diff options
Diffstat (limited to 'fdk-aac/libFDK/include/qmf_pcm.h')
| -rw-r--r-- | fdk-aac/libFDK/include/qmf_pcm.h | 218 |
1 files changed, 217 insertions, 1 deletions
diff --git a/fdk-aac/libFDK/include/qmf_pcm.h b/fdk-aac/libFDK/include/qmf_pcm.h index f24e0cd..5da53db 100644 --- a/fdk-aac/libFDK/include/qmf_pcm.h +++ b/fdk-aac/libFDK/include/qmf_pcm.h @@ -1,7 +1,7 @@ /* ----------------------------------------------------------------------------- Software License for The Fraunhofer FDK AAC Codec Library for Android -© Copyright 1995 - 2018 Fraunhofer-Gesellschaft zur Förderung der angewandten +© Copyright 1995 - 2019 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V. All rights reserved. 1. INTRODUCTION @@ -402,4 +402,220 @@ void qmfSynthesisFiltering( timeOut + (i * L * stride), stride, pWorkBuffer); } /* no_col loop i */ } + +/*! + * + * \brief Create QMF filter bank instance + * + * + * \return 0 if successful + * + */ +int qmfInitAnalysisFilterBank( + HANDLE_QMF_FILTER_BANK h_Qmf, /*!< Returns handle */ + FIXP_QAS *pFilterStates, /*!< Handle to filter states */ + int noCols, /*!< Number of timeslots per frame */ + int lsb, /*!< lower end of QMF */ + int usb, /*!< upper end of QMF */ + int no_channels, /*!< Number of channels (bands) */ + int flags) /*!< Low Power flag */ +{ + int err = qmfInitFilterBank(h_Qmf, pFilterStates, noCols, lsb, usb, + no_channels, flags, 0); + if (!(flags & QMF_FLAG_KEEP_STATES) && (h_Qmf->FilterStates != NULL)) { + FDKmemclear(h_Qmf->FilterStates, + (2 * QMF_NO_POLY - 1) * h_Qmf->no_channels * sizeof(FIXP_QAS)); + } + + FDK_ASSERT(h_Qmf->no_channels >= h_Qmf->lsb); + + return err; +} + +#ifndef FUNCTION_qmfAnaPrototypeFirSlot +/*! + \brief Perform Analysis Prototype Filtering on a single slot of input data. +*/ +static void qmfAnaPrototypeFirSlot( + FIXP_DBL *analysisBuffer, + INT no_channels, /*!< Number channels of analysis filter */ + const FIXP_PFT *p_filter, INT p_stride, /*!< Stride of analysis filter */ + FIXP_QAS *RESTRICT pFilterStates) { + INT k; + + FIXP_DBL accu; + const FIXP_PFT *RESTRICT p_flt = p_filter; + FIXP_DBL *RESTRICT pData_0 = analysisBuffer + 2 * no_channels - 1; + FIXP_DBL *RESTRICT pData_1 = analysisBuffer; + + FIXP_QAS *RESTRICT sta_0 = (FIXP_QAS *)pFilterStates; + FIXP_QAS *RESTRICT sta_1 = + (FIXP_QAS *)pFilterStates + (2 * QMF_NO_POLY * no_channels) - 1; + INT pfltStep = QMF_NO_POLY * (p_stride); + INT staStep1 = no_channels << 1; + INT staStep2 = (no_channels << 3) - 1; /* Rewind one less */ + + /* FIR filters 127..64 0..63 */ + for (k = 0; k < no_channels; k++) { + accu = fMultDiv2(p_flt[0], *sta_1); + sta_1 -= staStep1; + accu += fMultDiv2(p_flt[1], *sta_1); + sta_1 -= staStep1; + accu += fMultDiv2(p_flt[2], *sta_1); + sta_1 -= staStep1; + accu += fMultDiv2(p_flt[3], *sta_1); + sta_1 -= staStep1; + accu += fMultDiv2(p_flt[4], *sta_1); + *pData_1++ = (accu << 1); + sta_1 += staStep2; + + p_flt += pfltStep; + accu = fMultDiv2(p_flt[0], *sta_0); + sta_0 += staStep1; + accu += fMultDiv2(p_flt[1], *sta_0); + sta_0 += staStep1; + accu += fMultDiv2(p_flt[2], *sta_0); + sta_0 += staStep1; + accu += fMultDiv2(p_flt[3], *sta_0); + sta_0 += staStep1; + accu += fMultDiv2(p_flt[4], *sta_0); + *pData_0-- = (accu << 1); + sta_0 -= staStep2; + } +} +#endif /* !defined(FUNCTION_qmfAnaPrototypeFirSlot) */ + +#ifndef FUNCTION_qmfAnaPrototypeFirSlot_NonSymmetric +/*! + \brief Perform Analysis Prototype Filtering on a single slot of input data. +*/ +static void qmfAnaPrototypeFirSlot_NonSymmetric( + FIXP_DBL *analysisBuffer, + int no_channels, /*!< Number channels of analysis filter */ + const FIXP_PFT *p_filter, int p_stride, /*!< Stride of analysis filter */ + FIXP_QAS *RESTRICT pFilterStates) { + const FIXP_PFT *RESTRICT p_flt = p_filter; + int p, k; + + for (k = 0; k < 2 * no_channels; k++) { + FIXP_DBL accu = (FIXP_DBL)0; + + p_flt += QMF_NO_POLY * (p_stride - 1); + + /* + Perform FIR-Filter + */ + for (p = 0; p < QMF_NO_POLY; p++) { + accu += fMultDiv2(*p_flt++, pFilterStates[2 * no_channels * p]); + } + analysisBuffer[2 * no_channels - 1 - k] = (accu << 1); + pFilterStates++; + } +} +#endif /* FUNCTION_qmfAnaPrototypeFirSlot_NonSymmetric */ + +/* + * \brief Perform one QMF slot analysis of the time domain data of timeIn + * with specified stride and stores the real part of the subband + * samples in rSubband, and the imaginary part in iSubband + * + * Note: anaQmf->lsb can be greater than anaQmf->no_channels in case + * of implicit resampling (USAC with reduced 3/4 core frame length). + */ +void qmfAnalysisFilteringSlot( + HANDLE_QMF_FILTER_BANK anaQmf, /*!< Handle of Qmf Synthesis Bank */ + FIXP_DBL *qmfReal, /*!< Low and High band, real */ + FIXP_DBL *qmfImag, /*!< Low and High band, imag */ + const INT_PCM_QMFIN *RESTRICT timeIn, /*!< Pointer to input */ + const int stride, /*!< stride factor of input */ + FIXP_DBL *pWorkBuffer /*!< pointer to temporal working buffer */ +) { + int offset = anaQmf->no_channels * (QMF_NO_POLY * 2 - 1); + /* + Feed time signal into oldest anaQmf->no_channels states + */ + { + FIXP_QAS *FilterStatesAnaTmp = ((FIXP_QAS *)anaQmf->FilterStates) + offset; + + /* Feed and scale actual time in slot */ + for (int i = anaQmf->no_channels >> 1; i != 0; i--) { + /* Place INT_PCM value left aligned in scaledTimeIn */ + *FilterStatesAnaTmp++ = (FIXP_QAS)*timeIn; + timeIn += stride; + *FilterStatesAnaTmp++ = (FIXP_QAS)*timeIn; + timeIn += stride; + } + } + + if (anaQmf->flags & QMF_FLAG_NONSYMMETRIC) { + qmfAnaPrototypeFirSlot_NonSymmetric(pWorkBuffer, anaQmf->no_channels, + anaQmf->p_filter, anaQmf->p_stride, + (FIXP_QAS *)anaQmf->FilterStates); + } else { + qmfAnaPrototypeFirSlot(pWorkBuffer, anaQmf->no_channels, anaQmf->p_filter, + anaQmf->p_stride, (FIXP_QAS *)anaQmf->FilterStates); + } + + if (anaQmf->flags & QMF_FLAG_LP) { + if (anaQmf->flags & QMF_FLAG_CLDFB) + qmfForwardModulationLP_odd(anaQmf, pWorkBuffer, qmfReal); + else + qmfForwardModulationLP_even(anaQmf, pWorkBuffer, qmfReal); + + } else { + qmfForwardModulationHQ(anaQmf, pWorkBuffer, qmfReal, qmfImag); + } + /* + Shift filter states + + Should be realized with modulo addressing on a DSP instead of a true buffer + shift + */ + FDKmemmove(anaQmf->FilterStates, + (FIXP_QAS *)anaQmf->FilterStates + anaQmf->no_channels, + offset * sizeof(FIXP_QAS)); +} + +/*! + * + * \brief Perform complex-valued subband filtering of the time domain + * data of timeIn and stores the real part of the subband + * samples in rAnalysis, and the imaginary part in iAnalysis + * The qmf coefficient table is symmetric. The symmetry is expoited by + * shrinking the coefficient table to half the size. The addressing mode + * takes care of the symmetries. + * + * + * \sa PolyphaseFiltering + */ +void qmfAnalysisFiltering( + HANDLE_QMF_FILTER_BANK anaQmf, /*!< Handle of Qmf Analysis Bank */ + FIXP_DBL **qmfReal, /*!< Pointer to real subband slots */ + FIXP_DBL **qmfImag, /*!< Pointer to imag subband slots */ + QMF_SCALE_FACTOR *scaleFactor, + const INT_PCM_QMFIN *timeIn, /*!< Time signal */ + const int timeIn_e, const int stride, + FIXP_DBL *pWorkBuffer /*!< pointer to temporal working buffer */ +) { + int i; + int no_channels = anaQmf->no_channels; + + scaleFactor->lb_scale = + -ALGORITHMIC_SCALING_IN_ANALYSIS_FILTERBANK - timeIn_e; + scaleFactor->lb_scale -= anaQmf->filterScale; + + for (i = 0; i < anaQmf->no_col; i++) { + FIXP_DBL *qmfImagSlot = NULL; + + if (!(anaQmf->flags & QMF_FLAG_LP)) { + qmfImagSlot = qmfImag[i]; + } + + qmfAnalysisFilteringSlot(anaQmf, qmfReal[i], qmfImagSlot, timeIn, stride, + pWorkBuffer); + + timeIn += no_channels * stride; + + } /* no_col loop i */ +} #endif /* QMF_PCM_H */ |