.txt", 'r', encoding='utf-8') as f:`
			`suscept = json.load(f)`
			`with open(kurpath+f"kurtosis_{suffix}_dim={dim:02}.txt", 'r', encoding='utf-8') as f:`
			`kurt = []+json.load(f)`
			`except:`
			`magnet=[]`
			`suscept = []`
			`kurt = []`
			`jumped = False`
			`print('suscept or kurt file not found')`
			`if not os.path.exists(suspath):`
			`os.makedirs(suspath)`
			`if not os.path.exists(kurpath):`
			`os.makedirs(kurpath)`
			`for epsilon in eps_space:`
			`try:`
			`with open(path+f"dim={dim:02}/eps={round(epsilon,3):.3f}_activation.txt", 'r', encoding='utf-8') as f:`
			`activation = np.array(json.load(f)[100:])`

			`if mode=='density':`
			`mag = np.sum(np.linalg.norm(activation,axis=1))/len(activation) # density`
			`mag2 = np.sum(np.linalg.norm(activation,axis=1)**2)/len(activation) # density`
			`mag4 = np.sum(np.linalg.norm(activation,axis=1)**4)/len(activation) # density`
			`elif mode=='absolute':`
			`mag = np.sum(np.linalg.norm(activationdim*2,axis=1))/len(activation) # density`
			`mag2 = np.sum(np.linalg.norm(activationdim2,axis=1)*2)/len(activation) # density`
			`mag4 = np.sum(np.linalg.norm(activationdim2,axis=1)*4)/len(activation) # density`


			`mag = round(mag,6)`
			`fluct = round(mag2-mag**2,6)`
			`tail = round(mag4/mag2**2,6)`

			`magnet.append(mag)`
			`suscept.append(fluct)`
			`kurt.append(tail)`
			`print(f"Done dim={dim:02} eps={round(epsilon,3):.3f}: mag={mag}")`
			`print(f"Done dim={dim:02} eps={round(epsilon,3):.3f}: fluct={fluct}")`
			`print(f"Done dim={dim:02} eps={round(epsilon,3):.3f}: tail ={tail}")`
			`print(f"===========================================================")`
			`jumped=True`
			`except:`
			`suscept.append(0)`
			`if not jumped:`
			`kurt.append(1)`
			`elif jumped:`
			`kurt.append(3)`
			`print(f"Missing dim={dim:02} eps={round(epsilon,3):.3f}")`
			`with open(suspath+f"radium_{suffix}_dim={dim:02}.txt", 'w', encoding='utf-8') as f:`
			`json.dump(magnet, f, ensure_ascii=False, indent=1)`
			`with open(suspath+f"susceptibility_{suffix}_dim={dim:02}.txt", 'w', encoding='utf-8') as f:`
			`json.dump(suscept, f, ensure_ascii=False, indent=1)`
			`with open(kurpath+f"kurtosis_{suffix}_dim={dim:02}.txt", 'w', encoding='utf-8') as f:`
			`json.dump(kurt, f, ensure_ascii=False, indent=1)`

			`ma.append([1]+magnet[:epses])`
			`s.append([0]+suscept[:epses])`
			`k.append([1]+kurt[:epses])`

			`return ma,s,k`

			`ma,s,k = __calc_chi()`
			`#%%`
			`qtplot(f"Magnetisation evolution for different automaton sizes",`
			`[[0]+list(eps_space[:epses])]*len(ma),`
			`[[dims[len(dims)-1-d]2]+list(dims[len(dims)-1-d]2*np.array(ls[1:])) for d,ls in enumerate(ma[::-1])],`
			`[f'dim={dim}x{dim}' for dim in dims[::-1]],`
			`y_tag = f'mean cycle {kappa}',`
			`export=True,`
			`path=path+"magnets/",`
			`filename=f'ep_radius_density_dims=3-9_steps={runsteps}_extra.png',`
			`close=False)`

			`qtplot(f"Susceptibility evolution for different automaton sizes",`
			`[[0]+list(eps_space[:epses])]*len(ma),`
			`[[0]+list(np.array(sus[1:])dims[len(dims)-1-i]*2) for i,sus in enumerate(s[::-1])],`
			`[f'dim={dim}x{dim}' for dim in dims[::-1]],`
			`y_tag = f'susceptibility {chi}',`
			`export=True,`
			`path=suspath,`
			`filename=f'eps+0_susceptibility_density_dims=3-15_odd_steps={runsteps}_extra.png',`
			`close=False)`

			`qtplot("Kurtosis evolution for different automaton sizes",`
			`[[0]+list(eps_space[:epses])]*len(k),`
			`k[::-1],`
			`[f'dim={dim}x{dim}' for dim in dims[::-1]],`
			`y_tag = f'kurtosis U',`
			`y_range = (1,2),`
			`y_log=True,`
			`export=True,`
			`path=kurpath,`
			`filename=f'eps+0_kurtosis_density_dims=3-15_odd_steps={runsteps}_extra.png',`
			`close=False)`