-#if 0
-extern const uint16_t ac3_freqs[3];
-extern const uint16_t ac3_bitratetab[19];
-extern const int16_t ac3_window[256];
-extern const uint8_t sdecaytab[4];
-extern const uint8_t fdecaytab[4];
-extern const uint16_t sgaintab[4];
-extern const uint16_t dbkneetab[4];
-extern const uint16_t floortab[8];
-extern const uint16_t fgaintab[8];
-#endif
-
-void ac3_common_init(void);
-void ac3_parametric_bit_allocation(AC3BitAllocParameters *s, uint8_t *bap,
- int8_t *exp, int start, int end,
- int snroffset, int fgain, int is_lfe,
- int deltbae,int deltnseg,
- uint8_t *deltoffst, uint8_t *deltlen, uint8_t *deltba);
+/**
+ * @struct AC3HeaderInfo
+ * Coded AC-3 header values up to the lfeon element, plus derived values.
+ */
+typedef struct AC3HeaderInfo {
+ /** @name Coded elements
+ * @{
+ */
+ uint16_t sync_word;
+ uint16_t crc1;
+ uint8_t sr_code;
+ uint8_t bitstream_id;
+ uint8_t bitstream_mode;
+ uint8_t channel_mode;
+ uint8_t lfe_on;
+ uint8_t frame_type;
+ int substreamid; ///< substream identification
+ int center_mix_level; ///< Center mix level index
+ int surround_mix_level; ///< Surround mix level index
+ uint16_t channel_map;
+ int num_blocks; ///< number of audio blocks
+ /** @} */
+
+ /** @name Derived values
+ * @{
+ */
+ uint8_t sr_shift;
+ uint16_t sample_rate;
+ uint32_t bit_rate;
+ uint8_t channels;
+ uint16_t frame_size;
+ uint64_t channel_layout;
+ /** @} */
+} AC3HeaderInfo;
+
+typedef enum {
+ EAC3_FRAME_TYPE_INDEPENDENT = 0,
+ EAC3_FRAME_TYPE_DEPENDENT,
+ EAC3_FRAME_TYPE_AC3_CONVERT,
+ EAC3_FRAME_TYPE_RESERVED
+} EAC3FrameType;
+
+void ff_ac3_common_init(void);
+
+/**
+ * Calculate the log power-spectral density of the input signal.
+ * This gives a rough estimate of signal power in the frequency domain by using
+ * the spectral envelope (exponents). The psd is also separately grouped
+ * into critical bands for use in the calculating the masking curve.
+ * 128 units in psd = -6 dB. The dbknee parameter in AC3BitAllocParameters
+ * determines the reference level.
+ *
+ * @param[in] exp frequency coefficient exponents
+ * @param[in] start starting bin location
+ * @param[in] end ending bin location
+ * @param[out] psd signal power for each frequency bin
+ * @param[out] band_psd signal power for each critical band
+ */
+void ff_ac3_bit_alloc_calc_psd(int8_t *exp, int start, int end, int16_t *psd,
+ int16_t *band_psd);
+
+/**
+ * Calculate the masking curve.
+ * First, the excitation is calculated using parameters in s and the signal
+ * power in each critical band. The excitation is compared with a predefined
+ * hearing threshold table to produce the masking curve. If delta bit
+ * allocation information is provided, it is used for adjusting the masking
+ * curve, usually to give a closer match to a better psychoacoustic model.
+ *
+ * @param[in] s adjustable bit allocation parameters
+ * @param[in] band_psd signal power for each critical band
+ * @param[in] start starting bin location
+ * @param[in] end ending bin location
+ * @param[in] fast_gain fast gain (estimated signal-to-mask ratio)
+ * @param[in] is_lfe whether or not the channel being processed is the LFE
+ * @param[in] dba_mode delta bit allocation mode (none, reuse, or new)
+ * @param[in] dba_nsegs number of delta segments
+ * @param[in] dba_offsets location offsets for each segment
+ * @param[in] dba_lengths length of each segment
+ * @param[in] dba_values delta bit allocation for each segment
+ * @param[out] mask calculated masking curve
+ * @return returns 0 for success, non-zero for error
+ */
+int ff_ac3_bit_alloc_calc_mask(AC3BitAllocParameters *s, int16_t *band_psd,
+ int start, int end, int fast_gain, int is_lfe,
+ int dba_mode, int dba_nsegs, uint8_t *dba_offsets,
+ uint8_t *dba_lengths, uint8_t *dba_values,
+ int16_t *mask);
+
+#endif /* AVCODEC_AC3_H */