/* encoding.cpp
 *
 * Copyright (C) 2012 Ivan Klyuchnikov
 * Copyright (C) 2012 Andreas Eversberg <jolly@eversberg.eu>
 * Copyright (C) 2013 by Holger Hans Peter Freyther
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 */

#include <encoding.h>
#include <gprs_rlcmac.h>
#include <bts.h>
#include <tbf.h>
#include <tbf_ul.h>
#include <tbf_dl.h>
#include <gprs_debug.h>
#include <egprs_rlc_compression.h>

extern "C" {
#include <osmocom/gsm/protocol/gsm_44_060.h>
#include <osmocom/gsm/protocol/gsm_04_08.h>
#include <osmocom/gsm/gsm48.h>
}

#include <stdbool.h>
#include <errno.h>
#include <string.h>

#define CHECK(rc) { if (rc < 0) return rc; }
#define SET_X(bv, x) { if (bitvec_set_bit(bv, x) < 0) return -EOWNERDEAD; }
#define SET_0(bv) SET_X(bv, ZERO)
#define SET_1(bv) SET_X(bv, ONE)
#define SET_L(bv) SET_X(bv, L)
#define SET_H(bv) SET_X(bv, H)

/* 3GPP TS 44.018 § 10.5.2.16:
   { 0 | 1 < ALPHA : bit (4) > }
   < GAMMA : bit (5) >
*/
static int write_alpha_gamma(bitvec *dest, uint8_t alpha, uint8_t gamma)
{
	int rc;

	if (alpha) {
		SET_1(dest);
		rc = bitvec_set_u64(dest, alpha, 4, false);
		CHECK(rc);
	} else
		SET_0(dest);

	rc = bitvec_set_u64(dest, gamma, 5, false);
	CHECK(rc);

	return 0;
}

/* TBF_STARTING_TIME -- same as 3GPP TS 44.018 §10.5.2.38 Starting Time without tag: */
static int write_tbf_start_time(bitvec *dest, uint16_t rfn)
{
	int rc;

	/* Set values according to 3GPP TS 44.018 Table 10.5.2.38.1 */

	/* T1' */
	rc = bitvec_set_u64(dest, (rfn / (26 * 51)) % 32, 5, false);
	CHECK(rc);

	/* T3  */
	rc = bitvec_set_u64(dest, rfn % 51, 6, false);
	CHECK(rc);

	/* T2  */
	rc = bitvec_set_u64(dest, rfn % 26, 5, false);
	CHECK(rc);

	return rc;
}

/* 3GPP TS 44.018 §10.5.2.16:
   < TFI_ASSIGNMENT : bit (5) >
   < POLLING : bit >
   0 -- The value '1' was allocated in an earlier version of the protocol and shall not be used.
   < USF: bit (3) >
   < USF_GRANULARITY : bit >
   { 0 | 1 < P0 : bit (4) > < PR_MODE : bit (1) > }
*/
static int write_tfi_usf(bitvec *dest, const gprs_rlcmac_ul_tbf *tbf, uint8_t usf)
{
	int rc = bitvec_set_u64(dest, tbf->tfi(), 5, false); /* TFI_ASSIGNMENT */
	CHECK(rc);

	SET_0(dest); /* POLLING -- no action is required from MS */

	SET_0(dest);

	rc = bitvec_set_u64(dest, usf, 3, false); /* USF */
	CHECK(rc);

	SET_0(dest); /* USF_GRANULARITY -- the mobile station shall transmit one RLC/MAC block */

	SET_0(dest); /* No P0 nor PR_MODE */

	return 0;
}

/* { 0 | 1 < TIMING_ADVANCE_INDEX : bit (4) > } */
static int write_ta_index(bitvec *dest, int8_t tai)
{
	int rc;

	if (tai < 0) { /* No TIMING_ADVANCE_INDEX: */
		SET_0(dest);
	} else { /* TIMING_ADVANCE_INDEX: */
		SET_1(dest);
		rc = bitvec_set_u64(dest, tai, 4, false);
		CHECK(rc);
	}

	return 0;
}

static inline bool write_tai(bitvec *dest, unsigned& wp, int8_t tai)
{
	if (tai < 0) { /* No TIMING_ADVANCE_INDEX: */
		bitvec_write_field(dest, &wp, 0, 1);
		return false;
	}
	/* TIMING_ADVANCE_INDEX: */
	bitvec_write_field(dest, &wp, 1, 1);
	bitvec_write_field(dest, &wp, tai, 4);
	return true;
}

/* { 0 | 1 < TIMING_ADVANCE_VALUE : bit (6) > } */
static inline void write_ta(bitvec *dest, unsigned& wp, uint8_t ta)
{
	if (ta > 63) /* No TIMING_ADVANCE_VALUE: */
		bitvec_write_field(dest, &wp, 0, 1);
	else { /* TIMING_ADVANCE_VALUE: */
		bitvec_write_field(dest, &wp, 1, 1);
		bitvec_write_field(dest, &wp, ta, 6);
	}
}

/* 3GPP TS 44.060 Table 12.5.2.1 */
static inline uint16_t enc_ws(uint16_t ws)
{
	return (ws - 64) / 32;
}

static inline void write_ws(bitvec *dest, unsigned int *write_index, uint16_t ws)
{
	dest->cur_bit = *write_index;

	int rc = bitvec_set_u64(dest, enc_ws(ws), 5, false);
	OSMO_ASSERT(rc == 0);

	*write_index += 5;
}

/* 3GPP TS 44.060 § 12.12:
   { 0 | 1 < TIMING_ADVANCE_VALUE : bit (6) > }
   { 0 | 1 < TIMING_ADVANCE_INDEX : bit (4) >
           < TIMING_ADVANCE_TIMESLOT_NUMBER : bit (3) > }
 */
static inline void write_ta_ie(bitvec *dest, unsigned& wp,
			       uint8_t ta, int8_t tai, uint8_t ts)
{
	write_ta(dest, wp, ta);
	if (write_tai(dest, wp, tai)) /* TIMING_ADVANCE_TIMESLOT_NUMBER: */
		bitvec_write_field(dest, &wp, ts, 3);
}

static int write_ia_rest_downlink(const gprs_rlcmac_dl_tbf *tbf, bitvec * dest, bool polling, bool ta_valid,
				  uint16_t rfn, uint8_t alpha, uint8_t gamma, int8_t ta_idx)
{
	int rc = 0;

	SET_H(dest); SET_H(dest);
	SET_0(dest); SET_1(dest); /* 00 Packet Downlink Assignment */

	rc = bitvec_set_u64(dest, tbf->tlli(), 32, false); /* TLLI */
	CHECK(rc);

	SET_1(dest);
	rc = bitvec_set_u64(dest, tbf->tfi(), 5, false);   /* TFI_ASSIGNMENT */
	CHECK(rc);

	/* RLC acknowledged mode */
	rc = bitvec_set_bit(dest, (bit_value) RLC_MODE_ACKNOWLEDGED);
	CHECK(rc);

	rc = write_alpha_gamma(dest, alpha, gamma);
	CHECK(rc);

	rc = bitvec_set_bit(dest, (bit_value) polling); /* POLLING */
	CHECK(rc);

	/* N. B: NOT related to TAI! */
	rc = bitvec_set_bit(dest, (bit_value) ta_valid); /* TA_VALID */
	CHECK(rc);

	rc = write_ta_index(dest, ta_idx);
	CHECK(rc);

	if (polling) {
		SET_1(dest);
		rc = write_tbf_start_time(dest, rfn);
		CHECK(rc);
	} else
		SET_0(dest);

	SET_0(dest); /* No P0 nor PR_MODE */

	if (tbf->is_egprs_enabled()) {
		SET_H(dest);
		rc = bitvec_set_u64(dest, enc_ws(tbf->window_size()), 5, false); /* EGPRS Window Size */
		CHECK(rc);

		/* The mobile station shall not report measurements: (see 3GPP TS 44.060 Table 11.2.7.1) */
		SET_0(dest); SET_0(dest); /* LINK_QUALITY_MEASUREMENT_MODE */
		SET_1(dest);              /* No BEP_PERIOD2 */
	} else
		SET_L(dest);              /* No Additions for Rel-6 */

	return rc;
}

/* 3GPP TS 44.018 Table 10.5.2.16.1 < Packet Uplink Assignment > -- Single Block Allocation */
static int write_ia_rest_uplink_sba(bitvec *dest, uint32_t rfn, uint8_t alpha, uint8_t gamma)
{
	int rc = 0;

	SET_0(dest); /* Single Block Allocation */
	rc = write_alpha_gamma(dest, alpha, gamma);
	CHECK(rc);

	/* A 'Timing Advance index' shall not be allocated at a Single Block allocation.
	   A 'TBF Starting Time' shall be allocated at a Single Block allocation. */
	SET_0(dest);
	SET_1(dest);

	rc = write_tbf_start_time(dest, rfn);
	CHECK(rc);

	 /* No P0 nor PR_MODE */
	SET_L(dest);

	/* No Additions for R99 */
	SET_L(dest);

	 /* No Additions for Rel-6 */
	SET_L(dest);

	return rc;
}

static int write_ia_rest_uplink_mba(const gprs_rlcmac_ul_tbf *tbf, bitvec *dest, uint8_t usf,
				    uint8_t alpha, uint8_t gamma, int8_t ta_idx)
{
	int rc = 0;

	SET_1(dest); /* Multi Block Allocation */

	rc = write_tfi_usf(dest, tbf, usf);
	CHECK(rc);

	/* 3GPP TS 44.060 Table 11.2.28.2 Channel Coding Indicator */
	rc = bitvec_set_u64(dest, mcs_chan_code(tbf->current_cs()), 2, false); /* CHANNEL_CODING_COMMAND */
	CHECK(rc);

	/* TLLI_BLOCK_CHANNEL_CODING */
	SET_1(dest); /* use coding scheme as specified by the corresponding CHANNEL CODING COMMAND */

	rc = write_alpha_gamma(dest, alpha, gamma);
	CHECK(rc);

	rc = write_ta_index(dest, ta_idx);
	CHECK(rc);

	/* No TBF_STARTING_TIME */
	SET_0(dest);

	return rc;
}

static int write_ia_rest_egprs_uplink_mba(bitvec * dest, uint32_t rfn, uint8_t alpha, uint8_t gamma)
{
	int rc = 0;

	SET_0(dest); /* Multi Block Allocation */

	rc = write_alpha_gamma(dest, alpha, gamma);
	CHECK(rc);

	rc = write_tbf_start_time(dest, rfn);
	CHECK(rc);

	SET_0(dest); /* NUMBER OF RADIO BLOCKS ALLOCATED: */
	SET_0(dest); /* 1 radio block reserved for uplink transmission */
	SET_0(dest); /* No P0 */

	return rc;
}

static int write_ia_rest_egprs_uplink_sba(const gprs_rlcmac_ul_tbf *tbf, bitvec * dest, uint8_t usf,
					  uint8_t alpha, uint8_t gamma, int8_t ta_idx)
{
	int rc = 0;

	SET_1(dest); /* Single Block Allocation */

	rc = write_tfi_usf(dest, tbf, usf);
	CHECK(rc);

	/* 3GPP TS 44.060 §12.10d EGPRS Modulation and coding Scheme description: */
	rc = bitvec_set_u64(dest, mcs_chan_code(tbf->current_cs()), 4, false); /* EGPRS CHANNEL_CODING_COMMAND */
	CHECK(rc);

	/* TLLI_BLOCK_CHANNEL_CODING */
	rc = bitvec_set_bit(dest, (bit_value)tbf->tlli());
	CHECK(rc);

	/* No BEP_PERIOD2 */
	SET_0(dest);

	/* Retransmitted RLC data blocks shall not be re-segmented: (see 3GPP TS 44.060 §12.10e) */
	SET_0(dest); /* RESEGMENT */

	rc = bitvec_set_u64(dest, enc_ws(tbf->window_size()), 5, false); /* EGPRS Window Size */
	CHECK(rc);

	rc = write_alpha_gamma(dest, alpha, gamma);
	CHECK(rc);

	rc = write_ta_index(dest, ta_idx);
	CHECK(rc);

	/* No TBF_STARTING_TIME */
	SET_0(dest);

	/* No Additions for Rel-7 */
	SET_0(dest);

	return rc;
}

/*
 * Immediate assignment reject, sent on the CCCH/AGCH
 * see GSM 44.018, 9.1.20 + 10.5.2.30
 */
int Encoding::write_immediate_assignment_reject(bitvec *dest, uint16_t ra,
	uint16_t ref_rfn, enum ph_burst_type burst_type, uint8_t t3142)
{
	unsigned wp = 0;
	int plen;
	int i;

	bitvec_write_field(dest, &wp, 0x0, 4);  // Skip Indicator
	bitvec_write_field(dest, &wp, 0x6, 4);  // Protocol Discriminator
	bitvec_write_field(dest, &wp, 0x3A, 8); // Immediate Assign Message Type

	// feature indicator
	bitvec_write_field(dest, &wp, 0x0, 1);      // spare
	bitvec_write_field(dest, &wp, 0x0, 1);      // spare
	bitvec_write_field(dest, &wp, 0x0, 1);      // no cs
	bitvec_write_field(dest, &wp, 0x1, 1);      // implicit detach for PS

	bitvec_write_field(dest, &wp, 0x0, 4); // Page Mode
	/*
	 * 9.1.20.2 of 44.018 version 11.7.0 Release 11
	 * Filling of the message
	 * If necessary the request reference information element and the
	 * wait indication information element should be duplicated to
	 * fill the message.
	 * TODO: group rejection for multiple MS
	*/
	for (i = 0; i < 4; i++) {
		//10.5.2.30 Request Reference
		if (((burst_type == GSM_L1_BURST_TYPE_ACCESS_1) ||
			(burst_type == GSM_L1_BURST_TYPE_ACCESS_2))) {
			//9.1.20.2a of 44.018 version 11.7.0 Release 11
			bitvec_write_field(dest, &wp, 0x7f, 8);  /* RACH value */
		} else {
			bitvec_write_field(dest, &wp, ra, 8);	/* RACH value */
		}

		bitvec_write_field(dest, &wp,
					(ref_rfn / (26 * 51)) % 32, 5); // T1'
		bitvec_write_field(dest, &wp, ref_rfn % 51, 6);          // T3
		bitvec_write_field(dest, &wp, ref_rfn % 26, 5);          // T2

		/* 10.5.2.43 Wait Indication */
		bitvec_write_field(dest, &wp, t3142, 8);
	}

	plen = wp / 8;

	if ((wp % 8)) {
		LOGP(DRLCMACUL, LOGL_ERROR, "Length of IMM.ASS.Rej without"
			"rest octets is not multiple of 8 bits, PLEASE FIX!\n");
		return -1;
	}

	// Extended RA
	else if (((burst_type == GSM_L1_BURST_TYPE_ACCESS_1) ||
			(burst_type == GSM_L1_BURST_TYPE_ACCESS_2))) {
		//9.1.20.2a of 44.018 version 11.7.0 Release 11
		uint8_t extended_ra = 0;

		extended_ra = (ra & 0x1F);
		bitvec_write_field(dest, &wp, 0x1, 1);
		bitvec_write_field(dest, &wp, extended_ra, 5); /* Extended RA */
	} else {
		bitvec_write_field(dest, &wp, 0x0, 1);
	}
	bitvec_write_field(dest, &wp, 0x0, 1);
	bitvec_write_field(dest, &wp, 0x0, 1);
	bitvec_write_field(dest, &wp, 0x0, 1);

	return plen;
}

/*
 * Immediate assignment, sent on the CCCH/AGCH
 * see GSM 04.08, 9.1.18 and GSM 44.018, 9.1.18 + 10.5.2.16
 */
int Encoding::write_immediate_assignment(
	const struct gprs_rlcmac_pdch *pdch,
	const struct gprs_rlcmac_tbf *tbf,
	bitvec * dest, bool downlink, uint16_t ra,
	uint16_t ref_rfn, uint8_t ta,
	uint8_t usf, bool polling, uint16_t rfn, uint8_t alpha,
	uint8_t gamma, int8_t ta_idx, enum ph_burst_type burst_type)
{
	unsigned wp = 0;
	int plen;
	int rc;

	bitvec_write_field(dest, &wp, 0x0, 4);  // Skip Indicator
	bitvec_write_field(dest, &wp, 0x6, 4);  // Protocol Discriminator
	bitvec_write_field(dest, &wp, GSM48_MT_RR_IMM_ASS, 8); // Immediate Assignment Message Type

	// 10.5.2.25b Dedicated mode or TBF
	bitvec_write_field(dest, &wp, 0x0, 1);      // spare
	bitvec_write_field(dest, &wp, 0x0, 1);      // TMA : Two-message assignment: No meaning
	bitvec_write_field(dest, &wp, downlink, 1); // Downlink : Downlink assignment to mobile in packet idle mode
	bitvec_write_field(dest, &wp, 0x1, 1);      // T/D : TBF or dedicated mode: this message assigns a Temporary Block Flow (TBF).

	bitvec_write_field(dest, &wp, 0x0, 4); // Page Mode

	// GSM 04.08 10.5.2.25a Packet Channel Description
	bitvec_write_field(dest, &wp, 0x01, 5);			// Channel type
	bitvec_write_field(dest, &wp, pdch->ts_no, 3);		// TN
	bitvec_write_field(dest, &wp, pdch->tsc, 3);		// TSC

	/* RF channel configuraion: hopping or non-hopping */
	if (pdch->fh.enabled) {
		bitvec_write_field(dest, &wp, 0x01, 1); /* direct encoding */
		bitvec_write_field(dest, &wp, pdch->fh.maio, 6);
		bitvec_write_field(dest, &wp, pdch->fh.hsn, 6);
	} else {
		bitvec_write_field(dest, &wp, 0x00, 3);
		bitvec_write_field(dest, &wp, pdch->trx->arfcn, 10);
	}

	//10.5.2.30 Request Reference
	if (((burst_type == GSM_L1_BURST_TYPE_ACCESS_1) ||
		(burst_type == GSM_L1_BURST_TYPE_ACCESS_2))) {
		bitvec_write_field(dest, &wp, 0x7f, 8);  /* RACH value */
	} else {
		bitvec_write_field(dest, &wp, ra, 8);	/* RACH value */
	}

	bitvec_write_field(dest, &wp, (ref_rfn / (26 * 51)) % 32, 5); // T1'
	bitvec_write_field(dest, &wp, ref_rfn % 51, 6);               // T3
	bitvec_write_field(dest, &wp, ref_rfn % 26, 5);               // T2

	// 10.5.2.40 Timing Advance
	bitvec_write_field(dest, &wp, 0x0, 2); // spare
	bitvec_write_field(dest, &wp, ta, 6);  // Timing Advance value

	/* 10.5.2.21 Mobile Allocation */
	if (pdch->fh.enabled) {
		bitvec_write_field(dest, &wp, pdch->fh.ma_oct_len, 8);
		for (int i = 0; i < pdch->fh.ma_oct_len; i++)
			bitvec_write_field(dest, &wp, pdch->fh.ma[i], 8);
	} else {
		// No mobile allocation in non-hopping systems.
		// A zero-length LV.  Just write L=0.
		bitvec_write_field(dest, &wp, 0x00, 8);
	}

	OSMO_ASSERT(wp % 8 == 0);

	plen = wp / 8;

	/* 3GPP TS 44.018 §10.5.2.16 IA Rest Octets */
	dest->cur_bit = wp;
	if (downlink) {
		OSMO_ASSERT(tbf_as_dl_tbf_const(tbf) != NULL);

		rc = write_ia_rest_downlink(tbf_as_dl_tbf_const(tbf), dest, polling, gsm48_ta_is_valid(ta), rfn, alpha, gamma,
					    ta_idx);
	} else if (((burst_type == GSM_L1_BURST_TYPE_ACCESS_1) || (burst_type == GSM_L1_BURST_TYPE_ACCESS_2))) {
		SET_L(dest); SET_H(dest); // "LH"
		SET_0(dest); SET_0(dest); // "00" < EGPRS Packet Uplink Assignment >
		rc = bitvec_set_u64(dest, ra & 0x1F, 5, false); // < Extended RA >
		CHECK(rc);

		SET_0(dest); // No < Access Technologies Request struct >

		if (tbf_as_ul_tbf_const(tbf) != NULL)
			rc = write_ia_rest_egprs_uplink_sba(tbf_as_ul_tbf_const(tbf), dest, usf, alpha, gamma, ta_idx);
		else
			rc = write_ia_rest_egprs_uplink_mba(dest, rfn, alpha, gamma);
	} else {
		OSMO_ASSERT(!tbf || !tbf->is_egprs_enabled());

		SET_H(dest); SET_H(dest); // "HH"
		SET_0(dest); SET_0(dest); // "00" < Packet Uplink Assignment >

		if (tbf_as_ul_tbf_const(tbf) != NULL)
			rc = write_ia_rest_uplink_mba(tbf_as_ul_tbf_const(tbf), dest, usf, alpha, gamma, ta_idx);
		else
			rc = write_ia_rest_uplink_sba(dest, rfn, alpha, gamma);
	}

	if (rc < 0) {
		LOGP(DRLCMAC, LOGL_ERROR,
			"Failed to create IMMEDIATE ASSIGNMENT (%s) for %s\n",
			downlink ? "downlink" : "uplink",
			tbf ? tbf->name() : "single block allocation");
		return rc;
	}

	return plen;
}

/* Prepare to be encoded Frequency Parameters IE (see Table 12.8.1) */
static void gen_freq_params(Frequency_Parameters_t *freq_params,
			    const struct gprs_rlcmac_tbf *tbf)
{
	const struct gprs_rlcmac_pdch *pdch;
	Direct_encoding_1_t fh_params;

	/* Check one PDCH, if it's hopping then all other should too */
	pdch = tbf_get_first_ts_const(tbf);
	OSMO_ASSERT(pdch != NULL);

	/* Training Sequence Code */
	freq_params->TSC = pdch->tsc;

	/* If frequency hopping is not in use, encode a single ARFCN */
	if (!pdch->fh.enabled) {
		freq_params->UnionType = 0x00;
		freq_params->u.ARFCN = pdch->trx->arfcn;
		return;
	}

	/* Direct encoding 1 (see Table 12.8.1) */
	freq_params->UnionType = 0x2;

	/* HSN / MAIO */
	fh_params.MAIO = pdch->fh.maio;
	fh_params.GPRS_Mobile_Allocation.HSN = pdch->fh.hsn;
	fh_params.GPRS_Mobile_Allocation.ElementsOf_RFL_NUMBER = 0;
	memset(&fh_params.GPRS_Mobile_Allocation.RFL_NUMBER[0], 0x00,
	       sizeof(fh_params.GPRS_Mobile_Allocation.RFL_NUMBER));

	/* Mobile Allocation bitmap */
	fh_params.GPRS_Mobile_Allocation.UnionType = 0; /* MA bitmap */
	fh_params.GPRS_Mobile_Allocation.u.MA.MA_LENGTH = pdch->fh.ma_oct_len; /* in bytes */
	fh_params.GPRS_Mobile_Allocation.u.MA.MA_BitLength = pdch->fh.ma_bit_len; /* in bits */
	memcpy(fh_params.GPRS_Mobile_Allocation.u.MA.MA_BITMAP, pdch->fh.ma, pdch->fh.ma_oct_len);

	freq_params->u.Direct_encoding_1 = fh_params;
}

/* Generate Packet Uplink Assignment as per 3GPP TS 44.060, section 11.2.29.
 * NOTE: 'block' is expected to be zero-initialized by the caller. */
void write_packet_uplink_assignment(RlcMacDownlink_t *block, uint8_t old_tfi,
	uint8_t old_downlink, uint32_t tlli, uint8_t use_tlli,
	const struct gprs_rlcmac_ul_tbf *tbf, uint8_t poll, uint8_t rrbp, uint8_t alpha,
	uint8_t gamma, int8_t ta_idx, bool use_egprs)
{
	Packet_Uplink_Assignment_t *pua;
	Packet_Timing_Advance_t *pta;
	Frequency_Parameters_t *fp;
	Dynamic_Allocation_t *da;

	/* RLC/MAC control block without the optional RLC/MAC control header */
	block->PAYLOAD_TYPE = 0x01;  // Payload Type
	block->RRBP         = rrbp;  // RRBP (e.g. N+13)
	block->SP           = poll;  // RRBP field is valid
	block->USF          = 0x00;  // Uplink state flag

	/* See 3GPP TS 44.060, section 11.2.29 */
	pua = &block->u.Packet_Uplink_Assignment;
	pua->MESSAGE_TYPE = MT_PACKET_UPLINK_ASSIGNMENT;  // Packet Uplink Assignment
	pua->PAGE_MODE    = 0x00;  // Normal Paging

	/* TLLI or Global (UL/DL) TFI */
	if (use_tlli) {
		pua->ID.UnionType = 0x01;
		pua->ID.u.TLLI = tlli;
	} else {
		pua->ID.UnionType = 0x00;
		pua->ID.u.Global_TFI.UnionType = old_downlink;
		pua->ID.u.Global_TFI.u.UPLINK_TFI = old_tfi;
	}

	/* GPRS/EGPRS specific parameters */
	pua->UnionType = use_egprs ? 0x01 : 0x00;
	if (!use_egprs) {
		PUA_GPRS_t *gprs = &pua->u.PUA_GPRS_Struct;

		/* Use the commanded CS/MCS value during the content resolution */
		gprs->CHANNEL_CODING_COMMAND    = mcs_chan_code(tbf->current_cs());
		gprs->TLLI_BLOCK_CHANNEL_CODING = 0x01;  // ^^^

		/* Dynamic allocation */
		gprs->UnionType = 0x01;
		/* Frequency Parameters IE is present */
		gprs->Exist_Frequency_Parameters = 0x01;

		/* Common parameters to be set below */
		pta = &gprs->Packet_Timing_Advance;
		fp = &gprs->Frequency_Parameters;
		da = &gprs->u.Dynamic_Allocation;
	} else {
		PUA_EGPRS_00_t *egprs = &pua->u.PUA_EGPRS_Struct.u.PUA_EGPRS_00;
		pua->u.PUA_EGPRS_Struct.UnionType = 0x00;  // 'Normal' EGPRS, not EGPRS2

		/* Use the commanded CS/MCS value during the content resolution */
		egprs->EGPRS_CHANNEL_CODING_COMMAND = mcs_chan_code(tbf->current_cs());
		egprs->TLLI_BLOCK_CHANNEL_CODING    = 0x01;  // ^^^
		egprs->RESEGMENT                    = 0x01;  // Enable segmentation
		egprs->EGPRS_WindowSize             = tbf->window_size();

		/* Dynamic allocation */
		egprs->UnionType = 0x01;
		/* Frequency Parameters IE is present */
		egprs->Exist_Frequency_Parameters = 0x01;

		/* Common parameters to be set below */
		pta = &egprs->Packet_Timing_Advance;
		fp = &egprs->Frequency_Parameters;
		da = &egprs->u.Dynamic_Allocation;
	}

	/* Packet Timing Advance (if known) */
	if (gsm48_ta_is_valid(tbf->ta())) { /* { 0 | 1  < TIMING_ADVANCE_VALUE : bit (6) > } */
		pta->Exist_TIMING_ADVANCE_VALUE = 0x01;  // Present
		pta->TIMING_ADVANCE_VALUE       = tbf->ta();
	}

	/* Continuous Timing Advance Control */
	if (ta_idx >= 0 && ta_idx < 16) {
		pta->Exist_IndexAndtimeSlot         = 0x01;  // Present
		pta->TIMING_ADVANCE_TIMESLOT_NUMBER = 0;  // FIXME!
		pta->TIMING_ADVANCE_INDEX           = ta_idx;
	}

	/* Frequency Parameters IE */
	gen_freq_params(fp, tbf);

	/* Dynamic allocation parameters */
	da->USF_GRANULARITY = 0x00;

	/* Assign an Uplink TFI */
	da->Exist_UPLINK_TFI_ASSIGNMENT = 0x01;
	da->UPLINK_TFI_ASSIGNMENT = tbf->tfi();

	/* Timeslot Allocation with or without Power Control */
	da->UnionType = (alpha || gamma) ? 0x01 : 0x00;
	if (da->UnionType == 0x01)
		da->u.Timeslot_Allocation_Power_Ctrl_Param.ALPHA = alpha;

	for (unsigned int tn = 0; tn < 8; tn++) {
		if (tbf->pdch[tn] == NULL)
			continue;

		if (da->UnionType == 0x01) {
			Timeslot_Allocation_Power_Ctrl_Param_t *params = \
				&da->u.Timeslot_Allocation_Power_Ctrl_Param;
			params->Slot[tn].Exist    = 0x01;  // Enable this timeslot
			params->Slot[tn].USF_TN   = tbf->m_usf[tn];  // USF_TN(i)
			params->Slot[tn].GAMMA_TN = gamma;
		} else {
			Timeslot_Allocation_t *slot = &da->u.Timeslot_Allocation[tn];
			slot->Exist  = 0x01;  // Enable this timeslot
			slot->USF_TN = tbf->m_usf[tn];  // USF_TN(i)
		}
	}
}


/* Generate Packet Downlink Assignment as per 3GPP TS 44.060, section 11.2.7.
 * NOTE: 'block' is expected to be zero-initialized by the caller. */
void write_packet_downlink_assignment(RlcMacDownlink_t * block,
	bool old_tfi_is_valid, uint8_t old_tfi, uint8_t old_downlink,
	const struct gprs_rlcmac_dl_tbf *tbf, uint8_t poll, uint8_t rrbp,
	uint8_t alpha, uint8_t gamma, int8_t ta_idx,
	uint8_t ta_ts, bool use_egprs, uint8_t control_ack)
{
	PDA_AdditionsR99_t *pda_r99;

	uint8_t tn;

	block->PAYLOAD_TYPE = 0x1;  // RLC/MAC control block that does not include the optional octets of the RLC/MAC control header
	block->RRBP         = rrbp;  // 0: N+13
	block->SP           = poll; // RRBP field is valid
	block->USF          = 0x0;  // Uplink state flag

	block->u.Packet_Downlink_Assignment.MESSAGE_TYPE = 0x2;  // Packet Downlink Assignment
	block->u.Packet_Downlink_Assignment.PAGE_MODE    = 0x0;  // Normal Paging

	block->u.Packet_Downlink_Assignment.Exist_PERSISTENCE_LEVEL      = 0x0;          // PERSISTENCE_LEVEL: off

	if (old_tfi_is_valid) {
		block->u.Packet_Downlink_Assignment.ID.UnionType                 = 0x0;          // TFI = on
		block->u.Packet_Downlink_Assignment.ID.u.Global_TFI.UnionType    = old_downlink; // 0=UPLINK TFI, 1=DL TFI
		block->u.Packet_Downlink_Assignment.ID.u.Global_TFI.u.UPLINK_TFI = old_tfi;      // TFI
	} else {
		block->u.Packet_Downlink_Assignment.ID.UnionType                 = 0x1;          // TLLI
		block->u.Packet_Downlink_Assignment.ID.u.TLLI                    = tbf->tlli();
	}

	block->u.Packet_Downlink_Assignment.MAC_MODE            = 0x0;          // Dynamic Allocation
	block->u.Packet_Downlink_Assignment.RLC_MODE            = RLC_MODE_ACKNOWLEDGED;
	block->u.Packet_Downlink_Assignment.CONTROL_ACK         = control_ack; // NW establishes no new DL TBF for the MS with running timer T3192
	block->u.Packet_Downlink_Assignment.TIMESLOT_ALLOCATION = 0;   // timeslot(s)
	for (tn = 0; tn < 8; tn++) {
		if (tbf->pdch[tn])
			block->u.Packet_Downlink_Assignment.TIMESLOT_ALLOCATION |= 0x80 >> tn;   // timeslot(s)
	}

	if (tbf->ta() > 63) { /* { 0 | 1  < TIMING_ADVANCE_VALUE : bit (6) > } */
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.Exist_TIMING_ADVANCE_VALUE = 0x0; // TIMING_ADVANCE_VALUE = off
	} else {
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.Exist_TIMING_ADVANCE_VALUE = 0x1; // TIMING_ADVANCE_VALUE = on
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.TIMING_ADVANCE_VALUE       = tbf->ta();  // TIMING_ADVANCE_VALUE
	}

	if (ta_idx < 0) {
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.Exist_IndexAndtimeSlot     = 0x0; // TIMING_ADVANCE_INDEX = off
	} else {
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.Exist_IndexAndtimeSlot     = 0x1; // TIMING_ADVANCE_INDEX = on
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.TIMING_ADVANCE_INDEX       = ta_idx; // TIMING_ADVANCE_INDEX
		block->u.Packet_Downlink_Assignment.Packet_Timing_Advance.TIMING_ADVANCE_TIMESLOT_NUMBER = ta_ts; // TIMING_ADVANCE_TS
	}

	block->u.Packet_Downlink_Assignment.Exist_P0_and_BTS_PWR_CTRL_MODE = 0x0;   // POWER CONTROL = off

	block->u.Packet_Downlink_Assignment.Exist_Frequency_Parameters     = 0x1;   // Frequency Parameters = on
	gen_freq_params(&block->u.Packet_Downlink_Assignment.Frequency_Parameters, tbf);

	block->u.Packet_Downlink_Assignment.Exist_DOWNLINK_TFI_ASSIGNMENT  = 0x1;     // DOWNLINK TFI ASSIGNMENT = on
	block->u.Packet_Downlink_Assignment.DOWNLINK_TFI_ASSIGNMENT        = tbf->tfi(); // TFI

	block->u.Packet_Downlink_Assignment.Exist_Power_Control_Parameters = 0x1;   // Power Control Parameters = on
	block->u.Packet_Downlink_Assignment.Power_Control_Parameters.ALPHA = alpha;   // ALPHA

	for (tn = 0; tn < 8; tn++)
	{
		if (tbf->pdch[tn])
		{
			block->u.Packet_Downlink_Assignment.Power_Control_Parameters.Slot[tn].Exist    = 0x1; // Slot[i] = on
			block->u.Packet_Downlink_Assignment.Power_Control_Parameters.Slot[tn].GAMMA_TN = gamma; // GAMMA_TN
		}
		else
		{
			block->u.Packet_Downlink_Assignment.Power_Control_Parameters.Slot[tn].Exist    = 0x0; // Slot[i] = off
		}
	}

	block->u.Packet_Downlink_Assignment.Exist_TBF_Starting_Time   = 0x0; // TBF Starting TIME = off
	block->u.Packet_Downlink_Assignment.Exist_Measurement_Mapping = 0x0; // Measurement_Mapping = off
	if (!use_egprs) {
		block->u.Packet_Downlink_Assignment.Exist_AdditionsR99        = 0x0; // AdditionsR99 = off
		return;
	}

	block->u.Packet_Downlink_Assignment.Exist_AdditionsR99        = 0x1; // AdditionsR99 = on
	pda_r99 = &block->u.Packet_Downlink_Assignment.AdditionsR99;
	pda_r99->Exist_EGPRS_Params = 1;
	pda_r99->EGPRS_WindowSize = enc_ws(tbf->window_size()); /* see TS 44.060, table 12.5.2.1 */
	pda_r99->LINK_QUALITY_MEASUREMENT_MODE = 0x0; /* no meas, see TS 44.060, table 11.2.7.2 */
	pda_r99->Exist_BEP_PERIOD2 = 0; /* No extra EGPRS BEP PERIOD */
	pda_r99->Exist_Packet_Extended_Timing_Advance = 0;
	pda_r99->Exist_COMPACT_ReducedMA = 0;
}

/* Generate paging request. See 44.018, sections 10 and 9.1.22 */
int write_paging_request(struct bitvec *dest, const struct osmo_mobile_identity *mi)
{
	uint8_t mi_buf[GSM48_MID_MAX_SIZE];
	int mi_len;
	unsigned wp = 0;
	int plen;

	bitvec_write_field(dest, &wp,0x0,4);  // Skip Indicator
	bitvec_write_field(dest, &wp,0x6,4);  // Protocol Discriminator
	bitvec_write_field(dest, &wp,0x21,8); // Paging Request Message Type 1

	bitvec_write_field(dest, &wp,0x0,4);  // Page Mode
	bitvec_write_field(dest, &wp,0x0,4);  // Channel Needed

	mi_len = osmo_mobile_identity_encode_buf(mi_buf, sizeof(mi_buf), mi, true);
	if (mi_len <= 0)
		return mi_len;
	bitvec_write_field(dest, &wp, mi_len, 8);  // Mobile Identity length
	bitvec_set_bytes(dest, mi_buf, mi_len);    // Mobile Identity
	wp += mi_len * 8;

	OSMO_ASSERT(wp % 8 == 0);

	plen = wp / 8;
	bitvec_write_field(dest, &wp,0x0,1); // "L" Notification List Number; NLN(PCH) = off
	bitvec_write_field(dest, &wp,0x0,1); // "L" Priority1 = off
	bitvec_write_field(dest, &wp,0x1,1); // "L" Priority2 = off
	bitvec_write_field(dest, &wp,0x0,1); // "L" Group Call information = off
	bitvec_write_field(dest, &wp,0x0,1); // "H" Packet Page Indication 1 = packet paging procedure
	bitvec_write_field(dest, &wp,0x1,1); // "H" Packet Page Indication 2 = packet paging procedure

	return plen;
}

/**
 * The index of the array show_rbb is the bit position inside the rbb
 * (show_rbb[63] relates to BSN ssn-1)
 */
void Encoding::encode_rbb(const char *show_rbb, bitvec *bv)
{
	// RECEIVE_BLOCK_BITMAP
	for (int i = 0; i < 64; i++) {
		/* Set bit at the appropriate position (see 3GPP TS 44.060 9.1.8.1) */
		bitvec_set_bit(bv, show_rbb[i] == 'R' ? ONE : ZERO);
	}
}

static void write_packet_ack_nack_desc_gprs(
	bitvec * dest, unsigned& wp,
	gprs_rlc_ul_window *window, bool is_final)
{
	char rbb[65];

	window->update_rbb(rbb);

	rbb[64] = 0;
	LOGP(DRLCMACUL, LOGL_DEBUG, "- V(N): \"%s\" R=Received "
		"I=Invalid\n", rbb);

	bitvec_write_field(dest, &wp, is_final, 1); // FINAL_ACK_INDICATION
	bitvec_write_field(dest, &wp, window->ssn(), 7); // STARTING_SEQUENCE_NUMBER

	for (int i = 0; i < 64; i++) {
		/* Set bit at the appropriate position (see 3GPP TS 44.060 9.1.8.1) */
		bool is_ack = (rbb[i] == 'R');
		bitvec_write_field(dest, &wp, is_ack, 1);
	}
}

static void write_packet_uplink_ack_gprs(
	bitvec * dest, unsigned& wp,
	struct gprs_rlcmac_ul_tbf *tbf, bool is_final)
{
	gprs_rlc_ul_window *window = static_cast<gprs_rlc_ul_window *>(tbf->window());

	bitvec_write_field(dest, &wp, mcs_chan_code(tbf->current_cs()), 2); // CHANNEL_CODING_COMMAND
	write_packet_ack_nack_desc_gprs(dest, wp, window, is_final);

	if (tbf->is_tlli_valid()) {
		bitvec_write_field(dest, &wp, 1, 1); // 1: have CONTENTION_RESOLUTION_TLLI
		bitvec_write_field(dest, &wp, tbf->tlli(), 32); // CONTENTION_RESOLUTION_TLLI
	} else {
		bitvec_write_field(dest, &wp, 0, 1); // 0: don't have CONTENTION_RESOLUTION_TLLI
	}

	if (gsm48_ta_is_valid(tbf->ta())) {
		bitvec_write_field(dest, &wp, 1, 1); // 1: have Packet Timing Advance IE (TS 44.060 12.12)
		bitvec_write_field(dest, &wp, 1, 1); // 1: have TIMING_ADVANCE_VALUE
		bitvec_write_field(dest, &wp, tbf->ta(), 6); // TIMING_ADVANCE_VALUE
		bitvec_write_field(dest, &wp, 0, 1); // 0: don't have TIMING_ADVANCE_INDEX
	} else {
		bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Packet Timing Advance
	}

	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Power Control Parameters
	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Extension Bits
	bitvec_write_field(dest, &wp, 0, 1); // fixed 0
	bitvec_write_field(dest, &wp, 1, 1); // 1: have Additions R99
	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Packet Extended Timing Advance
	bitvec_write_field(dest, &wp, 1, 1); // TBF_EST (enabled)
	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have REL 5
};

/* Encode the Ack/Nack for EGPRS. 44.060
 * The PCU encodes to receive block bitmap to the following rules:
 * - always encode the lenght field
 * - use compressed receive block bitmap if it's smaller than uncompressed
 *   receive block bitmap
 * - use the remaining bits for an uncompressed receive block bitmap if needed
 *
 * Note: The spec also defines an Ack/Nack without length field, but the PCU's
 *       doesn't support this in UL. It would require a lot more code complexity
 *       and only saves 7 bit in lossy sitations.
 */
static void write_packet_ack_nack_desc_egprs(
	bitvec * dest, unsigned& wp,
	gprs_rlc_ul_window *window, bool is_final, unsigned rest_bits)
{
	unsigned int urbb_len = 0;
	uint8_t crbb_len = 0;
	uint8_t len;
	bool bow = true;
	bool eow = true;
	uint16_t ssn = window->mod_sns(window->v_q() + 1);
	unsigned int num_blocks = window->mod_sns(window->v_r() - window->v_q());
	uint16_t esn_crbb = window->mod_sns(ssn - 1);
	static  uint8_t rbb[RLC_EGPRS_MAX_WS] = {'\0'};
	uint8_t iter = 0;
	int is_compressed = 0;
	bool try_compression = false;
	uint16_t ucmp_bmplen;
	uint8_t crbb_bitmap[23] = {'\0'};
	bitvec ucmp_vec;
	bitvec crbb_vec;
	uint8_t uclen_crbb = 0;
	uint8_t crbb_start_clr_code;
	uint8_t i;

	/* static size of 16 bits
	 ..1. .... = ACKNACK:  (Union)
	    0 0000 000 Length
	Desc

	    ...0 .... = FINAL_ACK_INDICATION: False

	    .... 1... = BEGINNING_OF_WINDOW: 1

	    .... .1.. = END_OF_WINDOW: 1

	    .... ..10  0101 0001  1... .... = STARTING_SEQUENCE_NUMBER: 1187

	    .0.. .... = CRBB Exist: 0
	minimal size is 24 rest_bits */
	rest_bits -= 24;

	if (num_blocks > 0)
		/* V(Q) is NACK and omitted -> SSN = V(Q) + 1 */
		num_blocks -= 1;

	if (num_blocks > window->ws())
		num_blocks = window->ws();
	/* Try Compression  as number of blocks does not fit */
	if (num_blocks > rest_bits) {
		try_compression = true;
	}
	if (try_compression == true) {
		ucmp_bmplen = window->update_egprs_rbb(rbb);
		ucmp_vec.data = rbb;
		ucmp_vec.cur_bit = ucmp_bmplen;
		ucmp_vec.data_len = 127;
		crbb_vec.data = crbb_bitmap;
		crbb_vec.cur_bit = 0;
		crbb_vec.data_len = 127;
		LOGP(DRLCMACUL, LOGL_DEBUG,
		"rest_bits=%d uncompressed len %d and uncompressed bitmap = %s\n",
		 rest_bits, ucmp_bmplen,
		osmo_hexdump(ucmp_vec.data, (ucmp_bmplen+7)/8));

		is_compressed = egprs_compress::compress_rbb(&ucmp_vec, /* Uncompressed bitmap*/
			&crbb_vec, /*Compressed bitmap vector */
			&uclen_crbb,
			(rest_bits - 16));/* CRBBlength:7 colourcode:1 dissector length:8*/
		LOGP(DRLCMACUL, LOGL_DEBUG,
		"the ucmp len=%d uclen_crbb=%d num_blocks=%d crbb length %d, "
		"and the CRBB bitmap  = %s\n",
		ucmp_bmplen, uclen_crbb, num_blocks, crbb_vec.cur_bit,
		osmo_hexdump(crbb_bitmap, (crbb_vec.cur_bit+7)/8));
		crbb_len = crbb_vec.cur_bit;
	}


	if (is_compressed) {
		/* 8 = 7 (CRBBlength) + 1 (CRBB starting color code) */
		rest_bits -= 8;
	} else {
		uclen_crbb = 0;
		crbb_len = 0;
	}

	if (num_blocks > uclen_crbb + rest_bits) {
		eow = false;
		urbb_len = rest_bits - crbb_len;
	} else
		urbb_len = num_blocks - uclen_crbb;

	if (is_compressed)
		len = urbb_len + crbb_len + 23;
	else
		len = urbb_len + 15;


	/* EGPRS Ack/Nack Description IE
	 * do not support Ack/Nack without length */
	bitvec_write_field(dest, &wp, 1, 1); // 1: have length
	bitvec_write_field(dest, &wp, len, 8); // length

	bitvec_write_field(dest, &wp, is_final, 1); // FINAL_ACK_INDICATION
	bitvec_write_field(dest, &wp, bow, 1); // BEGINNING_OF_WINDOW
	bitvec_write_field(dest, &wp, eow, 1); // END_OF_WINDOW
	bitvec_write_field(dest, &wp, ssn, 11); // STARTING_SEQUENCE_NUMBER
	if (is_compressed) {
		bitvec_write_field(dest, &wp, 1, 1); // CRBB_Exist
		bitvec_write_field(dest, &wp, crbb_len, 7); // CRBB_LENGTH
		crbb_start_clr_code = (0x80 & ucmp_vec.data[0])>>7;
		bitvec_write_field(dest, &wp, crbb_start_clr_code, 1); // CRBB_clr_code
		LOGP(DRLCMACUL, LOGL_DEBUG,
			"EGPRS CRBB, crbb_len = %d, crbb_start_clr_code = %d\n",
			crbb_len, crbb_start_clr_code);
		while (crbb_len != 0) {
			if (crbb_len > 8) {
				bitvec_write_field(dest, &wp, crbb_bitmap[iter], 8);
				crbb_len = crbb_len - 8;
				iter++;
			} else {
				bitvec_write_field(dest, &wp, crbb_bitmap[iter] >> (8 - crbb_len), crbb_len);
				crbb_len = 0;
			}
		}
		esn_crbb = window->mod_sns(esn_crbb + uclen_crbb);
	} else {
		bitvec_write_field(dest, &wp, 0, 1); // CRBB_Exist
	}
	LOGP(DRLCMACUL, LOGL_DEBUG,
		"EGPRS URBB, urbb len = %d, SSN = %u, ESN_CRBB = %u, "
		"desc len = %d, "
		"SNS = %d, WS = %d, V(Q) = %d, V(R) = %d%s%s\n",
		urbb_len, ssn, esn_crbb, len,
		window->sns(), window->ws(), window->v_q(), window->v_r(),
		bow ? ", BOW" : "", eow ? ", EOW" : "");

	for (i = urbb_len; i > 0; i--) {
		/* Set bit at the appropriate position (see 3GPP TS 44.060 12.3.1) */
		bool is_ack = window->m_v_n.is_received(esn_crbb + i);
		bitvec_write_field(dest, &wp, is_ack, 1);
	}
}

static void write_packet_uplink_ack_egprs(
	bitvec * dest, unsigned& wp,
	struct gprs_rlcmac_ul_tbf *tbf, bool is_final)
{
	gprs_rlc_ul_window *window = static_cast<gprs_rlc_ul_window *>(tbf->window());

	bitvec_write_field(dest, &wp, 0, 2); // fixed 00
	/* CHANNEL_CODING_COMMAND */
	bitvec_write_field(dest, &wp,
		mcs_chan_code(tbf->current_cs()), 4);
	/* 0: no RESEGMENT, 1: Segmentation*/
	bitvec_write_field(dest, &wp, 1, 1);
	bitvec_write_field(dest, &wp, 1, 1); // PRE_EMPTIVE_TRANSMISSION, TODO: This resembles GPRS, change it?
	bitvec_write_field(dest, &wp, 0, 1); // 0: no PRR_RETRANSMISSION_REQUEST, TODO: clarify
	bitvec_write_field(dest, &wp, 0, 1); // 0: no ARAC_RETRANSMISSION_REQUEST, TODO: clarify

	if (tbf->is_tlli_valid()) {
		bitvec_write_field(dest, &wp, 1, 1); // 1: have CONTENTION_RESOLUTION_TLLI
		bitvec_write_field(dest, &wp, tbf->tlli(), 32); // CONTENTION_RESOLUTION_TLLI
	} else {
		bitvec_write_field(dest, &wp, 0, 1); // 0: don't have CONTENTION_RESOLUTION_TLLI
	}

	bitvec_write_field(dest, &wp, 1, 1); // TBF_EST (enabled)

	if (gsm48_ta_is_valid(tbf->ta())) {
		bitvec_write_field(dest, &wp, 1, 1); // 1: have Packet Timing Advance IE (TS 44.060 12.12)
		bitvec_write_field(dest, &wp, 1, 1); // 1: have TIMING_ADVANCE_VALUE
		bitvec_write_field(dest, &wp, tbf->ta(), 6); // TIMING_ADVANCE_VALUE
		bitvec_write_field(dest, &wp, 0, 1); // 0: don't have TIMING_ADVANCE_INDEX
	} else {
		bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Packet Timing Advance
	}

	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Packet Extended Timing Advance
	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Power Control Parameters
	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have Extension Bits

	/* -2 for last bit 0 mandatory and REL5 not supported */
	unsigned bits_ack_nack = dest->data_len * 8 - wp - 2;
	write_packet_ack_nack_desc_egprs(dest, wp, window, is_final, bits_ack_nack);

	bitvec_write_field(dest, &wp, 0, 1); // fixed 0
	bitvec_write_field(dest, &wp, 0, 1); // 0: don't have REL 5
};

void write_packet_uplink_ack(struct bitvec *dest, struct gprs_rlcmac_ul_tbf *tbf,
			     bool is_final, uint8_t rrbp)
{
	unsigned wp = 0;

	LOGP(DRLCMACUL, LOGL_DEBUG, "Encoding Ack/Nack for %s "
		"(final=%d)\n", tbf_name(tbf), is_final);

	bitvec_write_field(dest, &wp, 0x1, 2);  // Payload Type
	bitvec_write_field(dest, &wp, rrbp, 2);  // Uplink block with TDMA framenumber
	bitvec_write_field(dest, &wp, is_final, 1);  // Suppl/Polling Bit
	bitvec_write_field(dest, &wp, 0x0, 3);  // Uplink state flag
	bitvec_write_field(dest, &wp, 0x9, 6);  // MESSAGE TYPE Uplink Ack/Nack
	bitvec_write_field(dest, &wp, 0x0, 2);  // Page Mode

	bitvec_write_field(dest, &wp, 0x0, 2);  // fixed 00
	bitvec_write_field(dest, &wp, tbf->tfi(), 5);  // Uplink TFI

	if (tbf->is_egprs_enabled()) {
		/* PU_AckNack_EGPRS = on */
		bitvec_write_field(dest, &wp, 1, 1);  // 1: EGPRS
		write_packet_uplink_ack_egprs(dest, wp, tbf, is_final);
	} else {
		/* PU_AckNack_GPRS = on */
		bitvec_write_field(dest, &wp, 0, 1);  // 0: GPRS
		write_packet_uplink_ack_gprs(dest, wp, tbf, is_final);
	}

	LOGP(DRLCMACUL, LOGL_DEBUG,
		"Uplink Ack/Nack bit count %d, max %d, message = %s\n",
		wp, dest->data_len * 8,
		osmo_hexdump(dest->data, dest->data_len));
}

unsigned Encoding::write_packet_paging_request(bitvec * dest)
{
	unsigned wp = 0;

	bitvec_write_field(dest, &wp, 0x1, 2);  // Payload Type
	bitvec_write_field(dest, &wp, 0x0, 3);  // No polling
	bitvec_write_field(dest, &wp, 0x0, 3);  // Uplink state flag
	bitvec_write_field(dest, &wp, 0x22, 6);  // MESSAGE TYPE

	bitvec_write_field(dest, &wp, 0x0, 2);  // Page Mode

	bitvec_write_field(dest, &wp, 0x0, 1);  // No PERSISTENCE_LEVEL
	bitvec_write_field(dest, &wp, 0x0, 1);  // No NLN

	return wp;
}

/* 3GPP TS 44.060 § 11.2.10:
   < Repeated Page info struct > ::=
   { 0  -- Page request for TBF establishment
    { 0 < PTMSI : bit (32) >
    | 1 < Length of Mobile Identity contents : bit (4) >
        < Mobile Identity : octet (val (Length of Mobile Identity contents)) > }
   | 1  -- Page request for RR conn. establishment
    { 0 < TMSI : bit (32) >
    | 1 < Length of Mobile Identity contents : bit (4) >
        < Mobile Identity : octet (val (Length of Mobile Identity contents)) > }
    < CHANNEL_NEEDED : bit (2) >
    { 0 | 1 < eMLPP_PRIORITY : bit (3) > }
   }
 */
unsigned Encoding::write_repeated_page_info(bitvec * dest, unsigned& wp, uint8_t len,
	uint8_t *identity, uint8_t chan_needed)
{
	bitvec_write_field(dest, &wp,0x1,1);  // Repeated Page info exists

	bitvec_write_field(dest, &wp,0x1,1);  // RR connection paging

	if ((identity[0] & 0x07) == 4) {
		bitvec_write_field(dest, &wp,0x0,1);  // TMSI
		identity++;
		len--;
	} else {
		bitvec_write_field(dest, &wp,0x1,1);  // MI
		bitvec_write_field(dest, &wp,len,4);  // MI len
	}
	while (len) {
		bitvec_write_field(dest, &wp,*identity++,8);  // MI data
		len--;
	}
	bitvec_write_field(dest, &wp,chan_needed,2);  // CHANNEL_NEEDED
	bitvec_write_field(dest, &wp,0x0,1);  // No eMLPP_PRIORITY

	return wp;
}

int Encoding::rlc_write_dl_data_header(const struct gprs_rlc_data_info *rlc,
	uint8_t *data)
{
	struct gprs_rlc_dl_header_egprs_1 *egprs1;
	struct gprs_rlc_dl_header_egprs_2 *egprs2;
	struct gprs_rlc_dl_header_egprs_3 *egprs3;
	struct rlc_dl_header *gprs;
	unsigned int e_fbi_header;
	enum CodingScheme cs = rlc->cs;
	unsigned int offs;
	unsigned int bsn_delta;

	switch(mcs_header_type(cs)) {
	case HEADER_GPRS_DATA:
		gprs = static_cast<struct rlc_dl_header *>
			((void *)data);

		gprs->usf   = rlc->usf;
		gprs->s_p   = rlc->es_p != 0 ? 1 : 0;
		gprs->rrbp  = rlc->rrbp;
		gprs->pt    = 0;
		gprs->tfi   = rlc->tfi;
		gprs->pr    = rlc->pr;

		gprs->fbi   = rlc->block_info[0].cv == 0;
		gprs->e     = rlc->block_info[0].e;
		gprs->bsn   = rlc->block_info[0].bsn;
		break;

	case HEADER_EGPRS_DATA_TYPE_1:
		egprs1 = static_cast<struct gprs_rlc_dl_header_egprs_1 *>
			((void *)data);

		egprs1->usf    = rlc->usf;
		egprs1->es_p   = rlc->es_p;
		egprs1->rrbp   = rlc->rrbp;
		egprs1->tfi_hi = rlc->tfi >> 0; /* 1 bit LSB */
		egprs1->tfi_lo = rlc->tfi >> 1; /* 4 bits */
		egprs1->pr     = rlc->pr;
		egprs1->cps    = rlc->cps;

		egprs1->bsn1_hi  = rlc->block_info[0].bsn >> 0; /* 2 bits LSB */
		egprs1->bsn1_mid = rlc->block_info[0].bsn >> 2; /* 8 bits */
		egprs1->bsn1_lo  = rlc->block_info[0].bsn >> 10; /* 1 bit */

		bsn_delta = (rlc->block_info[1].bsn - rlc->block_info[0].bsn) &
			(RLC_EGPRS_SNS - 1);

		egprs1->bsn2_hi = bsn_delta >> 0; /* 7 bits LSB */
		egprs1->bsn2_lo = bsn_delta >> 7; /* 3 bits */

		/* first FBI/E header */
		e_fbi_header   = rlc->block_info[0].e       ? 0x01 : 0;
		e_fbi_header  |= rlc->block_info[0].cv == 0 ? 0x02 : 0; /* FBI */
		offs = rlc->data_offs_bits[0] / 8;
		OSMO_ASSERT(rlc->data_offs_bits[0] % 8 == 2);
		e_fbi_header <<= 0;
		data[offs] = (data[offs] & 0b11111100) | e_fbi_header;

		/* second FBI/E header */
		e_fbi_header   = rlc->block_info[1].e       ? 0x01 : 0;
		e_fbi_header  |= rlc->block_info[1].cv == 0 ? 0x02 : 0; /* FBI */
		offs = rlc->data_offs_bits[1] / 8;
		OSMO_ASSERT(rlc->data_offs_bits[1] % 8 == 4);
		e_fbi_header <<= 2;
		data[offs] = (data[offs] & 0b11110011) | e_fbi_header;
		break;

	case HEADER_EGPRS_DATA_TYPE_2:
		egprs2 = static_cast<struct gprs_rlc_dl_header_egprs_2 *>
			((void *)data);

		egprs2->usf    = rlc->usf;
		egprs2->es_p   = rlc->es_p;
		egprs2->rrbp   = rlc->rrbp;
		egprs2->tfi_hi = rlc->tfi >> 0; /* 1 bit LSB */
		egprs2->tfi_lo = rlc->tfi >> 1; /* 4 bits */
		egprs2->pr     = rlc->pr;
		egprs2->cps    = rlc->cps;

		egprs2->bsn1_hi  = rlc->block_info[0].bsn >> 0; /* 2 bits LSB */
		egprs2->bsn1_mid = rlc->block_info[0].bsn >> 2; /* 8 bits */
		egprs2->bsn1_lo  = rlc->block_info[0].bsn >> 10; /* 1 bit */

		e_fbi_header   = rlc->block_info[0].e       ? 0x01 : 0;
		e_fbi_header  |= rlc->block_info[0].cv == 0 ? 0x02 : 0; /* FBI */
		offs = rlc->data_offs_bits[0] / 8;
		OSMO_ASSERT(rlc->data_offs_bits[0] % 8 == 6);
		e_fbi_header <<= 4;
		data[offs] = (data[offs] & 0b11001111) | e_fbi_header;
		break;

	case HEADER_EGPRS_DATA_TYPE_3:
		egprs3 = static_cast<struct gprs_rlc_dl_header_egprs_3 *>
			((void *)data);

		egprs3->usf    = rlc->usf;
		egprs3->es_p   = rlc->es_p;
		egprs3->rrbp   = rlc->rrbp;
		egprs3->tfi_hi = rlc->tfi >> 0; /* 1 bit LSB */
		egprs3->tfi_lo = rlc->tfi >> 1; /* 4 bits */
		egprs3->pr     = rlc->pr;
		egprs3->cps    = rlc->cps;

		egprs3->bsn1_hi  = rlc->block_info[0].bsn >> 0; /* 2 bits LSB */
		egprs3->bsn1_mid = rlc->block_info[0].bsn >> 2; /* 8 bits */
		egprs3->bsn1_lo  = rlc->block_info[0].bsn >> 10; /* 1 bit */

		egprs3->spb    = rlc->block_info[0].spb;

		e_fbi_header   = rlc->block_info[0].e       ? 0x01 : 0;
		e_fbi_header  |= rlc->block_info[0].cv == 0 ? 0x02 : 0; /* FBI */
		offs = rlc->data_offs_bits[0] / 8;
		OSMO_ASSERT(rlc->data_offs_bits[0] % 8 == 1);
		e_fbi_header <<= 7;
		data[offs-1] = (data[offs-1] & 0b01111111) | (e_fbi_header >> 0);
		data[offs]   = (data[offs]   & 0b11111110) | (e_fbi_header >> 8);
		break;

	default:
		LOGP(DRLCMACDL, LOGL_ERROR,
			"Encoding of uplink %s data blocks not yet supported.\n",
			mcs_name(cs));
		return -ENOTSUP;
	};

	return 0;
}

/**
 * \brief Copy LSB bitstream RLC data block from byte aligned buffer.
 *
 * Note that the bitstream is encoded in LSB first order, so the two octets
 * 654321xx xxxxxx87 contain the octet 87654321 starting at bit position 3
 * (LSB has bit position 1). This is a different order than the one used by
 * CSN.1.
 *
 * \param data_block_idx  The block index, 0..1 for header type 1, 0 otherwise
 * \param src     A pointer to the start of the RLC block (incl. the header)
 * \param buffer  A data area of a least the size of the RLC block
 * \returns  the number of bytes copied
 */
unsigned int Encoding::rlc_copy_from_aligned_buffer(
	const struct gprs_rlc_data_info *rlc,
	unsigned int data_block_idx,
	uint8_t *dst, const uint8_t *buffer)
{
	unsigned int hdr_bytes;
	unsigned int extra_bits;
	unsigned int i;

	uint8_t c, last_c;
	const uint8_t *src;
	const struct gprs_rlc_data_block_info *rdbi;

	OSMO_ASSERT(data_block_idx < rlc->num_data_blocks);
	rdbi = &rlc->block_info[data_block_idx];

	hdr_bytes = rlc->data_offs_bits[data_block_idx] / 8;
	extra_bits = (rlc->data_offs_bits[data_block_idx] % 8);

	if (extra_bits == 0) {
		/* It is aligned already */
		memmove(dst + hdr_bytes, buffer, rdbi->data_len);
		return rdbi->data_len;
	}

	src = buffer;
	dst = dst + hdr_bytes;
	last_c = *dst << (8 - extra_bits);

	for (i = 0; i < rdbi->data_len; i++) {
		c = src[i];
		*(dst++) = (last_c >> (8 - extra_bits)) | (c << extra_bits);
		last_c = c;
	}

	/* overwrite the lower extra_bits */
	*dst = (*dst & (0xff << extra_bits)) | (last_c >> (8 - extra_bits));

	return rdbi->data_len;
}

/*!
 * \brief (GPRS) put llc pdu into an rlc/mac block. fragment the llc pdu if needed
 * \param rdbi rlc/mac block info
 * \param llc llc pdu
 * \param offset given offset within the rlc/mac block
 * \param num_chunks count the chunks (llc pdu data) within rlc/mac
 * \param data_block buffer holds rlc/mac data
 * \param is_final if this is the last rlc/mac within a TBF
 * \param count_payload if not NULL save the written size of payload in bytes into it
 * \return the state of the rlc/mac like if there is more space for another chunk
 */
static Encoding::AppendResult rlc_data_to_dl_append_gprs(
	struct gprs_rlc_data_block_info *rdbi,
	gprs_llc *llc, int *offset, int *num_chunks,
	uint8_t *data_block, bool is_final, int *count_payload)
{
	int chunk;
	int space;
	struct rlc_li_field *li;
	uint8_t *delimiter, *data, *e_pointer;

	data = data_block + *offset;
	delimiter = data_block + *num_chunks;
	e_pointer = (*num_chunks ? delimiter - 1 : NULL);

	chunk = llc_chunk_size(llc);
	space = rdbi->data_len - *offset;

	/* if chunk will exceed block limit */
	if (chunk > space) {
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d "
			"larger than space (%d) left in block: copy "
			"only remaining space, and we are done\n",
			chunk, space);
		if (e_pointer) {
			/* LLC frame not finished, so there is no extension octet */
			*e_pointer |= 0x02; /* set previous M bit = 1 */
		}
		/* fill only space */
		llc_consume_data(llc, data, space);
		if (count_payload)
			*count_payload = space;
		/* return data block as message */
		*offset = rdbi->data_len;
		(*num_chunks)++;
		return Encoding::AR_NEED_MORE_BLOCKS;
	}
	/* if FINAL chunk would fit precisely in space left */
	if (chunk == space && is_final)
	{
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d "
			"would exactly fit into space (%d): because "
			"this is a final block, we don't add length "
			"header, and we are done\n", chunk, space);
		/* block is filled, so there is no extension */
		if (e_pointer)
			*e_pointer |= 0x01;
		/* fill space */
		llc_consume_data(llc, data, space);
		if (count_payload)
			*count_payload = space;
		*offset = rdbi->data_len;
		(*num_chunks)++;
		rdbi->cv = 0;
		return Encoding::AR_COMPLETED_BLOCK_FILLED;
	}
	/* if chunk would fit exactly in space left */
	if (chunk == space) {
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d "
			"would exactly fit into space (%d): add length "
			"header with LI=0, to make frame extend to "
			"next block, and we are done\n", chunk, space);
		/* make space for delimiter */
		if (delimiter != data)
			memmove(delimiter + 1, delimiter,
				data - delimiter);
		if (e_pointer) {
			*e_pointer &= 0xfe; /* set previous E bit = 0 */
			*e_pointer |= 0x02; /* set previous M bit = 1 */
		}
		data++;
		(*offset)++;
		space--;
		/* add LI with 0 length */
		li = (struct rlc_li_field *)delimiter;
		li->e = 1; /* not more extension */
		li->m = 0; /* shall be set to 0, in case of li = 0 */
		li->li = 0; /* chunk fills the complete space */
		rdbi->e = 0; /* 0: extensions present */
		// no need to set e_pointer nor increase delimiter
		/* fill only space, which is 1 octet less than chunk */
		llc_consume_data(llc, data, space);
		if (count_payload)
			*count_payload = space;
		/* return data block as message */
		*offset = rdbi->data_len;
		(*num_chunks)++;
		return Encoding::AR_NEED_MORE_BLOCKS;
	}

	LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d is less "
		"than remaining space (%d): add length header to "
		"delimit LLC frame\n", chunk, space);
	/* the LLC frame chunk ends in this block */
	/* make space for delimiter */
	if (delimiter != data)
		memmove(delimiter + 1, delimiter, data - delimiter);
	if (e_pointer) {
		*e_pointer &= 0xfe; /* set previous E bit = 0 */
		*e_pointer |= 0x02; /* set previous M bit = 1 */
	}
	data++;
	(*offset)++;
	space--;
	/* add LI to delimit frame */
	li = (struct rlc_li_field *)delimiter;
	li->e = 1; /*  not more extension, maybe set later */
	li->m = 0; /* will be set later, if there is more LLC data */
	li->li = chunk; /* length of chunk */
	rdbi->e = 0; /* 0: extensions present */
	(*num_chunks)++;
	/* copy (rest of) LLC frame to space and reset later */
	llc_consume_data(llc, data, chunk);
	if (count_payload)
		*count_payload = chunk;
	data += chunk;
	space -= chunk;
	(*offset) += chunk;
	/* if we have more data and we have space left */
	if (space > 0 && !is_final)
		return Encoding::AR_COMPLETED_SPACE_LEFT;

	/* if we don't have more LLC frames */
	if (is_final) {
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Final block, so we "
			"done.\n");
		rdbi->cv = 0;
		return Encoding::AR_COMPLETED_BLOCK_FILLED;
	}
	/* we have no space left */
	LOGP(DRLCMACDL, LOGL_DEBUG, "-- No space left, so we are "
		"done.\n");
	return Encoding::AR_COMPLETED_BLOCK_FILLED;
}

/*!
 * \brief (EGPRS) put llc pdu into an rlc/mac block. fragment the llc pdu if needed
 * \param rdbi rlc/mac block info
 * \param llc llc pdu
 * \param offset given offset within the rlc/mac block
 * \param num_chunks count the chunks (llc pdu data) within rlc/mac
 * \param data_block buffer holds rlc/mac data
 * \param is_final if this is the last rlc/mac within a TBF
 * \param count_payload if not NULL save the written size of payload in bytes into it
 * \return the state of the rlc/mac like if there is more space for another chunk
 */
static Encoding::AppendResult rlc_data_to_dl_append_egprs(
	struct gprs_rlc_data_block_info *rdbi,
	gprs_llc *llc, int *offset, int *num_chunks,
	uint8_t *data_block,
	bool is_final, int *count_payload)
{
	int chunk;
	int space;
	struct rlc_li_field_egprs *li;
	struct rlc_li_field_egprs *prev_li;
	uint8_t *delimiter, *data;

	data = data_block + *offset;
	delimiter = data_block + *num_chunks;
	prev_li = (struct rlc_li_field_egprs *)
		(*num_chunks ? delimiter - 1 : NULL);

	chunk = llc_chunk_size(llc);
	space = rdbi->data_len - *offset;

	/* if chunk will exceed block limit */
	if (chunk > space) {
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d "
			"larger than space (%d) left in block: copy "
			"only remaining space, and we are done\n",
			chunk, space);
		/* fill only space */
		llc_consume_data(llc, data, space);
		if (count_payload)
			*count_payload = space;
		/* return data block as message */
		*offset = rdbi->data_len;
		(*num_chunks)++;
		return Encoding::AR_NEED_MORE_BLOCKS;
	}
	/* if FINAL chunk would fit precisely in space left */
	if (chunk == space && is_final)
	{
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d "
			"would exactly fit into space (%d): because "
			"this is a final block, we don't add length "
			"header, and we are done\n", chunk, space);
		/* fill space */
		llc_consume_data(llc, data, space);
		if (count_payload)
			*count_payload = space;
		*offset = rdbi->data_len;
		(*num_chunks)++;
		rdbi->cv = 0;
		return Encoding::AR_COMPLETED_BLOCK_FILLED;
	}
	/* if chunk would fit exactly in space left */
	if (chunk == space) {
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d "
			"would exactly fit into space (%d): just copy "
			"it, and we are done. The next block will have "
			"to start with an empty chunk\n",
			chunk, space);
		/* fill space */
		llc_consume_data(llc, data, space);
		if (count_payload)
			*count_payload = space;
		*offset = rdbi->data_len;
		(*num_chunks)++;
		return Encoding::AR_NEED_MORE_BLOCKS;
	}

	LOGP(DRLCMACDL, LOGL_DEBUG, "-- Chunk with length %d is less "
		"than remaining space (%d): add length header to "
		"to delimit LLC frame\n", chunk, space);
	/* the LLC frame chunk ends in this block */
	/* make space for delimiter */

	if (delimiter != data)
		memmove(delimiter + 1, delimiter, data - delimiter);

	data      += 1;
	(*offset) += 1;
	space     -= 1;
	/* add LI to delimit frame */
	li = (struct rlc_li_field_egprs *)delimiter;
	li->e = 1; /* not more extension, maybe set later */
	li->li = chunk; /* length of chunk */
	/* tell previous extension header about the new one */
	if (prev_li)
		prev_li->e = 0;
	rdbi->e = 0; /* 0: extensions present */
	delimiter++;
	prev_li = li;
	(*num_chunks)++;
	/* copy (rest of) LLC frame to space and reset later */
	llc_consume_data(llc, data, chunk);
	if (count_payload)
		*count_payload = chunk;
	data += chunk;
	space -= chunk;
	(*offset) += chunk;
	/* if we have more data and we have space left */
	if (!is_final) {
		if (space > 0) {
			return Encoding::AR_COMPLETED_SPACE_LEFT;
		} else {
			/* we have no space left */
			LOGP(DRLCMACDL, LOGL_DEBUG, "-- No space left, so we are "
				"done.\n");
			return Encoding::AR_COMPLETED_BLOCK_FILLED;
		}
	} else {
		/* we don't have more LLC frames */
		LOGP(DRLCMACDL, LOGL_DEBUG, "-- Final block, so we are done.\n");
		rdbi->cv = 0;
		if (space > 0)
			Encoding::rlc_data_to_dl_append_egprs_li_padding(rdbi,
									 offset,
									 num_chunks,
									 data_block);
		return Encoding::AR_COMPLETED_BLOCK_FILLED;
	}
}

/*!
 * \brief Encoding::rlc_data_to_dl_append
 * \param rdbi rlc/mac block info
 * \param cs the coding scheme to use
 * \param llc llc pdu
 * \param offset given offset within the rlc/mac block
 * \param num_chunks count the chunks (llc pdu data) within rlc/mac
 * \param data_block buffer holds rlc/mac data
 * \param is_final if this is the last rlc/mac within a TBF
 * \param count_payload if not NULL save the written size of payload in bytes into it
 * \return the state of the rlc/mac like if there is more space for another chunk
 */
Encoding::AppendResult Encoding::rlc_data_to_dl_append(
	struct gprs_rlc_data_block_info *rdbi, enum CodingScheme cs,
	gprs_llc *llc, int *offset, int *num_chunks,
	uint8_t *data_block, bool is_final, int *count_payload)
{
	if (mcs_is_gprs(cs))
		return rlc_data_to_dl_append_gprs(rdbi,
			llc, offset, num_chunks, data_block, is_final,
			count_payload);

	if (mcs_is_edge(cs))
		return rlc_data_to_dl_append_egprs(rdbi,
			llc, offset, num_chunks, data_block, is_final,
			count_payload);

	LOGP(DRLCMACDL, LOGL_ERROR, "%s data block encoding not implemented\n",
		mcs_name(cs));
	OSMO_ASSERT(mcs_is_valid(cs));

	return AR_NEED_MORE_BLOCKS;
}

void Encoding::rlc_data_to_dl_append_egprs_li_padding(
	const struct gprs_rlc_data_block_info *rdbi,
	int *offset, int *num_chunks, uint8_t *data_block)
{
	struct rlc_li_field_egprs *li;
	struct rlc_li_field_egprs *prev_li;
	uint8_t *delimiter, *data;

	LOGP(DRLCMACDL, LOGL_DEBUG, "Adding LI=127 to signal padding\n");

	data = data_block + *offset;
	delimiter = data_block + *num_chunks;
	prev_li = (struct rlc_li_field_egprs *)(*num_chunks ? delimiter - 1 : NULL);

	/* we don't have more LLC frames */
	/* We will have to add another chunk with filling octets */

	if (delimiter != data)
		memmove(delimiter + 1, delimiter, data - delimiter);

	/* set filling bytes extension */
	li = (struct rlc_li_field_egprs *)delimiter;
	li->e = 1;
	li->li = 127;

	/* tell previous extension header about the new one */
	if (prev_li)
		prev_li->e = 0;

	(*num_chunks)++;
	*offset = rdbi->data_len;
}

/*
 * Refer 44.060 version 7.27.0 Release 7
 * section 7.1.3.2.1 On receipt of a PACKET RESOURCE REQUEST message
 * 8.1.2.5 Establishment of uplink TBF
 */
void write_packet_access_reject(struct bitvec *dest, uint32_t tlli, unsigned long t3172_ms)
{
	unsigned wp = 0;

	bitvec_write_field(dest, &wp, 0x1, 2);  // Payload Type
	bitvec_write_field(dest, &wp, 0x0, 2);  // Uplink block with TDMA FN
	bitvec_write_field(dest, &wp, 0, 1);  // No Polling Bit
	bitvec_write_field(dest, &wp, 0x0, 3);  // Uplink state flag
	bitvec_write_field(dest, &wp,
				MT_PACKET_ACCESS_REJECT, 6);  // MESSAGE TYPE
	bitvec_write_field(dest, &wp, 0, 2); // fixed 00
	bitvec_write_field(dest, &wp, 0x0, 1);  //  TLLI / G-RNTI : bit (32)
	bitvec_write_field(dest, &wp, tlli, 32); // CONTENTION_RESOLUTION_TLLI
	bitvec_write_field(dest, &wp, 1, 1);  //  WAIT_INDICATION size in seconds

	/* WAIT_INDICATION, WAIT_INDICATION_SIZE */
	if (t3172_ms / 20 <= 255) { /* In units of 20 milliseconds */
		bitvec_write_field(dest, &wp, t3172_ms/20, 8);
		bitvec_write_field(dest, &wp, 1, 1);
	} else { /* value too big to fit in ms, do it in seconds */
		bitvec_write_field(dest, &wp, t3172_ms/1000, 8);
		bitvec_write_field(dest, &wp, 0, 1);
	}
}

void write_packet_neighbour_cell_data(RlcMacDownlink_t *block,
		bool tfi_is_dl, uint8_t tfi, uint8_t container_id,
		uint8_t container_idx, PNCDContainer_t *container)
{

	block->PAYLOAD_TYPE = 0x1;  // RLC/MAC control block that does not include the optional octets of the RLC/MAC control header
	block->RRBP         = 0;  // 0: N+13
	block->SP           = 0; // RRBP field is not valid
	block->USF          = 0x0;  // Uplink state flag

	block->u.Packet_Neighbour_Cell_Data.MESSAGE_TYPE = MT_PACKET_NEIGHBOUR_CELL_DATA;
	block->u.Packet_Neighbour_Cell_Data.PAGE_MODE    = 0x0;  // Normal Paging

	block->u.Packet_Neighbour_Cell_Data.Global_TFI.UnionType = tfi_is_dl; // 0=UPLINK TFI, 1=DL TFI
	if (tfi_is_dl) {
		block->u.Packet_Neighbour_Cell_Data.Global_TFI.u.DOWNLINK_TFI = tfi;
	} else {
		block->u.Packet_Neighbour_Cell_Data.Global_TFI.u.UPLINK_TFI = tfi;
	}
	block->u.Packet_Neighbour_Cell_Data.CONTAINER_ID = container_id;
	block->u.Packet_Neighbour_Cell_Data.spare = 0;
	block->u.Packet_Neighbour_Cell_Data.CONTAINER_INDEX = container_idx;
	block->u.Packet_Neighbour_Cell_Data.Container = *container;
}

void write_packet_cell_change_continue(RlcMacDownlink_t *block, uint8_t poll, uint8_t rrbp,
				       bool tfi_is_dl, uint8_t tfi, bool exist_id,
				       uint16_t arfcn, uint8_t bsic, uint8_t container_id)
{

	block->PAYLOAD_TYPE = 0x1;  // RLC/MAC control block that does not include the optional octets of the RLC/MAC control header
	block->RRBP         = rrbp;  // RRBP (e.g. N+13)
	block->SP           = poll;  // RRBP field is valid?
	block->USF          = 0x0;  // Uplink state flag

	block->u.Packet_Cell_Change_Continue.MESSAGE_TYPE = MT_PACKET_CELL_CHANGE_CONTINUE;
	block->u.Packet_Cell_Change_Continue.PAGE_MODE    = 0x0;  // Normal Paging

	block->u.Packet_Cell_Change_Continue.Global_TFI.UnionType = tfi_is_dl; // 0=UPLINK TFI, 1=DL TFI
	if (tfi_is_dl) {
		block->u.Packet_Cell_Change_Continue.Global_TFI.u.DOWNLINK_TFI = tfi;
	} else {
		block->u.Packet_Cell_Change_Continue.Global_TFI.u.UPLINK_TFI = tfi;
	}

	block->u.Packet_Cell_Change_Continue.Exist_ID = exist_id;
	if (exist_id) {
		block->u.Packet_Cell_Change_Continue.ARFCN = arfcn;
		block->u.Packet_Cell_Change_Continue.BSIC = bsic;
	}
	block->u.Packet_Cell_Change_Continue.CONTAINER_ID = container_id;
}