Exemplos de LOG10F em C++ (Cpp)

Linguagem de programação: C++ (Cpp)

Método / Função: LOG10F

Exemplos em hotexamples.com: 2

LOG10F em C++ (Cpp) - 2 exemplos encontrados. Esses são os exemplos do mundo real mais bem avaliados de LOG10F em C++ (Cpp) extraídos de projetos de código aberto. Você pode avaliar os exemplos para nos ajudar a melhorar a qualidade deles.

Exemplo n.º 1

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Arquivo: Tables.cpp Projeto: fivearrows/scummvm

Tables::Tables() { int lf; for (lf = 0; lf <= 100; lf++) { // CONFIRMED:KG: This matches a ROM table found by Mok float fVal = (2.0f - LOG10F((float)lf + 1.0f)) * 128.0f; int val = (int)(fVal + 1.0); if (val > 255) { val = 255; } levelToAmpSubtraction[lf] = (Bit8u)val; } envLogarithmicTime[0] = 64; for (lf = 1; lf <= 255; lf++) { // CONFIRMED:KG: This matches a ROM table found by Mok envLogarithmicTime[lf] = (Bit8u)ceil(64.0f + LOG2F((float)lf) * 8.0f); } #ifdef EMULATE_LAPC_I // Dummy #ifdef - we'll have runtime emulation mode selection in future. // CONFIRMED: Based on a table found by Mok in the LAPC-I control ROM // Note that this matches the MT-32 table, but with the values clamped to a maximum of 8. memset(masterVolToAmpSubtraction, 8, 71); memset(masterVolToAmpSubtraction + 71, 7, 3); memset(masterVolToAmpSubtraction + 74, 6, 4); memset(masterVolToAmpSubtraction + 78, 5, 3); memset(masterVolToAmpSubtraction + 81, 4, 4); memset(masterVolToAmpSubtraction + 85, 3, 3); memset(masterVolToAmpSubtraction + 88, 2, 4); memset(masterVolToAmpSubtraction + 92, 1, 4); memset(masterVolToAmpSubtraction + 96, 0, 5); #else // CONFIRMED: Based on a table found by Mok in the MT-32 control ROM masterVolToAmpSubtraction[0] = 255; for (int masterVol = 1; masterVol <= 100; masterVol++) { masterVolToAmpSubtraction[masterVol] = (int)(106.31 - 16.0f * LOG2F((float)masterVol)); } #endif for (int i = 0; i <= 100; i++) { pulseWidth100To255[i] = (int)(i * 255 / 100.0f + 0.5f); //synth->printDebug("%d: %d", i, pulseWidth100To255[i]); } // The LA32 chip presumably has such a table inside as the internal computaions seem to be performed using fixed point math with 12-bit fractions for (int i = 0; i < 4096; i++) { exp2[i] = EXP2F(i / 4096.0f); } // found from sample analysis resAmpFadeFactor[7] = 1.0f / 8.0f; resAmpFadeFactor[6] = 2.0f / 8.0f; resAmpFadeFactor[5] = 3.0f / 8.0f; resAmpFadeFactor[4] = 5.0f / 8.0f; resAmpFadeFactor[3] = 8.0f / 8.0f; resAmpFadeFactor[2] = 12.0f / 8.0f; resAmpFadeFactor[1] = 16.0f / 8.0f; resAmpFadeFactor[0] = 31.0f / 8.0f; for (int i = 0; i < 5120; i++) { sinf10[i] = sin(FLOAT_PI * i / 2048.0f); } }

Exemplo n.º 2

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Arquivo: Tables.cpp Projeto: AReim1982/scummvm

Tables::Tables() { for (int lf = 0; lf <= 100; lf++) { // CONFIRMED:KG: This matches a ROM table found by Mok float fVal = (2.0f - LOG10F(float(lf) + 1.0f)) * 128.0f; int val = int(fVal + 1.0); if (val > 255) { val = 255; } levelToAmpSubtraction[lf] = Bit8u(val); } envLogarithmicTime[0] = 64; for (int lf = 1; lf <= 255; lf++) { // CONFIRMED:KG: This matches a ROM table found by Mok envLogarithmicTime[lf] = Bit8u(ceil(64.0f + LOG2F(float(lf)) * 8.0f)); } #if 0 // The table below is to be used in conjunction with emulation of VCA of newer generation units which is currently missing. // These relatively small values are rather intended to fine-tune the overall amplification of the VCA. // CONFIRMED: Based on a table found by Mok in the LAPC-I control ROM // Note that this matches the MT-32 table, but with the values clamped to a maximum of 8. memset(masterVolToAmpSubtraction, 8, 71); memset(masterVolToAmpSubtraction + 71, 7, 3); memset(masterVolToAmpSubtraction + 74, 6, 4); memset(masterVolToAmpSubtraction + 78, 5, 3); memset(masterVolToAmpSubtraction + 81, 4, 4); memset(masterVolToAmpSubtraction + 85, 3, 3); memset(masterVolToAmpSubtraction + 88, 2, 4); memset(masterVolToAmpSubtraction + 92, 1, 4); memset(masterVolToAmpSubtraction + 96, 0, 5); #else // CONFIRMED: Based on a table found by Mok in the MT-32 control ROM masterVolToAmpSubtraction[0] = 255; for (int masterVol = 1; masterVol <= 100; masterVol++) { masterVolToAmpSubtraction[masterVol] = Bit8u(106.31 - 16.0f * LOG2F(float(masterVol))); } #endif for (int i = 0; i <= 100; i++) { pulseWidth100To255[i] = Bit8u(i * 255 / 100.0f + 0.5f); //synth->printDebug("%d: %d", i, pulseWidth100To255[i]); } // The LA32 chip contains an exponent table inside. The table contains 12-bit integer values. // The actual table size is 512 rows. The 9 higher bits of the fractional part of the argument are used as a lookup address. // To improve the precision of computations, the lower bits are supposed to be used for interpolation as the LA32 chip also // contains another 512-row table with inverted differences between the main table values. for (int i = 0; i < 512; i++) { exp9[i] = Bit16u(8191.5f - EXP2F(13.0f + ~i / 512.0f)); } // There is a logarithmic sine table inside the LA32 chip. The table contains 13-bit integer values. for (int i = 1; i < 512; i++) { logsin9[i] = Bit16u(0.5f - LOG2F(sin((i + 0.5f) / 1024.0f * FLOAT_PI)) * 1024.0f); } // The very first value is clamped to the maximum possible 13-bit integer logsin9[0] = 8191; // found from sample analysis static const Bit8u resAmpDecayFactorTable[] = {31, 16, 12, 8, 5, 3, 2, 1}; resAmpDecayFactor = resAmpDecayFactorTable; }