Module: CodeRunner::Gs2::GSLVectors

Included in:

CodeRunner::Gs2

Defined in:

lib/gs2crmod/gsl_data.rb

Instance Method Summary

• #apar2_over_time_gsl_vector(options) ⇒ Object
• #drhodpsi_gsl_vector(options) ⇒ Object

  This function reads in the ‘drhodpsi’ variable from the netcdf file.

• #dt_gsl_vector(options) ⇒ Object

  The size of each time step, indexed by time, normalised to a/v_th1.

• #es_heat_flux_by_kx_over_time_gsl_vector(options) ⇒ Object
• #es_heat_flux_by_ky_over_time_gsl_vector(options) ⇒ Object
• #es_heat_flux_over_kx_gsl_vector(options) ⇒ Object
• #es_heat_flux_over_kxy_gsl_vector(options) ⇒ Object

  This function will output the heat flux as a function of kx or ky.

• #es_heat_flux_over_ky_gsl_vector(options) ⇒ Object
• #es_heat_flux_over_time_gsl_vector(options) ⇒ Object
• #es_heat_par_over_time_gsl_vector(options) ⇒ Object (also: #es_heat_par_gsl_vector)
• #es_heat_perp_over_time_gsl_vector(options) ⇒ Object (also: #es_heat_perp_gsl_vector)
• #es_mom_flux_over_time_gsl_vector(options) ⇒ Object
• #es_part_flux_over_time_gsl_vector(options) ⇒ Object
• #frequency_by_kx_over_time_gsl_vector(options) ⇒ Object

  The real frequency of the fluctuations, read from the .out file, indexed by time and normalised to vth_1/a.

• #frequency_by_kxy_over_time_gsl_vector(options) ⇒ Object
• #frequency_by_ky_over_time_gsl_vector(options) ⇒ Object
• #growth_rate_by_kx_over_time_gsl_vector(options) ⇒ Object

  The growth rate of the fluctuations, calculated from the potential, indexed by time and normalised to vth_1/a.

• #growth_rate_by_kxy_over_time_gsl_vector(options) ⇒ Object
• #growth_rate_by_ky_over_time_gsl_vector(options) ⇒ Object

  The growth rate of the fluctuations, calculated from the potential, indexed by time and normalised to vth_1/a.

• #growth_rate_over_kx_gsl_vector(options) ⇒ Object

  The growth rate, calculated from the potential, indexed by kx.

• #growth_rate_over_kx_slice_gsl_vector(options) ⇒ Object

  The growth rate, calculated from the potential, indexed by kx.

• #growth_rate_over_ky_gsl_vector(options) ⇒ Object

  The growth rate, calculated from the potential, indexed by ky.

• #growth_rate_over_ky_slice_gsl_vector(options) ⇒ Object

  The growth rate, calculated from the potential, indexed by ky.

• #hflux_tot_over_time_gsl_vector(options) ⇒ Object (also: #hflux_tot_gsl_vector)
• #kpar_gsl_vector(options) ⇒ Object
• #linked_kx_elements_gsl_vector(options) ⇒ Object
• #lpc_energy_gsl_vector(options) ⇒ Object

  Velocity space diagnostics: fraction of dist func in higher energy harmonics.

• #lpc_pitch_angle_gsl_vector(options) ⇒ Object

  Velocity space diagnostics: fraction of dist func in higher pitch angle harmonics.

• #mean_flow_velocity_over_x_gsl_vector(options) ⇒ Object

  This function returns the mean flow velocity as a function of x (the radial coordinate).

• #par_mom_flux_over_time_gsl_vector(options) ⇒ Object
• #perp_mom_flux_over_time_gsl_vector(options) ⇒ Object
• #phi0_by_kx_by_ky_over_time_gsl_vector(options) ⇒ Object
• #phi2_by_kx_over_time_gsl_vector(options) ⇒ Object
• #phi2_by_ky_over_time_gsl_vector(options) ⇒ Object
• #phi2_by_mode_over_time_gsl_vector(options) ⇒ Object
• #phi2tot_over_time_gsl_vector(options) ⇒ Object

  The square of the potential summed over all wave numbers, indexed by time, normalised to (e/T)(rho_1/a).

• #phi_along_field_line_gsl_vector(options) ⇒ Object
• #phi_for_eab_movie_gsl_vector(options) ⇒ Object
• #scan_parameter_value_gsl_vector(options) ⇒ Object
• #spectrum_over_kpar_gsl_vector(options) ⇒ Object
• #spectrum_over_kx_avg_gsl_vector(options) ⇒ Object
• #spectrum_over_kx_gsl_vector(options) ⇒ Object
• #spectrum_over_kxy_avg_gsl_vector(options) ⇒ Object

  spectrum averaged in time.

• #spectrum_over_kxy_gsl_vector(options) ⇒ Object
• #spectrum_over_ky_avg_gsl_vector(options) ⇒ Object
• #spectrum_over_ky_gsl_vector(options) ⇒ Object
• #theta_along_field_line_gsl_vector(options) ⇒ Object
• #tpar2_by_mode_over_time_gsl_vector(options) ⇒ Object
• #tperp2_by_mode_over_time_gsl_vector(options) ⇒ Object
• #transient_amplification_over_kx_gsl_vector(options) ⇒ Object
• #transient_amplification_over_ky_gsl_vector(options) ⇒ Object
• #transient_es_heat_flux_amplification_over_kx_gsl_vector(options) ⇒ Object
• #transient_es_heat_flux_amplification_over_kxy_gsl_vector(options) ⇒ Object
• #transient_es_heat_flux_amplification_over_ky_gsl_vector(options) ⇒ Object
• #vres_energy_gsl_vector(options) ⇒ Object

  Velocity space diagnostics: integral error due to energy resolution.

• #vres_pitch_angle_gsl_vector(options) ⇒ Object

  Velocity space diagnostics: integral error due to pitch angle resolution.

• #x_gsl_vector(options) ⇒ Object
• #y_gsl_vector(options) ⇒ Object
• #zf_velocity_over_x_gsl_vector(options) ⇒ Object

  This function returns the zonal flow velocity as a function of x (the radial coordinate).

• #zonal_spectrum_gsl_vector(options) ⇒ Object

Instance Method Details

#apar2_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 224

def apar2_over_time_gsl_vector(options)

  Dir.chdir(@directory) do      #Necessary options: ky
    #log 'about to open netcdf file'
    #options.setup_time_window
    phis = netcdf_file.var('apar2').get('start'=>[options[:begin_element]], 'end'=>[options[:end_element]] ).to_a
    log 'about to allocate gsl vector'
    vec = GSL::Vector.alloc(phis)
    log 'finished'
    return fix_norm(vec, 1, options)
  end
end

#drhodpsi_gsl_vector(options) ⇒ Object

This function reads in the ‘drhodpsi’ variable from the netcdf file.

# File 'lib/gs2crmod/gsl_data.rb', line 1023

def drhodpsi_gsl_vector(options)
  drhodpsi = netcdf_file.var('drhodpsi').get()[0]
  return drhodpsi
end

#dt_gsl_vector(options) ⇒ Object

The size of each time step, indexed by time, normalised to a/v_th1.

# File 'lib/gs2crmod/gsl_data.rb', line 355

def dt_gsl_vector(options)
  t = gsl_vector('t', options)
  size = t.size
  # NB t already has norm fixed
  return t.subvector(1, size - 1) - t.subvector(0, size-1)
end

#es_heat_flux_by_kx_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 400

def es_heat_flux_by_kx_over_time_gsl_vector(options)
  options[:direction] = :kx
  es_heat_flux_by_kxy_over_time_gsl_vector(options)
end

#es_heat_flux_by_ky_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 405

def es_heat_flux_by_ky_over_time_gsl_vector(options)
  options[:direction] = :ky
  es_heat_flux_by_kxy_over_time_gsl_vector(options)
end

#es_heat_flux_over_kx_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 438

def es_heat_flux_over_kx_gsl_vector(options)
  options[:direction] = :kx
  es_heat_flux_over_kxy_gsl_vector(options)
end

#es_heat_flux_over_kxy_gsl_vector(options) ⇒ Object

This function will output the heat flux as a function of kx or ky. Default behaviour will be to average the heat flux over the time domain.

# File 'lib/gs2crmod/gsl_data.rb', line 450

def es_heat_flux_over_kxy_gsl_vector(options)
  Dir.chdir(@directory) do
    kxy = options[:direction]
    raise "Please provide species_index " unless options[:species_index]
    if kxy==:ky
      es_heat = (netcdf_file.var('es_heat_flux_by_mode').get({'start' => [0,0,options[:species_index]-1, 0], 'end' => [-1,-1,options[:species_index]-1, -1]})) #index = [kx,ky,spec,t]
      #Need to average over time and sum over kx
      shape = es_heat.shape
      es_heat_av = []; temp = [];
      for iy in 0...shape[1]
        for ix in 0...shape[0]
          temp[ix] = es_heat[ix,iy,0,0..-1].sum / shape[3]
        end
        es_heat_av[iy] = temp.sum
      end
      return es_heat_av.to_gslv
    else
      es_heat = (netcdf_file.var('es_heat_flux_by_mode').get({'start' => [0,0,options[:species_index]-1, 0], 'end' => [-1,-1,options[:species_index]-1, -1]})) #index = [kx,ky,spec,t]
      shape = es_heat.shape
      es_heat_av = []; temp = [];
      for ix in 0...shape[0]
        for iy in 0...shape[1]
          temp[iy] = es_heat[ix,iy,0,0..-1].sum / shape[3]
        end
        es_heat_av[ix] = temp.sum
      end
      return es_heat_av.to_gslv.from_box_order
    end
  end
end

#es_heat_flux_over_ky_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 443

def es_heat_flux_over_ky_gsl_vector(options)
  options[:direction] = :ky
  es_heat_flux_over_kxy_gsl_vector(options)
end

#es_heat_flux_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 825

def es_heat_flux_over_time_gsl_vector(options)
  Dir.chdir(@directory) do

    options.setup_time_window
    return GSL::Vector.alloc(netcdf_file.var('es_heat_flux').get('start' => [options[:species_index].to_i - 1, options[:begin_element]], 'end' => [options[:species_index].to_i - 1, options[:end_element]]).to_a.flatten)
  end
end

#es_heat_par_over_time_gsl_vector(options) ⇒ Object Also known as: es_heat_par_gsl_vector

# File 'lib/gs2crmod/gsl_data.rb', line 833

def es_heat_par_over_time_gsl_vector(options)
  Dir.chdir(@directory) do

    options.setup_time_window
    return GSL::Vector.alloc(netcdf_file.var('es_heat_par').get('start' => [options[:species_index].to_i - 1, options[:begin_element]], 'end' => [options[:species_index].to_i - 1, options[:end_element]]).to_a.flatten)
  end
end

#es_heat_perp_over_time_gsl_vector(options) ⇒ Object Also known as: es_heat_perp_gsl_vector

# File 'lib/gs2crmod/gsl_data.rb', line 842

def es_heat_perp_over_time_gsl_vector(options)
  Dir.chdir(@directory) do

    options.setup_time_window
    return GSL::Vector.alloc(netcdf_file.var('es_heat_perp').get('start' => [options[:species_index].to_i - 1, options[:begin_element]], 'end' => [options[:species_index].to_i - 1, options[:end_element]]).to_a.flatten)
  end
end

#es_mom_flux_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 859

def es_mom_flux_over_time_gsl_vector(options)
  Dir.chdir(@directory) do
    options.setup_time_window
    return GSL::Vector.alloc(netcdf_file.var('es_mom_flux').get('start' => [options[:species_index].to_i - 1, options[:begin_element]], 'end' => [options[:species_index].to_i - 1, options[:end_element]]).to_a.flatten)
  end
end

#es_part_flux_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 866

def es_part_flux_over_time_gsl_vector(options)
  Dir.chdir(@directory) do
    options.setup_time_window
    return GSL::Vector.alloc(netcdf_file.var('es_part_flux').get('start' => [options[:species_index].to_i - 1, options[:begin_element]], 'end' => [options[:species_index].to_i - 1, options[:end_element]]).to_a.flatten)
  end
end

#frequency_by_kx_over_time_gsl_vector(options) ⇒ Object

The real frequency of the fluctuations, read from the .out file, indexed by time and normalised to vth_1/a. :ky_index or :kx_index must be specified in options.

# File 'lib/gs2crmod/gsl_data.rb', line 307

def frequency_by_kx_over_time_gsl_vector(options)
  options[:direction] = :kx
  frequency_by_kxy_over_time_gsl_vector(options)
end

#frequency_by_kxy_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 317

def frequency_by_kxy_over_time_gsl_vector(options)
  kxy = options[:direction]
  kxy_index = kxy + :_index
  kxys = get_list_of(kxy)
  desired_kxy = kxys[options[kxy_index]]
  raise "No k found at the desired index" if desired_kxy.nil?

  omega_reals = []
  File.open(@run_name+".out",'r') do |fileHandle|
    fileHandle.each_line do |fileLine|
      if fileLine.include?('aky=')  # Only examine the lines of the .out file that contain frequency information.

        index = fileLine.index('akx=')
        raise "akx wasn't found where it was expected in the .out file." if index.nil?
        akx = fileLine[(index+4)..-1].to_f

        index = fileLine.index('aky=')
        raise "aky wasn't found where it was expected in the .out file." if index.nil?
        aky = fileLine[(index+4)..-1].to_f

        index = fileLine.index('om=')
        raise "om wasn't found where it was expected in the .out file." if index.nil?
        omr = fileLine[(index+3)..-1].to_f
        if kxy == :kx
          # You need to be careful when testing equality of the desired k with the k in the .out file
          # since the .out file is only written to ~ 5 significant digits:
          omega_reals << omr if ((desired_kxy - akx).abs/(desired_kxy.abs + 1e-7) < 1e-4)
        else
          omega_reals << omr if ((desired_kxy - aky).abs/(desired_kxy.abs + 1e-7) < 1e-4)
        end
      end
    end
  end
  raise "No real frequencies found in the .out file for the desired k" if (omega_reals.size==0)
  GSL::Vector.alloc(omega_reals)
end

#frequency_by_ky_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 312

def frequency_by_ky_over_time_gsl_vector(options)
  options[:direction] = :ky
  frequency_by_kxy_over_time_gsl_vector(options)
end

#growth_rate_by_kx_over_time_gsl_vector(options) ⇒ Object

The growth rate of the fluctuations, calculated from the potential, indexed by time and normalised to vth_1/a. :kx or :kx_index must be specified in options

# File 'lib/gs2crmod/gsl_data.rb', line 280

def growth_rate_by_kx_over_time_gsl_vector(options)
  options[:direction] = :kx
  growth_rate_by_kxy_over_time_gsl_vector(options)
end

#growth_rate_by_kxy_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 292

def growth_rate_by_kxy_over_time_gsl_vector(options)
  # i.e. time_dependent_gr_by_ky_vs_time or phi2_by_kx_vs_time

  kxy = options[:direction]

  phi = gsl_vector("phi2_by_#{kxy}_over_time", options).log / 2.0

  size = phi.size
  dphi = phi.subvector(1, size - 1) - phi.subvector(0, size-1)
  # NB dt already has norm fixed, dphi is dimensionless
  return fix_norm(dphi/gsl_vector('dt'), 0, options)
end

#growth_rate_by_ky_over_time_gsl_vector(options) ⇒ Object

The growth rate of the fluctuations, calculated from the potential, indexed by time and normalised to vth_1/a. :ky or :ky_index must be specified in options

# File 'lib/gs2crmod/gsl_data.rb', line 287

def growth_rate_by_ky_over_time_gsl_vector(options)
  options[:direction] = :ky
  growth_rate_by_kxy_over_time_gsl_vector(options)
end

#growth_rate_over_kx_gsl_vector(options) ⇒ Object

The growth rate, calculated from the potential, indexed by kx. Only makes sense in linear calculations.

# File 'lib/gs2crmod/gsl_data.rb', line 363

def growth_rate_over_kx_gsl_vector(options)
  options[:direction] = :kx
  growth_rate_over_kxy_gsl_vector(options)
end

#growth_rate_over_kx_slice_gsl_vector(options) ⇒ Object

The growth rate, calculated from the potential, indexed by kx. Only makes sense in linear calculations.

# File 'lib/gs2crmod/gsl_data.rb', line 382

def growth_rate_over_kx_slice_gsl_vector(options)
  Dir.chdir(@directory) do
    slice_of_growth_rates = send(:growth_rate_at_ky_at_kx)[options[:ky]].values
    raise "Something went wrong: slice of growth rates seems empty" if slice_of_growth_rates.nil?
    return GSL::Vector.alloc(slice_of_growth_rates)
    #return GSL::Vector.alloc(send(:growth_rate_at_ky_at_kx[ky]).values)
  end
end

#growth_rate_over_ky_gsl_vector(options) ⇒ Object

The growth rate, calculated from the potential, indexed by ky. Only makes sense in linear calculations.

# File 'lib/gs2crmod/gsl_data.rb', line 368

def growth_rate_over_ky_gsl_vector(options)
  options[:direction] = :ky
  growth_rate_over_kxy_gsl_vector(options)
end

#growth_rate_over_ky_slice_gsl_vector(options) ⇒ Object

The growth rate, calculated from the potential, indexed by ky. Only makes sense in linear calculations.

# File 'lib/gs2crmod/gsl_data.rb', line 392

def growth_rate_over_ky_slice_gsl_vector(options)
  Dir.chdir(@directory) do
    slice_of_growth_rates = send(:growth_rate_at_ky_at_kx).values.map{|h| h[options[:kx]]}
    raise "Something went wrong: slice of growth rates seems empty" if slice_of_growth_rates.nil?
    return GSL::Vector.alloc(slice_of_growth_rates)
  end
end

#hflux_tot_over_time_gsl_vector(options) ⇒ Object Also known as: hflux_tot_gsl_vector

# File 'lib/gs2crmod/gsl_data.rb', line 813

def hflux_tot_over_time_gsl_vector(options)
  Dir.chdir(@directory) do
    options.setup_time_window
    narr = netcdf_file.var('hflux_tot').get('start' => [options[:begin_element]], 'end' => [options[:end_element]])
    #eputs 'Got narr'
    #ep 'hflux_tot', hflux
    #eputs "fixing norm"
    return fix_heat_flux_norm(GSL::Vector.alloc(narr.to_a), options)
  end
end

#kpar_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 688

def kpar_gsl_vector(options)

  Dir.chdir(@directory) do
    if agk? or (@s_hat_input||@shat).abs  < 1.0e-5
      dk = 1
      phi = list(:theta).values
    else
      kxe = gsl_vector('linked_kx_elements', options)
      dk = 1.0/kxe.size
    phi = gsl_vector_complex('phi_along_field_line', options)
    end
    case phi.size%2
    when 0
      kpar = GSL::Vector.indgen(phi.size-1, -((phi.size-3)/2))*dk
    when 1
      kpar = GSL::Vector.indgen(phi.size-1, -((phi.size-2)/2))*dk
    end
    #ep 'kpar', kpar, 'phi.size', phi.size

    #ep 'kpar.class', kpar.class
    return kpar

  end
end

#linked_kx_elements_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 595

def linked_kx_elements_gsl_vector(options)
  Dir.chdir(@directory) do
    return GSL::Vector.alloc([0]) if @grid_option == "single" or agk?
    if agk? or (@s_hat_input or @shat).abs < 1.0e-5
      #p 'op1', options
      options.convert_to_index(self, :ky, :kx)
      #p 'op2', options
      #eputs "No Magnetic Shear"

#         begin
#           options.convert_to_index(:kx)
#         rescue
#           raise "Must specify kx or kx_index if no magnetics shear"
#         end
# #         theta0 = (options[:theta0] || 0)
# #         theta0 += jump(options) if @g_exb

      #theta0 = (options[:kx_index])
      #if @g_exb and @g_exb.abs > 0.0
        #theta0 += jump(options)
        #theta0 = theta0%((list(:kx).size-1)/2) if list(:kx).size > 1
      #end

      return GSL::Vector.alloc([options[:kx_index] - 1])
    end

    options.convert_to_index(self, :ky, :kx)
    nkx = netcdf_file.var('kx').dims[0].length
#       p nkx
    stride = @jtwist * (options[:ky_index] -1 )
    #stride = 3
    nlinks = [(nkx / stride).floor, 1].max
    theta0 = options[:kx_index] % @jtwist  #(options[:theta0] || 0)
    #log 'stride', stride, 'nlinks', nlinks, 'theta0', theta0
    #if @g_exb and @jtwist > 1 #and options[:t_index]
#         kx_shift = list(:ky)[options[:ky_index]]  * @g_exb
#         p list(:t)[options[:t_index]], options[:t_index], kx_shift

#         kx_shift *=  list(:t)[(options[:t_index] or list(:t).keys.max)]
#         jump = (kx_shift / list(:kx)[2]).round
      #theta0  += (@jtwist - jump(options) % @jtwist) % @jtwist

#         else
#           jump = 0
    #end
    #ep 'stride', stride, 'nlinks', nlinks, 'theta0', theta0
    #ep GSL::Vector.indgen(nlinks / 2,  nkx + theta0 - nlinks / 2 * stride, stride).connect(GSL::Vector.indgen(nlinks / 2, theta0, stride)).reverse if nlinks > 1
    #return [7,5,3,1,34].to_gslv
    return GSL::Vector.alloc([theta0 % jtwist]) if nlinks ==1
    return GSL::Vector.indgen(nlinks / 2,  nkx + theta0 - nlinks / 2 * stride, stride).connect(GSL::Vector.indgen(nlinks / 2, theta0, stride)).reverse

  end
end

#lpc_energy_gsl_vector(options) ⇒ Object

Velocity space diagnostics: fraction of dist func in higher energy harmonics

# File 'lib/gs2crmod/gsl_data.rb', line 883

def lpc_energy_gsl_vector(options)
  raise "Velocity space lpc diagnostics not found" unless FileTest.exist? "#@directory/#@run_name.lpc"
  lpc = GSL::Vector.filescan("#@directory/#@run_name.lpc")
  return lpc[2]
end

#lpc_pitch_angle_gsl_vector(options) ⇒ Object

Velocity space diagnostics: fraction of dist func in higher pitch angle harmonics

# File 'lib/gs2crmod/gsl_data.rb', line 875

def lpc_pitch_angle_gsl_vector(options)
  raise "Velocity space lpc diagnostics not found" unless FileTest.exist? "#@directory/#@run_name.lpc"
  lpc = GSL::Vector.filescan("#@directory/#@run_name.lpc")
  return lpc[1]
end

#mean_flow_velocity_over_x_gsl_vector(options) ⇒ Object

This function returns the mean flow velocity as a function of x (the radial coordinate). This is v_g_exb = (x - x(centre))*g_exb. The x-x(centre) ensures that the flow is zero at the middle of the box.

# File 'lib/gs2crmod/gsl_data.rb', line 1063

def mean_flow_velocity_over_x_gsl_vector(options)
  Dir.chdir(@directory) do
    raise CRFatal.new("Need to have g_exb > 0 to have a mean flow.") unless @g_exb
    x = gsl_vector(:x)

    vec_exb_vel = GSL::Vector.alloc(x.size)
    #Take imaginary part since i k_x will lead to imaginary part being real
    vec_exb_vel = (x - x[x.size/2])*@g_exb
    return vec_exb_vel
  end
end

#par_mom_flux_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 905

def par_mom_flux_over_time_gsl_vector(options)
Dir.chdir(@directory) do

  options.setup_time_window
  # This is a hack... one day some one will put it in the NetCDF file (haha).
  momlines = `grep parmom #@run_name.out`
  mom = []
  momlines.scan(Regexp.new("#{LongRegexen::FLOAT.to_s}$")) do
    mom.push $~[:float].to_f
  end
  options[:end_element] = (mom.size + options[:end_element]) if options[:end_element] < 0
#       p options
  return GSL::Vector.alloc(mom).subvector(options[:begin_element], options[:end_element] - options[:begin_element] + 1)
end
end

#perp_mom_flux_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 921

def perp_mom_flux_over_time_gsl_vector(options)

  Dir.chdir(@directory) do
    options.setup_time_window
    # This is a hack... one day some one will put it in the NetCDF file (haha).
    momlines = `grep perpmom #@run_name.out`
    mom = []
    momlines.scan(Regexp.new("#{LongRegexen::FLOAT.to_s}$")) do
      mom.push $~[:float].to_f
    end
    options[:end_element] = (mom.size + options[:end_element]) if options[:end_element] < 0
#       p options
    return GSL::Vector.alloc(mom).subvector(options[:begin_element], options[:end_element] - options[:begin_element] + 1)
  end
end

#phi0_by_kx_by_ky_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 587

def phi0_by_kx_by_ky_over_time_gsl_vector(options)
  Dir.chdir(@directory) do
    options.convert_to_index(self, :kx, :ky)
    phi0_array = netcdf_file.var('phi0').get.to_a.map{|arr| arr[options[:kx_index] - 1][options[:ky_index] - 1][options[:ri]]}
    return GSL::Vector.alloc(phi0_array)
  end
end

#phi2_by_kx_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 481

def phi2_by_kx_over_time_gsl_vector(options)
  options[:direction] = :kx
  phi2_by_kxy_over_time_gsl_vector(options)
end

#phi2_by_ky_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 486

def phi2_by_ky_over_time_gsl_vector(options)
  options[:direction] = :ky
  phi2_by_kxy_over_time_gsl_vector(options)
end

#phi2_by_mode_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 515

def phi2_by_mode_over_time_gsl_vector(options)
  Dir.chdir(@directory) do      #Necessary options: :ky and :kx
    #Optional options: :t_index_window
    #     eputs "got here"
    #options[:begin_element], options[:end_element] = (options[:t_index_window] ? options[:t_index_window].map{|ind| ind -1} : [0, -1])
    options.setup_time_window
    phi_t_array=nil
    if @grid_option == "single"
      phi_t_array = netcdf_file.var('phi2').get('start' => [options[:begin_element]], 'end' => [options[:end_element]]).to_a.flatten
    else
#         value = options[:ky]
#         eputs value
#         get_list_of(:ky)
#         index = @ky_list.find{|index,val| (val-value).abs < Float::EPSILON}[0]
      options.convert_to_index(self, :kx, :ky)
#         p options
      phi_t_array = netcdf_file.var("phi2_by_mode").get('start' => [options[:kx_index] - 1, options[:ky_index] - 1, options[:begin_element]], 'end' => [options[:kx_index] - 1, options[:ky_index] - 1, options[:end_element]]).to_a.flatten
#         eputs 'phi_t_array.size', phi_t_array.size
    end
    return GSL::Vector.alloc(phi_t_array)

  end
end

#phi2tot_over_time_gsl_vector(options) ⇒ Object

The square of the potential summed over all wave numbers, indexed by time, normalised to (e/T)(rho_1/a).

# File 'lib/gs2crmod/gsl_data.rb', line 211

def phi2tot_over_time_gsl_vector(options)

  Dir.chdir(@directory) do      #Necessary options: ky
    #log 'about to open netcdf file'
    #options.setup_time_window
    phis = netcdf_file.var('phi2').get('start'=>[options[:begin_element]], 'end'=>[options[:end_element]] ).to_a
    log 'about to allocate gsl vector'
    vec = GSL::Vector.alloc(phis)
    log 'finished'
    return fix_norm(vec, 1, options)
  end
end

#phi_along_field_line_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 713

def phi_along_field_line_gsl_vector(options)
  Dir.chdir(@directory) do
    complex_phi_vector= gsl_vector_complex('phi_along_field_line', options)
    case options[:imrc]
    when :im
      phi_vector = complex_phi_vector.imag
    when :mag
      _mag = true
      phi_vector = complex_phi_vector.abs2
    when :corr
      thetas = gsl_vector('theta_along_field_line', options)
      min = thetas.abs.to_a.index(thetas.abs.min)
      at_0 = complex_phi_vector[min]
#         ep at_0.class
      phi_vector = (complex_phi_vector * (at_0 / at_0.mag).conj).real
#         gsl_complex('correcting_phase', options)).real
    when :real
      phi_vector = complex_phi_vector.real
    else
      raise CRError.new("options[:imrc] was: #{options[:irmc]}")
    end
    phi_vector *= -1.0 if options[:flip]
    (phi_vector /= phi_vector.abs.max; phi_vector *= (options[:height] || 1.0)) if options[:norm]
    phi_vector = phi_vector.reverse if options[:rev]
    return phi_vector

  end
end

#phi_for_eab_movie_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 802

def phi_for_eab_movie_gsl_vector(options)
  Dir.chdir(@directory) do      #options required are x_index, y_index and tm_index (Time)
    mvf_name = @run_name + '.movie.nc'
    raise CRError.new("cannot find file #{mvf_name}") unless FileTest.exist? mvf_name
    ncf = NumRu::NetCDF.open(mvf_name)
#       p ncf.var('phi_by_xmode').get.to_a[0][0][0]
    return GSL::Vector.alloc(ncf.var('phi_by_xmode').get.to_a[options[:tm_index] - 1].map{|xy_arr| xy_arr[options[:x_index] - 1][options[:y_index] - 1]})

  end
end

#scan_parameter_value_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 937

def scan_parameter_value_gsl_vector(options)
  return GSL::Vector.alloc(netcdf_file.var('scan_parameter_value').get.to_a)
end

#spectrum_over_kpar_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 649

def spectrum_over_kpar_gsl_vector(options)
  Dir.chdir(@directory) do
 # , /kpar_spectrum/
    #ep 'zero?', (@s_hat_input||@shat)==0.0
    unless agk? or (@s_hat_input||@shat||0.0).abs<1.0e-5
      phi = gsl_vector_complex('phi_along_field_line', options)
      phi = phi.subvector(0,phi.size-1)
      #i = 0
      #phi = phi.collect{|re,im|
        #i+=1; GSL::Complex.alloc(Math.sin(0.1*i), Math.cos(0.1*i))+
        #GSL::Complex.alloc(Math.sin(0.4*i), Math.cos(0.4*i))

      #}
      ##GraphKit.quick_create([phi.square]).gnuplot
      phi_k = phi.forward
      phi_kr = phi_k.square
      case phi_kr.size%2
      when 0
        spec = phi_kr.subvector((phi_kr.size+2)/2, (phi_kr.size-2)/2).connect(phi_kr.subvector(0, (phi_kr.size+2)/2))
      when 1
        spec = phi_kr.subvector((phi_kr.size + 1)/2, (phi_kr.size-1)/2).connect(phi_kr.subvector(0, (phi_kr.size+1)/2))
      end
      ##spec = phi_kr
      #ep 'spec.class', spec.class
      return spec
    else

      gm = gsl_matrix('spectrum_over_ky_over_kpar', options)
      vec = GSL::Vector.alloc(gm.shape[1])
      vec.set_all(0.0)
      for ky_element in 0...gm.shape[0]
        vec+= gm.row(ky_element)
      end
      vec = vec/gm.shape[0]
      return vec
    end
  end
end

#spectrum_over_kx_avg_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 946

def spectrum_over_kx_avg_gsl_vector(options)
  options[:direction] = :kx
  spectrum_over_kxy_avg_gsl_vector(options)
end

#spectrum_over_kx_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 941

def spectrum_over_kx_gsl_vector(options)
  options[:direction] = :kx
  spectrum_over_kxy_gsl_vector(options)
end

#spectrum_over_kxy_avg_gsl_vector(options) ⇒ Object

spectrum averaged in time

# File 'lib/gs2crmod/gsl_data.rb', line 982

def spectrum_over_kxy_avg_gsl_vector(options)
  Dir.chdir(@directory) do
    # i.e. spectrum_over_ky or spectrum_over_kx
    kxy = options[:direction]
    raise "Spectrum makes no sense for single modes" if @grid_option == "single"

    phi_array = netcdf_file.var("phi2_by_#{kxy}").get('start' => [0, 0], 'end' => [-1, -1]) #index = [kx or ky, t]

    shape = phi_array.shape
    phi_av = [];
    #average over time for each kx or ky individually
    for i in 0...shape[0]
      phi_av[i] = phi_array[i,0..-1].sum / shape[1]
    end

    v = GSL::Vector.alloc(phi_av)
    v = v.from_box_order if kxy == :kx
    v = v.mul(gsl_vector(kxy).square) unless options[:phi2_only]
    return v
  end
end

#spectrum_over_kxy_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 961

def spectrum_over_kxy_gsl_vector(options)
  Dir.chdir(@directory) do
    # i.e. spectrum_over_ky or spectrum_over_kx
    kxy = options[:direction]
#       eputs options[:t_index]
    raise "Spectrum makes no sense for single modes" if @grid_option == "single"

    options.convert_to_index(:t) if options[:t] or options[:t_element]
#       eputs options[:t_index]

    options[:t_index] ||= list(:t).keys.max
#       eputs options[:t_index]
    phi_array = netcdf_file.var("phi2_by_#{kxy}").get('start' => [0, options[:t_index] - 1], 'end' => [-1, options[:t_index] - 1]).to_a.flatten
    v = GSL::Vector.alloc(phi_array)
    v = v.from_box_order if kxy == :kx
    v = v.mul(gsl_vector(kxy).square) unless options[:phi2_only]
    return v
  end
end

#spectrum_over_ky_avg_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 956

def spectrum_over_ky_avg_gsl_vector(options)
  options[:direction] = :ky
  spectrum_over_kxy_avg_gsl_vector(options)
end

#spectrum_over_ky_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 951

def spectrum_over_ky_gsl_vector(options)
  options[:direction] = :ky
  spectrum_over_kxy_gsl_vector(options)
end

#theta_along_field_line_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 742

def theta_along_field_line_gsl_vector(options)
  Dir.chdir(@directory) do
    case @grid_option
    when "single", "range"
      theta_vector = gsl_vector(:theta)
    when "box"
      #eputs "Start theta_along_field_line"

      kx_elements = gsl_vector('linked_kx_elements', options).to_a
#         ep list(:kx).keys.max
#         ep kx_elements[0], list(:kx)[(kx_elements[0] + 1).to_i]
#         ep kx_elements[-1], list(:kx)[(kx_elements[-1] + 1).to_i]
      thetas = gsl_vector(:theta)
#         ep thetas
      #eputs "End theta_along_field_line"
      return thetas if agk? or (@s_hat_input or @shat).abs < 1.0e-5
      if gryfx?
        theta_list = ((1..kx_elements.size).to_a.map do |i|
          thetas * i
        end)
        thetas = theta_list.inject{|o,n| o.connect(n)}
        thetas -= Math::PI*(kx_elements.size-1)
        return thetas

      end
      theta_list = (kx_elements.map do |element|

        kx = list(:kx)[(element + 1).to_i]
#                      ep element
                   #ep 'kx', kx, 'shat', (@s_hat_input or @shat), 'ky',   list(:ky)[options[:ky_index]]
        thetas - 1.0 / (@s_hat_input or @shat) / list(:ky)[options[:ky_index]] * kx
      end).inject{|old, new| old.connect(new)}
#         thetas = gsl_vector(:theta) - 1.0 / @shat / list(:ky)[options[:ky_index]] * list(:kx)[(kx_elements[0] + 1).to_i] #- Math::PI*(kx_elements.size  - 1)
#         get_list_of(:ky, :t)
#         if @g_exb #and options[:t_index]

        if options[:moving]
          theta_list = theta_list  -  Math::PI * 2.0 * (jump(options) / @jtwist)
        else
#             ep 'jump % jtwist is!!', jump(options) % @jtwist
          theta_list = theta_list - Math::PI * 2.0 / @nx.to_f * ((jump(options) % @jtwist).to_f / @jtwist.to_f)
        end
#           jump = 0
#         end
#         theta_list = thetas.dup #gsl_vector(:theta) - Math::PI*kx_elements.size
#         (kx_elements.size - 1).times do
#           thetas = thetas + Math::PI * 2.0
#           theta_list = theta_list.connect(thetas)
#         end
#         pp theta_list.to_a.values_at(0, theta_list.size - 1)
#         pp theta_list.to_a.max
      theta_vector = theta_list
    end
#       theta_vector = theta_vector.reverse if options[:rev]
    theta_vector *= (@shat) if options[:z]
    return theta_vector

  end
end

#tpar2_by_mode_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 539

def tpar2_by_mode_over_time_gsl_vector(options)
  Dir.chdir(@directory) do      #Necessary options: :ky and :kx
    #Optional options: :t_index_window
    #     eputs "got here"
    #options[:begin_element], options[:end_element] = (options[:t_index_window] ? options[:t_index_window].map{|ind| ind -1} : [0, -1])
    options.setup_time_window
    tpar_t_array=nil
    if @grid_option == "single"
      tpar_t_array = netcdf_file.var('tpar2').get('start' => [options[:begin_element]], 'end' => [options[:end_element]]).to_a.flatten
    else
#         value = options[:ky]
#         eputs value
#         get_list_of(:ky)
#         index = @ky_list.find{|index,val| (val-value).abs < Float::EPSILON}[0]
      options.convert_to_index(self, :kx, :ky, :species)
#         p options
      tpar_t_array = netcdf_file.var("tpar2_by_mode").get('start' => [options[:kx_index] - 1, options[:ky_index] - 1, options[:species_index] - 1, options[:begin_element]], 'end' => [options[:kx_index] - 1, options[:ky_index] - 1, options[:species_index] - 1, options[:end_element]]).to_a.flatten
#         eputs 'tpar_t_array.size', tpar_t_array.size
    end
    return GSL::Vector.alloc(tpar_t_array)

  end
end

#tperp2_by_mode_over_time_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 563

def tperp2_by_mode_over_time_gsl_vector(options)
  Dir.chdir(@directory) do      #Necessary options: :ky and :kx
    #Optional options: :t_index_window
    #     eputs "got here"
    #options[:begin_element], options[:end_element] = (options[:t_index_window] ? options[:t_index_window].map{|ind| ind -1} : [0, -1])
    options.setup_time_window
    tperp_t_array=nil
    if @grid_option == "single"
      tperp_t_array = netcdf_file.var('tperp2').get('start' => [options[:begin_element]], 'end' => [options[:end_element]]).to_a.flatten
    else
#         value = options[:ky]
#         eputs value
#         get_list_of(:ky)
#         index = @ky_list.find{|index,val| (val-value).abs < Float::EPSILON}[0]
      options.convert_to_index(self, :kx, :ky, :species)
#         p options
      tperp_t_array = netcdf_file.var("tperp2_by_mode").get('start' => [options[:kx_index] - 1, options[:ky_index] - 1, options[:species_index] - 1, options[:begin_element]], 'end' => [options[:kx_index] - 1, options[:ky_index] - 1, options[:species_index] - 1, options[:end_element]]).to_a.flatten
#         eputs 'tperp_t_array.size', tperp_t_array.size
    end
    return GSL::Vector.alloc(tperp_t_array)

  end
end

#transient_amplification_over_kx_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 258

def transient_amplification_over_kx_gsl_vector(options)
  options[:direction] = :kx
  transient_amplification_over_kxy_gsl_vector(options)
end

#transient_amplification_over_ky_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 263

def transient_amplification_over_ky_gsl_vector(options)
  options[:direction] = :ky
  transient_amplification_over_kxy_gsl_vector(options)
end

#transient_es_heat_flux_amplification_over_kx_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 237

def transient_es_heat_flux_amplification_over_kx_gsl_vector(options)
  options[:direction] = :kx
  transient_es_heat_flux_amplification_over_kxy_gsl_vector(options)
end

#transient_es_heat_flux_amplification_over_kxy_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 247

def transient_es_heat_flux_amplification_over_kxy_gsl_vector(options)
  Dir.chdir(@directory) do      # i.e. phi2_by_ky_vs_time or phi2_by_kx_vs_time
    kxy = options[:direction].to_sym

#       ep :growth_rate_at_ + kxy
    p send(:transient_es_heat_flux_amplification_at_species_at_ + kxy)
    return GSL::Vector.alloc(send(:transient_es_heat_flux_amplification_at_species_at_ + kxy)[options[:species_index]-1].values)

  end
end

#transient_es_heat_flux_amplification_over_ky_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 242

def transient_es_heat_flux_amplification_over_ky_gsl_vector(options)
  options[:direction] = :ky
  transient_es_heat_flux_amplification_over_kxy_gsl_vector(options)
end

#vres_energy_gsl_vector(options) ⇒ Object

Velocity space diagnostics: integral error due to energy resolution

# File 'lib/gs2crmod/gsl_data.rb', line 899

def vres_energy_gsl_vector(options)
  raise "Velocity space vres diagnostics not found" unless FileTest.exist? "#@directory/#@run_name.vres"
  vres = GSL::Vector.filescan("#@directory/#@run_name.vres")
  return vres[2]
end

#vres_pitch_angle_gsl_vector(options) ⇒ Object

Velocity space diagnostics: integral error due to pitch angle resolution

# File 'lib/gs2crmod/gsl_data.rb', line 891

def vres_pitch_angle_gsl_vector(options)
  raise "Velocity space vres diagnostics not found" unless FileTest.exist? "#@directory/#@run_name.vres"
  vres = GSL::Vector.filescan("#@directory/#@run_name.vres")
  return vres[1]
end

#x_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 1004

def x_gsl_vector(options)
  raise "options nakx and interpolate_x are incompatible" if options[:nakx] and options[:interpolate_x]
  kx = gsl_vector(:kx, options)
  lx = 2*Math::PI/kx.to_box_order[1]
  #ep 'lx', lx
  nx = options[:nakx]||kx.size
  GSL::Vector.indgen(nx, 0, lx/nx)
end

#y_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 1013

def y_gsl_vector(options)
  raise "options naky and interpolate_y are incompatible" if options[:naky] and options[:interpolate_y]
  ky = gsl_vector(:ky, options)
  ly = 2*Math::PI/ky[1]
  ny = options[:naky]||ky.size
  ysize = ny*2-2+ny%2
  GSL::Vector.indgen(ysize, 0, ly/ysize)
end

#zf_velocity_over_x_gsl_vector(options) ⇒ Object

This function returns the zonal flow velocity as a function of x (the radial coordinate). This is v_ZF = kxfac*IFT(i k_x phi_imag), where kxfac = (qinp/rhoc)*grho(rhoc).

# File 'lib/gs2crmod/gsl_data.rb', line 1030

def zf_velocity_over_x_gsl_vector(options)
  Dir.chdir(@directory) do
    raise CRFatal.new("Need either qinp or pk and epsl specified in order to calculate kxfac.
                      If using numerical equil use the option :kxfac to override calculation.") unless @qinp or (@pk and @eps) or options[:kxfac]

    kx = gsl_vector(:kx).to_box_order
    drhodpsi = gsl_vector('drhodpsi')

    phi = GSL::Vector.alloc(kx.size)
    for it in 0...gsl_vector(:t).size
      options[:t_index] = it
      phi += gsl_vector_complex('phi_zonal', options)
    end
    phi /= gsl_vector(:t).size

    if @qinp
      kxfac = (@qinp/@rhoc)/drhodpsi
    elsif @pk and @epsl
      kxfac = (@epsl/@pk)/drhodpsi
    elsif options[:kxfac]
      kxfac = options[:kxfac]
    end

    vec_zf_vel = GSL::Vector.alloc(kx.size)
    #Take imaginary part since i k_x will lead to imaginary part being real
    vec_zf_vel = 0.5*kxfac*(phi*kx).backward.imag
    return vec_zf_vel
  end
end

#zonal_spectrum_gsl_vector(options) ⇒ Object

# File 'lib/gs2crmod/gsl_data.rb', line 1075

def zonal_spectrum_gsl_vector(options)
  Dir.chdir(@directory) do
    gmzf = gsl_matrix('spectrum_over_ky_over_kx',options)
    veczf = GSL::Vector.alloc(gmzf.shape[1])
    gmzf.shape[1].times{|i| veczf[i] = gmzf[0,i]}
    return veczf
  end
end