// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2019-2020 Pengutronix, Michael Tretter * * Helper functions to generate a raw byte sequence payload from values. */ #include #include #include #include #include #include #include #include "nal-rbsp.h" void rbsp_init(struct rbsp *rbsp, void *addr, size_t size, struct nal_rbsp_ops *ops) { if (!rbsp) return; rbsp->data = addr; rbsp->size = size; rbsp->pos = 0; rbsp->ops = ops; rbsp->error = 0; } void rbsp_unsupported(struct rbsp *rbsp) { rbsp->error = -EINVAL; } static int rbsp_read_bits(struct rbsp *rbsp, int n, unsigned int *value); static int rbsp_write_bits(struct rbsp *rbsp, int n, unsigned int value); /* * When reading or writing, the emulation_prevention_three_byte is detected * only when the 2 one bits need to be inserted. Therefore, we are not * actually adding the 0x3 byte, but the 2 one bits and the six 0 bits of the * next byte. */ #define EMULATION_PREVENTION_THREE_BYTE (0x3 << 6) static int add_emulation_prevention_three_byte(struct rbsp *rbsp) { rbsp->num_consecutive_zeros = 0; rbsp_write_bits(rbsp, 8, EMULATION_PREVENTION_THREE_BYTE); return 0; } static int discard_emulation_prevention_three_byte(struct rbsp *rbsp) { unsigned int tmp = 0; rbsp->num_consecutive_zeros = 0; rbsp_read_bits(rbsp, 8, &tmp); if (tmp != EMULATION_PREVENTION_THREE_BYTE) return -EINVAL; return 0; } static inline int rbsp_read_bit(struct rbsp *rbsp) { int shift; int ofs; int bit; int err; if (rbsp->num_consecutive_zeros == 22) { err = discard_emulation_prevention_three_byte(rbsp); if (err) return err; } shift = 7 - (rbsp->pos % 8); ofs = rbsp->pos / 8; if (ofs >= rbsp->size) return -EINVAL; bit = (rbsp->data[ofs] >> shift) & 1; rbsp->pos++; if (bit == 1 || (rbsp->num_consecutive_zeros < 7 && (rbsp->pos % 8 == 0))) rbsp->num_consecutive_zeros = 0; else rbsp->num_consecutive_zeros++; return bit; } static inline int rbsp_write_bit(struct rbsp *rbsp, bool value) { int shift; int ofs; if (rbsp->num_consecutive_zeros == 22) add_emulation_prevention_three_byte(rbsp); shift = 7 - (rbsp->pos % 8); ofs = rbsp->pos / 8; if (ofs >= rbsp->size) return -EINVAL; rbsp->data[ofs] &= ~(1 << shift); rbsp->data[ofs] |= value << shift; rbsp->pos++; if (value || (rbsp->num_consecutive_zeros < 7 && (rbsp->pos % 8 == 0))) { rbsp->num_consecutive_zeros = 0; } else { rbsp->num_consecutive_zeros++; } return 0; } static inline int rbsp_read_bits(struct rbsp *rbsp, int n, unsigned int *value) { int i; int bit; unsigned int tmp = 0; if (n > 8 * sizeof(*value)) return -EINVAL; for (i = n; i > 0; i--) { bit = rbsp_read_bit(rbsp); if (bit < 0) return bit; tmp |= bit << (i - 1); } if (value) *value = tmp; return 0; } static int rbsp_write_bits(struct rbsp *rbsp, int n, unsigned int value) { int ret; if (n > 8 * sizeof(value)) return -EINVAL; while (n--) { ret = rbsp_write_bit(rbsp, (value >> n) & 1); if (ret) return ret; } return 0; } static int rbsp_read_uev(struct rbsp *rbsp, unsigned int *value) { int leading_zero_bits = 0; unsigned int tmp = 0; int ret; while ((ret = rbsp_read_bit(rbsp)) == 0) leading_zero_bits++; if (ret < 0) return ret; if (leading_zero_bits > 0) { ret = rbsp_read_bits(rbsp, leading_zero_bits, &tmp); if (ret) return ret; } if (value) *value = (1 << leading_zero_bits) - 1 + tmp; return 0; } static int rbsp_write_uev(struct rbsp *rbsp, unsigned int *value) { int ret; int leading_zero_bits; if (!value) return -EINVAL; leading_zero_bits = ilog2(*value + 1); ret = rbsp_write_bits(rbsp, leading_zero_bits, 0); if (ret) return ret; return rbsp_write_bits(rbsp, leading_zero_bits + 1, *value + 1); } static int rbsp_read_sev(struct rbsp *rbsp, int *value) { int ret; unsigned int tmp; ret = rbsp_read_uev(rbsp, &tmp); if (ret) return ret; if (value) { if (tmp & 1) *value = (tmp + 1) / 2; else *value = -(tmp / 2); } return 0; } static int rbsp_write_sev(struct rbsp *rbsp, int *value) { unsigned int tmp; if (!value) return -EINVAL; if (*value > 0) tmp = (2 * (*value)) | 1; else tmp = -2 * (*value); return rbsp_write_uev(rbsp, &tmp); } static int __rbsp_write_bit(struct rbsp *rbsp, int *value) { return rbsp_write_bit(rbsp, *value); } static int __rbsp_write_bits(struct rbsp *rbsp, int n, unsigned int *value) { return rbsp_write_bits(rbsp, n, *value); } struct nal_rbsp_ops write = { .rbsp_bit = __rbsp_write_bit, .rbsp_bits = __rbsp_write_bits, .rbsp_uev = rbsp_write_uev, .rbsp_sev = rbsp_write_sev, }; static int __rbsp_read_bit(struct rbsp *rbsp, int *value) { int tmp = rbsp_read_bit(rbsp); if (tmp < 0) return tmp; *value = tmp; return 0; } struct nal_rbsp_ops read = { .rbsp_bit = __rbsp_read_bit, .rbsp_bits = rbsp_read_bits, .rbsp_uev = rbsp_read_uev, .rbsp_sev = rbsp_read_sev, }; void rbsp_bit(struct rbsp *rbsp, int *value) { if (rbsp->error) return; rbsp->error = rbsp->ops->rbsp_bit(rbsp, value); } void rbsp_bits(struct rbsp *rbsp, int n, int *value) { if (rbsp->error) return; rbsp->error = rbsp->ops->rbsp_bits(rbsp, n, value); } void rbsp_uev(struct rbsp *rbsp, unsigned int *value) { if (rbsp->error) return; rbsp->error = rbsp->ops->rbsp_uev(rbsp, value); } void rbsp_sev(struct rbsp *rbsp, int *value) { if (rbsp->error) return; rbsp->error = rbsp->ops->rbsp_sev(rbsp, value); } void rbsp_trailing_bits(struct rbsp *rbsp) { unsigned int rbsp_stop_one_bit = 1; unsigned int rbsp_alignment_zero_bit = 0; rbsp_bit(rbsp, &rbsp_stop_one_bit); rbsp_bits(rbsp, round_up(rbsp->pos, 8) - rbsp->pos, &rbsp_alignment_zero_bit); }