blob: c41fd3d8efc5405ba9ec3ca6bef5a044bda66cdb [file] [log] [blame]
/******************************************************************************
*
* Copyright (C) 1999-2012 Broadcom Corporation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
******************************************************************************/
#ifndef BT_TYPES_H
#define BT_TYPES_H
#include <stdbool.h>
#include <stdint.h>
#include <string.h>
#ifndef FALSE
#define FALSE false
#endif
#ifndef TRUE
#define TRUE true
#endif
#ifdef __arm
#define PACKED __packed
#define INLINE __inline
#else
#define PACKED
#define INLINE
#endif
/* READ WELL !!
*
* This section defines global events. These are events that cross layers.
* Any event that passes between layers MUST be one of these events. Tasks
* can use their own events internally, but a FUNDAMENTAL design issue is
* that global events MUST be one of these events defined below.
*
* The convention used is the the event name contains the layer that the
* event is going to.
*/
#define BT_EVT_MASK 0xFF00
#define BT_SUB_EVT_MASK 0x00FF
/* To Bluetooth Upper Layers */
/************************************/
/* L2CAP event */
#define BT_EVT_TO_BTU_L2C_EVT 0x0900
/* HCI Event */
#define BT_EVT_TO_BTU_HCI_EVT 0x1000
/* event from BR/EDR controller */
#define BT_EVT_TO_BTU_HCI_BR_EDR_EVT (0x0000 | BT_EVT_TO_BTU_HCI_EVT)
/* event from local AMP 1 controller */
#define BT_EVT_TO_BTU_HCI_AMP1_EVT (0x0001 | BT_EVT_TO_BTU_HCI_EVT)
/* event from local AMP 2 controller */
#define BT_EVT_TO_BTU_HCI_AMP2_EVT (0x0002 | BT_EVT_TO_BTU_HCI_EVT)
/* event from local AMP 3 controller */
#define BT_EVT_TO_BTU_HCI_AMP3_EVT (0x0003 | BT_EVT_TO_BTU_HCI_EVT)
/* ACL Data from HCI */
#define BT_EVT_TO_BTU_HCI_ACL 0x1100
/* SCO Data from HCI */
#define BT_EVT_TO_BTU_HCI_SCO 0x1200
/* HCI Transport Error */
#define BT_EVT_TO_BTU_HCIT_ERR 0x1300
/* Serial Port Event */
#define BT_EVT_TO_BTU_SP_EVT 0x1400
/* Serial Port Data */
#define BT_EVT_TO_BTU_SP_DATA 0x1500
/* HCI command from upper layer */
#define BT_EVT_TO_BTU_HCI_CMD 0x1600
/* L2CAP segment(s) transmitted */
#define BT_EVT_TO_BTU_L2C_SEG_XMIT 0x1900
/* BlueStackTester event: incoming message from target */
#define BT_EVT_PROXY_INCOMING_MSG 0x1A00
/* Insight BTSIM event */
#define BT_EVT_BTSIM 0x1B00
/* Insight Script Engine event */
#define BT_EVT_BTISE 0x1C00
/* To LM */
/************************************/
/* HCI Command */
#define BT_EVT_TO_LM_HCI_CMD 0x2000
/* HCI ACL Data */
#define BT_EVT_TO_LM_HCI_ACL 0x2100
/* HCI SCO Data */
#define BT_EVT_TO_LM_HCI_SCO 0x2200
/* HCI Transport Error */
#define BT_EVT_TO_LM_HCIT_ERR 0x2300
/* LC event */
#define BT_EVT_TO_LM_LC_EVT 0x2400
/* LC Received LMP command frame */
#define BT_EVT_TO_LM_LC_LMP 0x2500
/* LC Received ACL data */
#define BT_EVT_TO_LM_LC_ACL 0x2600
/* LC Received SCO data (not used) */
#define BT_EVT_TO_LM_LC_SCO 0x2700
/* LMP data transmit complete */
#define BT_EVT_TO_LM_LC_ACL_TX 0x2800
/* LMP Command transmit complete */
#define BT_EVT_TO_LM_LC_LMPC_TX 0x2900
/* Data to be locally loopbacked */
#define BT_EVT_TO_LM_LOCAL_ACL_LB 0x2a00
/* HCI ACL Data ack (not used) */
#define BT_EVT_TO_LM_HCI_ACL_ACK 0x2b00
/* LM Diagnostics commands */
#define BT_EVT_TO_LM_DIAG 0x2c00
#define BT_EVT_TO_BTM_CMDS 0x2f00
#define BT_EVT_TO_BTM_PM_MDCHG_EVT (0x0001 | BT_EVT_TO_BTM_CMDS)
#define BT_EVT_TO_TCS_CMDS 0x3000
#define BT_EVT_TO_CTP_CMDS 0x3300
/* ftp events */
#define BT_EVT_TO_FTP_SRVR_CMDS 0x3600
#define BT_EVT_TO_FTP_CLNT_CMDS 0x3700
/* SIM Access Profile events */
#define BT_EVT_TO_BTU_SAP 0x3800
/* opp events */
#define BT_EVT_TO_OPP_SRVR_CMDS 0x3900
#define BT_EVT_TO_OPP_CLNT_CMDS 0x3a00
/* gap events */
#define BT_EVT_TO_GAP_MSG 0x3b00
/* for NFC */
/************************************/
/* NCI Command, Notification or Data*/
#define BT_EVT_TO_NFC_NCI 0x4000
/* Initialization message */
#define BT_EVT_TO_NFC_INIT 0x4100
/* Low power */
#define BT_EVT_TO_NCI_LP 0x4200
/* Error notification to NFC Task */
#define BT_EVT_TO_NFC_ERR 0x4300
/* events to NFCC simulation (NCI packets) */
#define BT_EVT_TO_NFCCSIM_NCI 0x4a00
/* HCISU Events */
#define BT_EVT_HCISU 0x5000
#define BT_EVT_TO_HCISU_RECONFIG_EVT (0x0001 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_UPDATE_BAUDRATE_EVT (0x0002 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_LP_ENABLE_EVT (0x0003 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_LP_DISABLE_EVT (0x0004 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_LP_APP_SLEEPING_EVT (0x0005 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_LP_ALLOW_BT_SLEEP_EVT (0x0006 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_LP_WAKEUP_HOST_EVT (0x0007 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_LP_RCV_H4IBSS_EVT (0x0008 | BT_EVT_HCISU)
#define BT_EVT_TO_HCISU_H5_RESET_EVT (0x0009 | BT_EVT_HCISU)
#define BT_EVT_HCISU_START_QUICK_TIMER (0x000a | BT_EVT_HCISU)
#define BT_EVT_DATA_TO_AMP_1 0x5100
#define BT_EVT_DATA_TO_AMP_15 0x5f00
/* HSP Events */
#define BT_EVT_BTU_HSP2 0x6000
#define BT_EVT_TO_BTU_HSP2_EVT (0x0001 | BT_EVT_BTU_HSP2)
/* BPP Events */
#define BT_EVT_TO_BPP_PR_CMDS 0x6100 /* Printer Events */
#define BT_EVT_TO_BPP_SND_CMDS 0x6200 /* BPP Sender Events */
/* BIP Events */
#define BT_EVT_TO_BIP_CMDS 0x6300
/* HCRP Events */
#define BT_EVT_BTU_HCRP 0x7000
#define BT_EVT_TO_BTU_HCRP_EVT (0x0001 | BT_EVT_BTU_HCRP)
#define BT_EVT_TO_BTU_HCRPM_EVT (0x0002 | BT_EVT_BTU_HCRP)
#define BT_EVT_BTU_HFP 0x8000
#define BT_EVT_TO_BTU_HFP_EVT (0x0001 | BT_EVT_BTU_HFP)
#define BT_EVT_BTU_IPC_EVT 0x9000
#define BT_EVT_BTU_IPC_LOGMSG_EVT (0x0000 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_ACL_EVT (0x0001 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_BTU_EVT (0x0002 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_L2C_EVT (0x0003 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_L2C_MSG_EVT (0x0004 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_BTM_EVT (0x0005 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_AVDT_EVT (0x0006 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_SLIP_EVT (0x0007 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_MGMT_EVT (0x0008 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_BTTRC_EVT (0x0009 | BT_EVT_BTU_IPC_EVT)
#define BT_EVT_BTU_IPC_BURST_EVT (0x000A | BT_EVT_BTU_IPC_EVT)
/* BTIF Events */
#define BT_EVT_BTIF 0xA000
#define BT_EVT_CONTEXT_SWITCH_EVT (0x0001 | BT_EVT_BTIF)
/* Define the header of each buffer used in the Bluetooth stack.
*/
typedef struct {
uint16_t event;
uint16_t len;
uint16_t offset;
uint16_t layer_specific;
uint8_t data[];
} BT_HDR;
#define BT_HDR_SIZE (sizeof(BT_HDR))
#define BT_PSM_SDP 0x0001
#define BT_PSM_RFCOMM 0x0003
#define BT_PSM_TCS 0x0005
#define BT_PSM_CTP 0x0007
#define BT_PSM_BNEP 0x000F
#define BT_PSM_HIDC 0x0011
#define BT_PSM_HIDI 0x0013
#define BT_PSM_UPNP 0x0015
#define BT_PSM_AVCTP 0x0017
#define BT_PSM_AVDTP 0x0019
#define BT_PSM_AVCTP_13 0x001B /* Advanced Control - Browsing */
#define BT_PSM_UDI_CP \
0x001D /* Unrestricted Digital Information Profile C-Plane */
#define BT_PSM_ATT 0x001F /* Attribute Protocol */
/* These macros extract the HCI opcodes from a buffer
*/
#define HCI_GET_CMD_HDR_OPCODE(p) \
(uint16_t)((*((uint8_t*)((p) + 1) + (p)->offset) + \
(*((uint8_t*)((p) + 1) + (p)->offset + 1) << 8)))
#define HCI_GET_CMD_HDR_PARAM_LEN(p) \
(uint8_t)(*((uint8_t*)((p) + 1) + (p)->offset + 2))
#define HCI_GET_EVT_HDR_OPCODE(p) \
(uint8_t)(*((uint8_t*)((p) + 1) + (p)->offset))
#define HCI_GET_EVT_HDR_PARAM_LEN(p) \
(uint8_t)(*((uint8_t*)((p) + 1) + (p)->offset + 1))
/*******************************************************************************
* Macros to get and put bytes to and from a stream (Little Endian format).
*/
#define UINT64_TO_BE_STREAM(p, u64) \
{ \
*(p)++ = (uint8_t)((u64) >> 56); \
*(p)++ = (uint8_t)((u64) >> 48); \
*(p)++ = (uint8_t)((u64) >> 40); \
*(p)++ = (uint8_t)((u64) >> 32); \
*(p)++ = (uint8_t)((u64) >> 24); \
*(p)++ = (uint8_t)((u64) >> 16); \
*(p)++ = (uint8_t)((u64) >> 8); \
*(p)++ = (uint8_t)(u64); \
}
#define UINT32_TO_STREAM(p, u32) \
{ \
*(p)++ = (uint8_t)(u32); \
*(p)++ = (uint8_t)((u32) >> 8); \
*(p)++ = (uint8_t)((u32) >> 16); \
*(p)++ = (uint8_t)((u32) >> 24); \
}
#define UINT24_TO_STREAM(p, u24) \
{ \
*(p)++ = (uint8_t)(u24); \
*(p)++ = (uint8_t)((u24) >> 8); \
*(p)++ = (uint8_t)((u24) >> 16); \
}
#define UINT16_TO_STREAM(p, u16) \
{ \
*(p)++ = (uint8_t)(u16); \
*(p)++ = (uint8_t)((u16) >> 8); \
}
#define UINT8_TO_STREAM(p, u8) \
{ *(p)++ = (uint8_t)(u8); }
#define INT8_TO_STREAM(p, u8) \
{ *(p)++ = (int8_t)(u8); }
#define ARRAY32_TO_STREAM(p, a) \
{ \
int ijk; \
for (ijk = 0; ijk < 32; ijk++) *(p)++ = (uint8_t)(a)[31 - ijk]; \
}
#define ARRAY16_TO_STREAM(p, a) \
{ \
int ijk; \
for (ijk = 0; ijk < 16; ijk++) *(p)++ = (uint8_t)(a)[15 - ijk]; \
}
#define ARRAY8_TO_STREAM(p, a) \
{ \
int ijk; \
for (ijk = 0; ijk < 8; ijk++) *(p)++ = (uint8_t)(a)[7 - ijk]; \
}
#define BDADDR_TO_STREAM(p, a) \
{ \
int ijk; \
for (ijk = 0; ijk < BD_ADDR_LEN; ijk++) \
*(p)++ = (uint8_t)(a)[BD_ADDR_LEN - 1 - ijk]; \
}
#define LAP_TO_STREAM(p, a) \
{ \
int ijk; \
for (ijk = 0; ijk < LAP_LEN; ijk++) \
*(p)++ = (uint8_t)(a)[LAP_LEN - 1 - ijk]; \
}
#define DEVCLASS_TO_STREAM(p, a) \
{ \
int ijk; \
for (ijk = 0; ijk < DEV_CLASS_LEN; ijk++) \
*(p)++ = (uint8_t)(a)[DEV_CLASS_LEN - 1 - ijk]; \
}
#define ARRAY_TO_STREAM(p, a, len) \
{ \
int ijk; \
for (ijk = 0; ijk < (len); ijk++) *(p)++ = (uint8_t)(a)[ijk]; \
}
#define REVERSE_ARRAY_TO_STREAM(p, a, len) \
{ \
int ijk; \
for (ijk = 0; ijk < (len); ijk++) *(p)++ = (uint8_t)(a)[(len)-1 - ijk]; \
}
#define STREAM_TO_INT8(u8, p) \
{ \
(u8) = (*((int8_t*)p)); \
(p) += 1; \
}
#define STREAM_TO_UINT8(u8, p) \
{ \
(u8) = (uint8_t)(*(p)); \
(p) += 1; \
}
#define STREAM_TO_UINT16(u16, p) \
{ \
(u16) = ((uint16_t)(*(p)) + (((uint16_t)(*((p) + 1))) << 8)); \
(p) += 2; \
}
#define STREAM_TO_UINT24(u32, p) \
{ \
(u32) = (((uint32_t)(*(p))) + ((((uint32_t)(*((p) + 1)))) << 8) + \
((((uint32_t)(*((p) + 2)))) << 16)); \
(p) += 3; \
}
#define STREAM_TO_UINT32(u32, p) \
{ \
(u32) = (((uint32_t)(*(p))) + ((((uint32_t)(*((p) + 1)))) << 8) + \
((((uint32_t)(*((p) + 2)))) << 16) + \
((((uint32_t)(*((p) + 3)))) << 24)); \
(p) += 4; \
}
#define STREAM_TO_BDADDR(a, p) \
{ \
int ijk; \
uint8_t* pbda = (uint8_t*)(a) + BD_ADDR_LEN - 1; \
for (ijk = 0; ijk < BD_ADDR_LEN; ijk++) *pbda-- = *(p)++; \
}
#define STREAM_TO_ARRAY32(a, p) \
{ \
int ijk; \
uint8_t* _pa = (uint8_t*)(a) + 31; \
for (ijk = 0; ijk < 32; ijk++) *_pa-- = *(p)++; \
}
#define STREAM_TO_ARRAY16(a, p) \
{ \
int ijk; \
uint8_t* _pa = (uint8_t*)(a) + 15; \
for (ijk = 0; ijk < 16; ijk++) *_pa-- = *(p)++; \
}
#define STREAM_TO_ARRAY8(a, p) \
{ \
int ijk; \
uint8_t* _pa = (uint8_t*)(a) + 7; \
for (ijk = 0; ijk < 8; ijk++) *_pa-- = *(p)++; \
}
#define STREAM_TO_DEVCLASS(a, p) \
{ \
int ijk; \
uint8_t* _pa = (uint8_t*)(a) + DEV_CLASS_LEN - 1; \
for (ijk = 0; ijk < DEV_CLASS_LEN; ijk++) *_pa-- = *(p)++; \
}
#define STREAM_TO_LAP(a, p) \
{ \
int ijk; \
uint8_t* plap = (uint8_t*)(a) + LAP_LEN - 1; \
for (ijk = 0; ijk < LAP_LEN; ijk++) *plap-- = *(p)++; \
}
#define STREAM_TO_ARRAY(a, p, len) \
{ \
int ijk; \
for (ijk = 0; ijk < (len); ijk++) ((uint8_t*)(a))[ijk] = *(p)++; \
}
#define REVERSE_STREAM_TO_ARRAY(a, p, len) \
{ \
int ijk; \
uint8_t* _pa = (uint8_t*)(a) + (len)-1; \
for (ijk = 0; ijk < (len); ijk++) *_pa-- = *(p)++; \
}
#define STREAM_SKIP_UINT8(p) \
do { \
(p) += 1; \
} while (0)
#define STREAM_SKIP_UINT16(p) \
do { \
(p) += 2; \
} while (0)
/*******************************************************************************
* Macros to get and put bytes to and from a field (Little Endian format).
* These are the same as to stream, except the pointer is not incremented.
*/
#define UINT32_TO_FIELD(p, u32) \
{ \
*(uint8_t*)(p) = (uint8_t)(u32); \
*((uint8_t*)(p) + 1) = (uint8_t)((u32) >> 8); \
*((uint8_t*)(p) + 2) = (uint8_t)((u32) >> 16); \
*((uint8_t*)(p) + 3) = (uint8_t)((u32) >> 24); \
}
#define UINT24_TO_FIELD(p, u24) \
{ \
*(uint8_t*)(p) = (uint8_t)(u24); \
*((uint8_t*)(p) + 1) = (uint8_t)((u24) >> 8); \
*((uint8_t*)(p) + 2) = (uint8_t)((u24) >> 16); \
}
#define UINT16_TO_FIELD(p, u16) \
{ \
*(uint8_t*)(p) = (uint8_t)(u16); \
*((uint8_t*)(p) + 1) = (uint8_t)((u16) >> 8); \
}
#define UINT8_TO_FIELD(p, u8) \
{ *(uint8_t*)(p) = (uint8_t)(u8); }
/*******************************************************************************
* Macros to get and put bytes to and from a stream (Big Endian format)
*/
#define UINT32_TO_BE_STREAM(p, u32) \
{ \
*(p)++ = (uint8_t)((u32) >> 24); \
*(p)++ = (uint8_t)((u32) >> 16); \
*(p)++ = (uint8_t)((u32) >> 8); \
*(p)++ = (uint8_t)(u32); \
}
#define UINT24_TO_BE_STREAM(p, u24) \
{ \
*(p)++ = (uint8_t)((u24) >> 16); \
*(p)++ = (uint8_t)((u24) >> 8); \
*(p)++ = (uint8_t)(u24); \
}
#define UINT16_TO_BE_STREAM(p, u16) \
{ \
*(p)++ = (uint8_t)((u16) >> 8); \
*(p)++ = (uint8_t)(u16); \
}
#define UINT8_TO_BE_STREAM(p, u8) \
{ *(p)++ = (uint8_t)(u8); }
#define ARRAY_TO_BE_STREAM(p, a, len) \
{ \
int ijk; \
for (ijk = 0; ijk < (len); ijk++) *(p)++ = (uint8_t)(a)[ijk]; \
}
#define ARRAY_TO_BE_STREAM_REVERSE(p, a, len) \
{ \
int ijk; \
for (ijk = 0; ijk < (len); ijk++) *(p)++ = (uint8_t)(a)[(len)-ijk - 1]; \
}
#define BE_STREAM_TO_UINT8(u8, p) \
{ \
(u8) = (uint8_t)(*(p)); \
(p) += 1; \
}
#define BE_STREAM_TO_UINT16(u16, p) \
{ \
(u16) = (uint16_t)(((uint16_t)(*(p)) << 8) + (uint16_t)(*((p) + 1))); \
(p) += 2; \
}
#define BE_STREAM_TO_UINT24(u32, p) \
{ \
(u32) = (((uint32_t)(*((p) + 2))) + ((uint32_t)(*((p) + 1)) << 8) + \
((uint32_t)(*(p)) << 16)); \
(p) += 3; \
}
#define BE_STREAM_TO_UINT32(u32, p) \
{ \
(u32) = ((uint32_t)(*((p) + 3)) + ((uint32_t)(*((p) + 2)) << 8) + \
((uint32_t)(*((p) + 1)) << 16) + ((uint32_t)(*(p)) << 24)); \
(p) += 4; \
}
#define BE_STREAM_TO_UINT64(u64, p) \
{ \
(u64) = ((uint64_t)(*((p) + 7)) + ((uint64_t)(*((p) + 6)) << 8) + \
((uint64_t)(*((p) + 5)) << 16) + ((uint64_t)(*((p) + 4)) << 24) + \
((uint64_t)(*((p) + 3)) << 32) + ((uint64_t)(*((p) + 2)) << 40) + \
((uint64_t)(*((p) + 1)) << 48) + ((uint64_t)(*(p)) << 56)); \
(p) += 8; \
}
#define BE_STREAM_TO_ARRAY(p, a, len) \
{ \
int ijk; \
for (ijk = 0; ijk < (len); ijk++) ((uint8_t*)(a))[ijk] = *(p)++; \
}
/*******************************************************************************
* Macros to get and put bytes to and from a field (Big Endian format).
* These are the same as to stream, except the pointer is not incremented.
*/
#define UINT32_TO_BE_FIELD(p, u32) \
{ \
*(uint8_t*)(p) = (uint8_t)((u32) >> 24); \
*((uint8_t*)(p) + 1) = (uint8_t)((u32) >> 16); \
*((uint8_t*)(p) + 2) = (uint8_t)((u32) >> 8); \
*((uint8_t*)(p) + 3) = (uint8_t)(u32); \
}
#define UINT24_TO_BE_FIELD(p, u24) \
{ \
*(uint8_t*)(p) = (uint8_t)((u24) >> 16); \
*((uint8_t*)(p) + 1) = (uint8_t)((u24) >> 8); \
*((uint8_t*)(p) + 2) = (uint8_t)(u24); \
}
#define UINT16_TO_BE_FIELD(p, u16) \
{ \
*(uint8_t*)(p) = (uint8_t)((u16) >> 8); \
*((uint8_t*)(p) + 1) = (uint8_t)(u16); \
}
#define UINT8_TO_BE_FIELD(p, u8) \
{ *(uint8_t*)(p) = (uint8_t)(u8); }
/* Common Bluetooth field definitions */
#define BD_ADDR_LEN 6 /* Device address length */
typedef uint8_t BD_ADDR[BD_ADDR_LEN]; /* Device address */
typedef uint8_t* BD_ADDR_PTR; /* Pointer to Device Address */
#define AMP_KEY_TYPE_GAMP 0
#define AMP_KEY_TYPE_WIFI 1
#define AMP_KEY_TYPE_UWB 2
typedef uint8_t tAMP_KEY_TYPE;
#define BT_OCTET8_LEN 8
typedef uint8_t BT_OCTET8[BT_OCTET8_LEN]; /* octet array: size 16 */
#define LINK_KEY_LEN 16
typedef uint8_t LINK_KEY[LINK_KEY_LEN]; /* Link Key */
#define AMP_LINK_KEY_LEN 32
typedef uint8_t
AMP_LINK_KEY[AMP_LINK_KEY_LEN]; /* Dedicated AMP and GAMP Link Keys */
#define BT_OCTET16_LEN 16
typedef uint8_t BT_OCTET16[BT_OCTET16_LEN]; /* octet array: size 16 */
#define PIN_CODE_LEN 16
typedef uint8_t PIN_CODE[PIN_CODE_LEN]; /* Pin Code (upto 128 bits) MSB is 0 */
typedef uint8_t* PIN_CODE_PTR; /* Pointer to Pin Code */
#define BT_OCTET32_LEN 32
typedef uint8_t BT_OCTET32[BT_OCTET32_LEN]; /* octet array: size 32 */
#define DEV_CLASS_LEN 3
typedef uint8_t DEV_CLASS[DEV_CLASS_LEN]; /* Device class */
typedef uint8_t* DEV_CLASS_PTR; /* Pointer to Device class */
#define EXT_INQ_RESP_LEN 3
typedef uint8_t EXT_INQ_RESP[EXT_INQ_RESP_LEN]; /* Extended Inquiry Response */
typedef uint8_t* EXT_INQ_RESP_PTR; /* Pointer to Extended Inquiry Response */
#define BD_NAME_LEN 248
typedef uint8_t BD_NAME[BD_NAME_LEN + 1]; /* Device name */
typedef uint8_t* BD_NAME_PTR; /* Pointer to Device name */
#define BD_FEATURES_LEN 8
typedef uint8_t
BD_FEATURES[BD_FEATURES_LEN]; /* LMP features supported by device */
#define BT_EVENT_MASK_LEN 8
typedef uint8_t BT_EVENT_MASK[BT_EVENT_MASK_LEN]; /* Event Mask */
#define LAP_LEN 3
typedef uint8_t LAP[LAP_LEN]; /* IAC as passed to Inquiry (LAP) */
typedef uint8_t INQ_LAP[LAP_LEN]; /* IAC as passed to Inquiry (LAP) */
#define RAND_NUM_LEN 16
typedef uint8_t RAND_NUM[RAND_NUM_LEN];
#define ACO_LEN 12
typedef uint8_t ACO[ACO_LEN]; /* Authenticated ciphering offset */
#define COF_LEN 12
typedef uint8_t COF[COF_LEN]; /* ciphering offset number */
typedef struct {
uint8_t qos_flags; /* TBD */
uint8_t service_type; /* see below */
uint32_t token_rate; /* bytes/second */
uint32_t token_bucket_size; /* bytes */
uint32_t peak_bandwidth; /* bytes/second */
uint32_t latency; /* microseconds */
uint32_t delay_variation; /* microseconds */
} FLOW_SPEC;
/* Values for service_type */
#define NO_TRAFFIC 0
#define BEST_EFFORT 1
#define GUARANTEED 2
/* Service class of the CoD */
#define SERV_CLASS_NETWORKING (1 << 1)
#define SERV_CLASS_RENDERING (1 << 2)
#define SERV_CLASS_CAPTURING (1 << 3)
#define SERV_CLASS_OBJECT_TRANSFER (1 << 4)
#define SERV_CLASS_OBJECT_AUDIO (1 << 5)
#define SERV_CLASS_OBJECT_TELEPHONY (1 << 6)
#define SERV_CLASS_OBJECT_INFORMATION (1 << 7)
/* Second byte */
#define SERV_CLASS_LIMITED_DISC_MODE (0x20)
/* Field size definitions. Note that byte lengths are rounded up. */
#define ACCESS_CODE_BIT_LEN 72
#define ACCESS_CODE_BYTE_LEN 9
#define SHORTENED_ACCESS_CODE_BIT_LEN 68
typedef uint8_t ACCESS_CODE[ACCESS_CODE_BYTE_LEN];
#define SYNTH_TX 1 /* want synth code to TRANSMIT at this freq */
#define SYNTH_RX 2 /* want synth code to RECEIVE at this freq */
#define SYNC_REPS 1 /* repeats of sync word transmitted to start of burst */
#define BT_1SEC_TIMEOUT_MS (1 * 1000) /* 1 second */
/* Maximum UUID size - 16 bytes, and structure to hold any type of UUID. */
#define MAX_UUID_SIZE 16
typedef struct {
#define LEN_UUID_16 2
#define LEN_UUID_32 4
#define LEN_UUID_128 16
uint16_t len;
union {
uint16_t uuid16;
uint32_t uuid32;
uint8_t uuid128[MAX_UUID_SIZE];
} uu;
} tBT_UUID;
#define BT_EIR_FLAGS_TYPE 0x01
#define BT_EIR_MORE_16BITS_UUID_TYPE 0x02
#define BT_EIR_COMPLETE_16BITS_UUID_TYPE 0x03
#define BT_EIR_MORE_32BITS_UUID_TYPE 0x04
#define BT_EIR_COMPLETE_32BITS_UUID_TYPE 0x05
#define BT_EIR_MORE_128BITS_UUID_TYPE 0x06
#define BT_EIR_COMPLETE_128BITS_UUID_TYPE 0x07
#define BT_EIR_SHORTENED_LOCAL_NAME_TYPE 0x08
#define BT_EIR_COMPLETE_LOCAL_NAME_TYPE 0x09
#define BT_EIR_TX_POWER_LEVEL_TYPE 0x0A
#define BT_EIR_OOB_BD_ADDR_TYPE 0x0C
#define BT_EIR_OOB_COD_TYPE 0x0D
#define BT_EIR_OOB_SSP_HASH_C_TYPE 0x0E
#define BT_EIR_OOB_SSP_RAND_R_TYPE 0x0F
#define BT_EIR_SERVICE_DATA_TYPE 0x16
#define BT_EIR_SERVICE_DATA_16BITS_UUID_TYPE 0x16
#define BT_EIR_SERVICE_DATA_32BITS_UUID_TYPE 0x20
#define BT_EIR_SERVICE_DATA_128BITS_UUID_TYPE 0x21
#define BT_EIR_MANUFACTURER_SPECIFIC_TYPE 0xFF
#define BT_OOB_COD_SIZE 3
#define BT_OOB_HASH_C_SIZE 16
#define BT_OOB_RAND_R_SIZE 16
/* Broadcom proprietary UUIDs and reserved PSMs
*
* The lowest 4 bytes byte of the UUID or GUID depend on the feature. Typically,
* the value of those bytes will be the PSM or SCN.
*/
#define BRCM_PROPRIETARY_UUID_BASE \
0xDA, 0x23, 0x41, 0x02, 0xA3, 0xBB, 0xC1, 0x71, 0xBA, 0x09, 0x6f, 0x21
#define BRCM_PROPRIETARY_GUID_BASE \
0xda23, 0x4102, 0xa3, 0xbb, 0xc1, 0x71, 0xba, 0x09, 0x6f, 0x21
/* We will not allocate a PSM in the reserved range to 3rd party apps
*/
#define BRCM_RESERVED_PSM_START 0x5AE1
#define BRCM_RESERVED_PSM_END 0x5AFF
#define BRCM_UTILITY_SERVICE_PSM 0x5AE1
#define BRCM_MATCHER_PSM 0x5AE3
/* Connection statistics
*/
/* Structure to hold connection stats */
#ifndef BT_CONN_STATS_DEFINED
#define BT_CONN_STATS_DEFINED
/* These bits are used in the bIsConnected field */
#define BT_CONNECTED_USING_BREDR 1
#define BT_CONNECTED_USING_AMP 2
typedef struct {
uint32_t is_connected;
int32_t rssi;
uint32_t bytes_sent;
uint32_t bytes_rcvd;
uint32_t duration;
} tBT_CONN_STATS;
#endif
/*****************************************************************************
* Low Energy definitions
*
* Address types
*/
#define BLE_ADDR_PUBLIC 0x00
#define BLE_ADDR_RANDOM 0x01
#define BLE_ADDR_PUBLIC_ID 0x02
#define BLE_ADDR_RANDOM_ID 0x03
typedef uint8_t tBLE_ADDR_TYPE;
#define BLE_ADDR_TYPE_MASK (BLE_ADDR_RANDOM | BLE_ADDR_PUBLIC)
#define BT_TRANSPORT_INVALID 0
#define BT_TRANSPORT_BR_EDR 1
#define BT_TRANSPORT_LE 2
typedef uint8_t tBT_TRANSPORT;
#define PHY_LE_1M_MASK 1
#define PHY_LE_2M_MASK 2
#define PHY_LE_CODED_MASK 4
#define BLE_ADDR_IS_STATIC(x) (((x)[0] & 0xC0) == 0xC0)
typedef struct {
tBLE_ADDR_TYPE type;
BD_ADDR bda;
} tBLE_BD_ADDR;
/* Device Types
*/
#define BT_DEVICE_TYPE_BREDR 0x01
#define BT_DEVICE_TYPE_BLE 0x02
#define BT_DEVICE_TYPE_DUMO 0x03
typedef uint8_t tBT_DEVICE_TYPE;
/*****************************************************************************/
/* Define trace levels */
#define BT_TRACE_LEVEL_NONE 0 /* No trace messages to be generated */
#define BT_TRACE_LEVEL_ERROR 1 /* Error condition trace messages */
#define BT_TRACE_LEVEL_WARNING 2 /* Warning condition trace messages */
#define BT_TRACE_LEVEL_API 3 /* API traces */
#define BT_TRACE_LEVEL_EVENT 4 /* Debug messages for events */
#define BT_TRACE_LEVEL_DEBUG 5 /* Full debug messages */
#define BT_TRACE_LEVEL_VERBOSE 6 /* Verbose debug messages */
#define MAX_TRACE_LEVEL 6
/* Define New Trace Type Definition */
/* TRACE_CTRL_TYPE 0x^^000000*/
#define TRACE_CTRL_MASK 0xff000000
#define TRACE_GET_CTRL(x) ((((uint32_t)(x)) & TRACE_CTRL_MASK) >> 24)
#define TRACE_CTRL_GENERAL 0x00000000
#define TRACE_CTRL_STR_RESOURCE 0x01000000
#define TRACE_CTRL_SEQ_FLOW 0x02000000
#define TRACE_CTRL_MAX_NUM 3
/* LAYER SPECIFIC 0x00^^0000*/
#define TRACE_LAYER_MASK 0x00ff0000
#define TRACE_GET_LAYER(x) ((((uint32_t)(x)) & TRACE_LAYER_MASK) >> 16)
#define TRACE_LAYER_NONE 0x00000000
#define TRACE_LAYER_USB 0x00010000
#define TRACE_LAYER_SERIAL 0x00020000
#define TRACE_LAYER_SOCKET 0x00030000
#define TRACE_LAYER_RS232 0x00040000
#define TRACE_LAYER_TRANS_MAX_NUM 5
#define TRACE_LAYER_TRANS_ALL 0x007f0000
#define TRACE_LAYER_LC 0x00050000
#define TRACE_LAYER_LM 0x00060000
#define TRACE_LAYER_HCI 0x00070000
#define TRACE_LAYER_L2CAP 0x00080000
#define TRACE_LAYER_RFCOMM 0x00090000
#define TRACE_LAYER_SDP 0x000a0000
#define TRACE_LAYER_TCS 0x000b0000
#define TRACE_LAYER_OBEX 0x000c0000
#define TRACE_LAYER_BTM 0x000d0000
#define TRACE_LAYER_GAP 0x000e0000
#define TRACE_LAYER_ICP 0x00110000
#define TRACE_LAYER_HSP2 0x00120000
#define TRACE_LAYER_SPP 0x00130000
#define TRACE_LAYER_CTP 0x00140000
#define TRACE_LAYER_BPP 0x00150000
#define TRACE_LAYER_HCRP 0x00160000
#define TRACE_LAYER_FTP 0x00170000
#define TRACE_LAYER_OPP 0x00180000
#define TRACE_LAYER_BTU 0x00190000
#define TRACE_LAYER_GKI 0x001a0000 /* OBSOLETED */
#define TRACE_LAYER_BNEP 0x001b0000
#define TRACE_LAYER_PAN 0x001c0000
#define TRACE_LAYER_HFP 0x001d0000
#define TRACE_LAYER_HID 0x001e0000
#define TRACE_LAYER_BIP 0x001f0000
#define TRACE_LAYER_AVP 0x00200000
#define TRACE_LAYER_A2DP 0x00210000
#define TRACE_LAYER_SAP 0x00220000
#define TRACE_LAYER_AMP 0x00230000
#define TRACE_LAYER_MCA 0x00240000
#define TRACE_LAYER_ATT 0x00250000
#define TRACE_LAYER_SMP 0x00260000
#define TRACE_LAYER_NFC 0x00270000
#define TRACE_LAYER_NCI 0x00280000
#define TRACE_LAYER_LLCP 0x00290000
#define TRACE_LAYER_NDEF 0x002a0000
#define TRACE_LAYER_RW 0x002b0000
#define TRACE_LAYER_CE 0x002c0000
#define TRACE_LAYER_P2P 0x002d0000
#define TRACE_LAYER_SNEP 0x002e0000
#define TRACE_LAYER_CHO 0x002f0000
#define TRACE_LAYER_NFA 0x00300000
#define TRACE_LAYER_MAX_NUM 0x0031
/* TRACE_ORIGINATOR 0x0000^^00*/
#define TRACE_ORG_MASK 0x0000ff00
#define TRACE_GET_ORG(x) ((((uint32_t)(x)) & TRACE_ORG_MASK) >> 8)
#define TRACE_ORG_STACK 0x00000000
#define TRACE_ORG_HCI_TRANS 0x00000100
#define TRACE_ORG_PROTO_DISP 0x00000200
#define TRACE_ORG_RPC 0x00000300
#define TRACE_ORG_GKI 0x00000400 /* OBSOLETED */
#define TRACE_ORG_APPL 0x00000500
#define TRACE_ORG_SCR_WRAPPER 0x00000600
#define TRACE_ORG_SCR_ENGINE 0x00000700
#define TRACE_ORG_USER_SCR 0x00000800
#define TRACE_ORG_TESTER 0x00000900
#define TRACE_ORG_MAX_NUM 10 /* 32-bit mask; must be < 32 */
#define TRACE_LITE_ORG_MAX_NUM 6
#define TRACE_ORG_ALL 0x03ff
#define TRACE_ORG_RPC_TRANS 0x04
#define TRACE_ORG_REG 0x00000909
#define TRACE_ORG_REG_SUCCESS 0x0000090a
/* TRACE_TYPE 0x000000^^*/
#define TRACE_TYPE_MASK 0x000000ff
#define TRACE_GET_TYPE(x) (((uint32_t)(x)) & TRACE_TYPE_MASK)
#define TRACE_TYPE_ERROR 0x00000000
#define TRACE_TYPE_WARNING 0x00000001
#define TRACE_TYPE_API 0x00000002
#define TRACE_TYPE_EVENT 0x00000003
#define TRACE_TYPE_DEBUG 0x00000004
#define TRACE_TYPE_STACK_ONLY_MAX TRACE_TYPE_DEBUG
#define TRACE_TYPE_TX 0x00000005
#define TRACE_TYPE_RX 0x00000006
#define TRACE_TYPE_DEBUG_ASSERT 0x00000007
#define TRACE_TYPE_GENERIC 0x00000008
#define TRACE_TYPE_REG 0x00000009
#define TRACE_TYPE_REG_SUCCESS 0x0000000a
#define TRACE_TYPE_CMD_TX 0x0000000b
#define TRACE_TYPE_EVT_TX 0x0000000c
#define TRACE_TYPE_ACL_TX 0x0000000d
#define TRACE_TYPE_CMD_RX 0x0000000e
#define TRACE_TYPE_EVT_RX 0x0000000f
#define TRACE_TYPE_ACL_RX 0x00000010
#define TRACE_TYPE_TARGET_TRACE 0x00000011
#define TRACE_TYPE_SCO_TX 0x00000012
#define TRACE_TYPE_SCO_RX 0x00000013
#define TRACE_TYPE_MAX_NUM 20
#define TRACE_TYPE_ALL 0xffff
/* Define color for script type */
#define SCR_COLOR_DEFAULT 0
#define SCR_COLOR_TYPE_COMMENT 1
#define SCR_COLOR_TYPE_COMMAND 2
#define SCR_COLOR_TYPE_EVENT 3
#define SCR_COLOR_TYPE_SELECT 4
/* Define protocol trace flag values */
#define SCR_PROTO_TRACE_HCI_SUMMARY 0x00000001
#define SCR_PROTO_TRACE_HCI_DATA 0x00000002
#define SCR_PROTO_TRACE_L2CAP 0x00000004
#define SCR_PROTO_TRACE_RFCOMM 0x00000008
#define SCR_PROTO_TRACE_SDP 0x00000010
#define SCR_PROTO_TRACE_TCS 0x00000020
#define SCR_PROTO_TRACE_OBEX 0x00000040
#define SCR_PROTO_TRACE_OAPP 0x00000080 /* OBEX Application Profile */
#define SCR_PROTO_TRACE_AMP 0x00000100
#define SCR_PROTO_TRACE_BNEP 0x00000200
#define SCR_PROTO_TRACE_AVP 0x00000400
#define SCR_PROTO_TRACE_MCA 0x00000800
#define SCR_PROTO_TRACE_ATT 0x00001000
#define SCR_PROTO_TRACE_SMP 0x00002000
#define SCR_PROTO_TRACE_NCI 0x00004000
#define SCR_PROTO_TRACE_LLCP 0x00008000
#define SCR_PROTO_TRACE_NDEF 0x00010000
#define SCR_PROTO_TRACE_RW 0x00020000
#define SCR_PROTO_TRACE_CE 0x00040000
#define SCR_PROTO_TRACE_SNEP 0x00080000
#define SCR_PROTO_TRACE_CHO 0x00100000
#define SCR_PROTO_TRACE_ALL 0x001fffff
#define SCR_PROTO_TRACE_HCI_LOGGING_VSE \
0x0800 /* Brcm vs event for logmsg and protocol traces */
#define MAX_SCRIPT_TYPE 5
#define TCS_PSM_INTERCOM 5
#define TCS_PSM_CORDLESS 7
#define BT_PSM_BNEP 0x000F
/* Define PSMs HID uses */
#define HID_PSM_CONTROL 0x0011
#define HID_PSM_INTERRUPT 0x0013
/* Define a function for logging */
typedef void(BT_LOG_FUNC)(int trace_type, const char* fmt_str, ...);
/* bd addr length and type */
#ifndef BD_ADDR_LEN
#define BD_ADDR_LEN 6
typedef uint8_t BD_ADDR[BD_ADDR_LEN];
#endif
// From bd.c
/*****************************************************************************
* Constants
****************************************************************************/
/* global constant for "any" bd addr */
static const BD_ADDR bd_addr_any = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
static const BD_ADDR bd_addr_null = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
/*****************************************************************************
* Functions
****************************************************************************/
/*******************************************************************************
*
* Function bdcpy
*
* Description Copy bd addr b to a.
*
*
* Returns void
*
******************************************************************************/
static inline void bdcpy(BD_ADDR a, const BD_ADDR b) {
int i;
for (i = BD_ADDR_LEN; i != 0; i--) {
*a++ = *b++;
}
}
/*******************************************************************************
*
* Function bdcmp
*
* Description Compare bd addr b to a.
*
*
* Returns Zero if b==a, nonzero otherwise (like memcmp).
*
******************************************************************************/
static inline int bdcmp(const BD_ADDR a, const BD_ADDR b) {
int i;
for (i = BD_ADDR_LEN; i != 0; i--) {
if (*a++ != *b++) {
return -1;
}
}
return 0;
}
/*******************************************************************************
*
* Function bdcmpany
*
* Description Compare bd addr to "any" bd addr.
*
*
* Returns Zero if a equals bd_addr_any.
*
******************************************************************************/
static inline int bdcmpany(const BD_ADDR a) { return bdcmp(a, bd_addr_any); }
/*******************************************************************************
*
* Function bdsetany
*
* Description Set bd addr to "any" bd addr.
*
*
* Returns void
*
******************************************************************************/
static inline void bdsetany(BD_ADDR a) { bdcpy(a, bd_addr_any); }
static inline bool is_sample_ltk(const BT_OCTET16 ltk) {
/* Sample LTK from BT Spec 5.1 | Vol 6, Part C 1
* 0x4C68384139F574D836BCF34E9DFB01BF */
const uint8_t SAMPLE_LTK[] = {0xbf, 0x01, 0xfb, 0x9d, 0x4e, 0xf3, 0xbc, 0x36,
0xd8, 0x74, 0xf5, 0x39, 0x41, 0x38, 0x68, 0x4c};
return memcmp(ltk, SAMPLE_LTK, BT_OCTET16_LEN) == 0;
}
#endif