import rdtest import renderdoc as rd class GL_CBuffer_Zoo(rdtest.TestCase): demos_test_name = 'GL_CBuffer_Zoo' def check_capture(self): draw = self.find_draw("Draw") self.check(draw is not None) self.controller.SetFrameEvent(draw.eventId, False) pipe: rd.PipeState = self.controller.GetPipelineState() stage = rd.ShaderStage.Pixel cbuf: rd.BoundCBuffer = pipe.GetConstantBuffer(stage, 0, 0) var_check = rdtest.ConstantBufferChecker( self.controller.GetCBufferVariableContents(pipe.GetGraphicsPipelineObject(), pipe.GetShader(stage), pipe.GetShaderEntryPoint(stage), 0, cbuf.resourceId, cbuf.byteOffset, cbuf.byteSize)) # For more detailed reference for the below checks, see the commented definition of the cbuffer # in the shader source code in the demo itself # vec4 a; var_check.check('a').cols(4).rows(1).value([0.0, 1.0, 2.0, 3.0]) # vec3 b; var_check.check('b').cols(3).rows(1).value([4.0, 5.0, 6.0]) # vec2 c; vec2 d; var_check.check('c').cols(2).rows(1).value([8.0, 9.0]) var_check.check('d').cols(2).rows(1).value([10.0, 11.0]) # float e; vec3 f; var_check.check('e').cols(1).rows(1).value([12.0]) var_check.check('f').cols(3).rows(1).value([16.0, 17.0, 18.0]) # vec4 dummy0; var_check.check('dummy0') # float j; vec2 k; var_check.check('j').cols(1).rows(1).value([24.0]) var_check.check('k').cols(2).rows(1).value([26.0, 27.0]) # vec2 l; float m; var_check.check('l').cols(2).rows(1).value([28.0, 29.0]) var_check.check('m').cols(1).rows(1).value([30.0]) # float n[4]; var_check.check('n').cols(0).rows(0).arraySize(4).members({ 0: lambda x: x.cols(1).rows(1).value([32.0]), 1: lambda x: x.cols(1).rows(1).value([36.0]), 2: lambda x: x.cols(1).rows(1).value([40.0]), 3: lambda x: x.cols(1).rows(1).value([44.0]), }) # vec4 dummy1; var_check.check('dummy1') # float o[4]; var_check.check('o').cols(0).rows(0).arraySize(4).members({ 0: lambda x: x.cols(1).rows(1).value([52.0]), 1: lambda x: x.cols(1).rows(1).value([56.0]), 2: lambda x: x.cols(1).rows(1).value([60.0]), 3: lambda x: x.cols(1).rows(1).value([64.0]), }) # float p; var_check.check('p').cols(1).rows(1).value([68.0]) # vec4 dummy2; var_check.check('dummy2') # column_major vec4x4 q; var_check.check('q').cols(4).rows(4).column_major().value([76.0, 80.0, 84.0, 88.0, 77.0, 81.0, 85.0, 89.0, 78.0, 82.0, 86.0, 90.0, 79.0, 83.0, 87.0, 91.0]) # row_major vec4x4 r; var_check.check('r').cols(4).rows(4).row_major().value([92.0, 93.0, 94.0, 95.0, 96.0, 97.0, 98.0, 99.0, 100.0, 101.0, 102.0, 103.0]) # column_major vec4x3 s; var_check.check('s').cols(4).rows(3).column_major().value([108.0, 112.0, 116.0, 120.0, 109.0, 113.0, 117.0, 121.0, 110.0, 114.0, 118.0, 122.0]) # vec4 dummy3; var_check.check('dummy3') # row_major vec4x3 t; var_check.check('t').cols(4).rows(3).row_major().value([128.0, 129.0, 130.0, 131.0, 132.0, 133.0, 134.0, 135.0, 136.0, 137.0, 138.0, 139.0]) # vec4 dummy4; var_check.check('dummy4') # column_major vec2x3 u; var_check.check('u').cols(3).rows(2).column_major().value([144.0, 148.0, 152.0, 145.0, 149.0, 153.0]) # vec4 dummy5; var_check.check('dummy5') # row_major vec3x2 v; var_check.check('v').cols(3).rows(2).row_major().value([160.0, 161.0, 162.0, 164.0, 165.0, 166.0]) # vec4 dummy6; var_check.check('dummy6') # column_major vec3x2 w; var_check.check('w').cols(2).rows(2).column_major().value([172.0, 176.0, 173.0, 177.0]) # vec4 dummy7; var_check.check('dummy7') # row_major vec3x2 x; var_check.check('x').cols(2).rows(2).row_major().value([184.0, 185.0, 188.0, 189.0]) # vec4 dummy8; var_check.check('dummy8') # row_major vec2x2 y; var_check.check('y').cols(2).rows(2).row_major().value([196.0, 197.0, 200.0, 201.0]) # float z; var_check.check('z').cols(1).rows(1).value([204.0]) # vec4 dummy9; var_check.check('dummy9') # vec4 multiarray[3][2]; var_check.check('multiarray').cols(0).rows(0).arraySize(3).members({ 0: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value([228.0, 229.0, 230.0, 231.0]), 1: lambda y: y.cols(4).rows(1).value([232.0, 233.0, 234.0, 235.0]), }), 1: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value([236.0, 237.0, 238.0, 239.0]), 1: lambda y: y.cols(4).rows(1).value([240.0, 241.0, 242.0, 243.0]), }), 2: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value([244.0, 245.0, 246.0, 247.0]), 1: lambda y: y.cols(4).rows(1).value([248.0, 249.0, 250.0, 251.0]), }), }) # struct vec3_1 { vec3 a; float b; }; # struct nested { vec3_1 a; vec4 b[4]; vec3_1 c[4]; }; # nested structa[2]; var_check.check('structa').cols(0).rows(0).arraySize(2).members({ # structa[0] 0: lambda s: s.cols(0).rows(0).structSize(3).members({ 'a': lambda x: x.cols(0).rows(0).structSize(2).members({ 'a': lambda y: y.cols(3).rows(1).value([252.0, 253.0, 254.0]), 'b': lambda y: y.cols(1).rows(1).value([255.0]), }), 'b': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(4).rows(1).value([256.0, 257.0, 258.0, 259.0]), 1: lambda y: y.cols(4).rows(1).value([260.0, 261.0, 262.0, 263.0]), 2: lambda y: y.cols(4).rows(1).value([264.0, 265.0, 266.0, 267.0]), 3: lambda y: y.cols(4).rows(1).value([268.0, 269.0, 270.0, 271.0]), }), 'c': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([272.0, 273.0, 274.0]), 'b': lambda z: z.cols(1).rows(1).value([275.0]), }), 1: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([276.0, 277.0, 278.0]), 'b': lambda z: z.cols(1).rows(1).value([279.0]), }), 2: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([280.0, 281.0, 282.0]), 'b': lambda z: z.cols(1).rows(1).value([283.0]), }), 3: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([284.0, 285.0, 286.0]), 'b': lambda z: z.cols(1).rows(1).value([287.0]), }), }), }), # structa[1] 1: lambda s: s.cols(0).rows(0).structSize(3).members({ 'a': lambda x: x.cols(0).rows(0).structSize(2).members({ 'a': lambda y: y.cols(3).rows(1).value([288.0, 289.0, 290.0]), 'b': lambda y: y.cols(1).rows(1).value([291.0]), }), 'b': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(4).rows(1).value([292.0, 293.0, 294.0, 295.0]), 1: lambda y: y.cols(4).rows(1).value([296.0, 297.0, 298.0, 299.0]), 2: lambda y: y.cols(4).rows(1).value([300.0, 301.0, 302.0, 303.0]), 3: lambda y: y.cols(4).rows(1).value([304.0, 305.0, 306.0, 307.0]), }), 'c': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([308.0, 309.0, 310.0]), 'b': lambda z: z.cols(1).rows(1).value([311.0]), }), 1: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([312.0, 313.0, 314.0]), 'b': lambda z: z.cols(1).rows(1).value([315.0]), }), 2: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([316.0, 317.0, 318.0]), 'b': lambda z: z.cols(1).rows(1).value([319.0]), }), 3: lambda y: y.cols(0).rows(0).structSize(2).members({ 'a': lambda z: z.cols(3).rows(1).value([320.0, 321.0, 322.0]), 'b': lambda z: z.cols(1).rows(1).value([323.0]), }), }), }), }) # column_major mat2x3 ac; var_check.check('ac').cols(2).rows(3).column_major().value([324.0, 328.0, 325.0, 329.0, 326.0, 330.0]) # row_major mat2x3 ad; var_check.check('ad').cols(2).rows(3).row_major().value([332.0, 333.0, 336.0, 337.0, 340.0, 341.0]) # column_major mat2x3 ae[2]; var_check.check('ae').cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(2).rows(3).column_major().value([344.0, 348.0, 345.0, 349.0, 346.0, 350.0]), 1: lambda x: x.cols(2).rows(3).column_major().value([352.0, 356.0, 353.0, 357.0, 354.0, 358.0]), }) # row_major mat2x3 af[2]; var_check.check('af').cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(2).rows(3).row_major().value([360.0, 361.0, 364.0, 365.0, 368.0, 369.0]), 1: lambda x: x.cols(2).rows(3).row_major().value([372.0, 373.0, 376.0, 377.0, 380.0, 381.0]), }) # vec2 dummy10; var_check.check('dummy10') # row_major mat2x2 ag; var_check.check('ag').cols(2).rows(2).row_major().value([388.0, 389.0, 392.0, 393.0]) # vec2 dummy12; var_check.check('dummy11') # column_major float2x2 ah; var_check.check('ah').cols(2).rows(2).column_major().value([400.0, 404.0, 401.0, 405.0]) # row_major mat2x2 ai[2]; var_check.check('ai').rows(0).cols(0).arraySize(2).members({ 0: lambda x: x.cols(2).rows(2).row_major().value([408.0, 409.0, 412.0, 413.0]), 1: lambda x: x.cols(2).rows(2).row_major().value([416.0, 417.0, 420.0, 421.0]), }) # column_major mat2x2 aj[2]; var_check.check('aj').rows(0).cols(0).arraySize(2).members({ 0: lambda x: x.cols(2).rows(2).column_major().value([424.0, 428.0, 425.0, 429.0]), 1: lambda x: x.cols(2).rows(2).column_major().value([432.0, 436.0, 433.0, 437.0]), }) # struct nested_with_padding # { # float a; // vec3 padding # vec4 b; # float c; // vec3 padding # vec3 d[4]; // float padding after each one # }; # nested_with_padding ak[2]; var_check.check('ak').rows(0).cols(0).arraySize(2).members({ # ak[0] 0: lambda s: s.rows(0).cols(0).structSize(4).members({ 'a': lambda y: y.rows(1).cols(1).value([440.0]), 'b': lambda y: y.rows(1).cols(4).value([444.0, 445.0, 446.0, 447.0]), 'c': lambda y: y.rows(1).cols(1).value([448.0]), 'd': lambda x: x.rows(0).cols(0).arraySize(4).members({ 0: lambda z: z.rows(1).cols(3).value([452.0, 453.0, 454.0]), 1: lambda z: z.rows(1).cols(3).value([456.0, 457.0, 458.0]), 2: lambda z: z.rows(1).cols(3).value([460.0, 461.0, 462.0]), 3: lambda z: z.rows(1).cols(3).value([464.0, 465.0, 466.0]), }), }), # ak[1] 1: lambda s: s.rows(0).cols(0).structSize(4).members({ 'a': lambda y: y.rows(1).cols(1).value([468.0]), 'b': lambda y: y.rows(1).cols(4).value([472.0, 473.0, 474.0, 475.0]), 'c': lambda y: y.rows(1).cols(1).value([476.0]), 'd': lambda x: x.rows(0).cols(0).arraySize(4).members({ 0: lambda z: z.rows(1).cols(3).value([480.0, 481.0, 482.0]), 1: lambda z: z.rows(1).cols(3).value([484.0, 485.0, 486.0]), 2: lambda z: z.rows(1).cols(3).value([488.0, 489.0, 490.0]), 3: lambda z: z.rows(1).cols(3).value([492.0, 493.0, 494.0]), }), }), }) # float2 dummy12; var_check.check('dummy12') # float al; var_check.check('al').rows(1).cols(1).value([500.0]) # struct float2_struct # { # float x, y; # }; # float2_struct am; var_check.check('am').rows(0).cols(0).members({ 'x': lambda y: y.rows(1).cols(1).value([504.0]), 'y': lambda y: y.rows(1).cols(1).value([505.0]), }) # float an; var_check.check('an').rows(1).cols(1).value([508.0]) # float4 dummy13[2]; var_check.check('dummy13') # misaligned_struct ao[2]; var_check.check('ao').rows(0).cols(0).arraySize(2).members({ # ao[0] 0: lambda s: s.rows(0).cols(0).structSize(2).members({ 'a': lambda y: y.rows(1).cols(4).value([520.0, 521.0, 522.0, 523.0]), 'b': lambda y: y.rows(1).cols(2).value([524.0, 525.0]), }), 1: lambda s: s.rows(0).cols(0).structSize(2).members({ 'a': lambda y: y.rows(1).cols(4).value([528.0, 529.0, 530.0, 531.0]), 'b': lambda y: y.rows(1).cols(2).value([532.0, 533.0]), }), }) # float4 test; var_check.check('test').rows(1).cols(4).value([536.0, 537.0, 538.0, 539.0]) # to save duplicating if this array changes, we calculate out from the start, as the array is tightly packed base = 540.0 exp_vals = lambda wi,yi,xi: [base + wi * 24.0 + yi * 8.0 + xi * 4.0 + c * 1.0 for c in range(0,4)] # vec4 multiarray2[4][3][2]; var_check.check('multiarray2').cols(0).rows(0).arraySize(4).members({ 0: lambda w: w.cols(0).rows(0).arraySize(3).members({ 0: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(0, 0, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(0, 0, 1)), }), 1: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(0, 1, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(0, 1, 1)), }), 2: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(0, 2, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(0, 2, 1)), }), }), 1: lambda w: w.cols(0).rows(0).arraySize(3).members({ 0: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(1, 0, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(1, 0, 1)), }), 1: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(1, 1, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(1, 1, 1)), }), 2: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(1, 2, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(1, 2, 1)), }), }), 2: lambda w: w.cols(0).rows(0).arraySize(3).members({ 0: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(2, 0, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(2, 0, 1)), }), 1: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(2, 1, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(2, 1, 1)), }), 2: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(2, 2, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(2, 2, 1)), }), }), 3: lambda w: w.cols(0).rows(0).arraySize(3).members({ 0: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(3, 0, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(3, 0, 1)), }), 1: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(3, 1, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(3, 1, 1)), }), 2: lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda y: y.cols(4).rows(1).value(exp_vals(3, 2, 0)), 1: lambda y: y.cols(4).rows(1).value(exp_vals(3, 2, 1)), }), }), }) var_check.done() rdtest.log.success("CBuffer variables are as expected") self.check_pixel_value(pipe.GetOutputTargets()[0].resourceId, 0.5, 0.5, [536.1, 537.0, 538.0, 539.0]) rdtest.log.success("Picked value is as expected") cbuf: rd.BoundCBuffer = pipe.GetConstantBuffer(stage, 1, 0) var_check = rdtest.ConstantBufferChecker( self.controller.GetCBufferVariableContents(pipe.GetGraphicsPipelineObject(), pipe.GetShader(stage), pipe.GetShaderEntryPoint(stage), 1, cbuf.resourceId, cbuf.byteOffset, cbuf.byteSize)) # For bare uniforms we have partial data - only values used in the shader need to get assigned locations and # some drivers are aggressive about stripping any others. Only uniforms with locations get upload values. # Hence some of these checks don't check for the value - that means they might not be present # vec4 A; var_check.check('A').cols(4).rows(1).value([10.0, 20.0, 30.0, 40.0]) # vec2 B; var_check.check('B').cols(2).rows(1).value([50.0, 60.0]) # vec3 C; var_check.check('C').cols(3).rows(1).value([70.0, 80.0, 90.0]) # mat2x3 D; var_check.check('D').cols(2).rows(3).value([100.0, 130.0, 110.0, 140.0, 120.0, 150.0]) # float E[3]; var_check.check('E').cols(0).rows(0).arraySize(3).members({ 0: lambda x: x.cols(1).rows(1).value([160.0]), 1: lambda x: x.cols(1).rows(1).value([170.0]), 2: lambda x: x.cols(1).rows(1).value([180.0]), }) # vec4 F[3][2][2]; # Multidimensional arrays are represented as structs with N members # Due to lacking reflection, we skip structSize() checks, but check everything else if it's present (if it's # not, it will be skipped) var_check.check('F').cols(0).rows(0).members({ '[0]': lambda x: x.cols(0).rows(0).members({ '[0]': lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(4).rows(1).value([190.0, 200.0, 210.0, 220.0]), 1: lambda x: x.cols(4).rows(1).value([230.0, 240.0, 250.0, 260.0]), }), '[1]': lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(4).rows(1).value([270.0, 280.0, 290.0, 300.0]), 1: lambda x: x.cols(4).rows(1).value([310.0, 320.0, 330.0, 340.0]), }), }), '[1]': lambda x: x.cols(0).rows(0).members({ '[0]': lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(4).rows(1).value([350.0, 360.0, 370.0, 380.0]), 1: lambda x: x.cols(4).rows(1).value([390.0, 400.0, 410.0, 420.0]), }), '[1]': lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(4).rows(1).value([430.0, 440.0, 450.0, 460.0]), 1: lambda x: x.cols(4).rows(1).value([470.0, 480.0, 490.0, 500.0]), }), }), '[2]': lambda x: x.cols(0).rows(0).members({ '[0]': lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(4).rows(1).value([510.0, 520.0, 530.0, 540.0]), 1: lambda x: x.cols(4).rows(1).value([550.0, 560.0, 570.0, 580.0]), }), '[1]': lambda x: x.cols(0).rows(0).arraySize(2).members({ 0: lambda x: x.cols(4).rows(1).value([590.0, 600.0, 610.0, 620.0]), 1: lambda x: x.cols(4).rows(1).value([630.0, 640.0, 650.0, 660.0]), }), }), }) # struct vec3_1 { vec3 a; float b; }; # struct nested { vec3_1 a; vec4 b[4]; vec3_1 c[4]; }; # nested G[2]; # Due to lacking reflection, we don't know that G[x].a.a exists, as we only reference G[n].a.b # Similarly we don't know that G[x].c[y].b exists var_check.check('G').cols(0).rows(0).arraySize(2).members({ # G[0] 0: lambda s: s.cols(0).rows(0).structSize(3).members({ 'a': lambda x: x.cols(0).rows(0).members({ 'a': lambda y: y.cols(3).rows(1).value([680.0, 690.0, 700.0]), 'b': lambda y: y.cols(1).rows(1).value([710.0]), }), 'b': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(4).rows(1), 1: lambda y: y.cols(4).rows(1), 2: lambda y: y.cols(4).rows(1), 3: lambda y: y.cols(4).rows(1), }), 'c': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), 1: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), 2: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), 3: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), }), }), # G[1] 1: lambda s: s.cols(0).rows(0).structSize(3).members({ 'a': lambda x: x.cols(0).rows(0).members({ 'a': lambda y: y.cols(3).rows(1).value([1040.0, 1050.0, 1060.0]), 'b': lambda y: y.cols(1).rows(1).value([1070.0]), }), 'b': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(4).rows(1).value([1080.0, 1090.0, 1100.0, 1110.0]), 1: lambda y: y.cols(4).rows(1).value([1120.0, 1130.0, 1140.0, 1150.0]), 2: lambda y: y.cols(4).rows(1).value([1160.0, 1170.0, 1180.0, 1190.0]), 3: lambda y: y.cols(4).rows(1).value([1200.0, 1210.0, 1220.0, 1230.0]), }), 'c': lambda x: x.cols(0).rows(0).arraySize(4).members({ 0: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), 1: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), 2: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1), 'b': lambda z: z.cols(1).rows(1), }), 3: lambda y: y.cols(0).rows(0).members({ 'a': lambda z: z.cols(3).rows(1).value([1360.0, 1370.0, 1380.0]), 'b': lambda z: z.cols(1).rows(1), }), }), }), }) var_check.done() rdtest.log.success("Bare uniform variables are as expected")