FreeCalypso > hg > fc-magnetite
view src/cs/riviera/rvf/rvf_trace_adapt.c @ 632:d968a3216ba0
new tangomdm build target
TCS211/Magnetite built for target leonardo runs just fine on the Tango-based
Caramel board, but a more proper tangomdm build target is preferable in order
to better market these Tango modems to prospective commercial customers. The
only differences are in GPIO and MCSI config:
* MCSI is enabled in the tangomdm build config.
* GPIO 1 is loudspeaker amplifier control on Leonardo, but on Tango platforms
it can be used for anything. On Caramel boards this GPIO should be
configured as an output driving high.
* GPIO 2 needs to be configured as Calypso input on Leonardo, but on Tango
platforms it can be used for anything. On Caramel boards this GPIO should be
configured as an output, either high or low is OK.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sat, 04 Jan 2020 19:27:41 +0000 |
| parents | 945cf7f506b2 |
| children |
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/****************************************************************************/ /* */ /* Name rvf_trace_adapt.c */ /* */ /* Function this file is used to trace messages if TRACE module is */ /* activated or not */ /* */ /* Version 0.1 */ /* */ /* Date Modification */ /* ------------------------------------ */ /* 03/19/2001 Create */ /* */ /* Author Pascal Puel (p-puel@tif.ti.com) */ /* */ /* (C) Copyright 1999 by Texas Instruments Incorporated, All Rights Reserved*/ /****************************************************************************/ #ifndef _WINDOWS #include "config/rv.cfg" #include "config/trace.cfg" #endif #include "rv/general.h" #include "rv/rv.h" #include "rv/rv_general.h" #include "rvf/rvf_api.h" #include "rvt/rvt_gen.h" #include "rvm/rvm_use_id_list.h" #include <string.h> /* DAR files used to redirect trace to DAR entity */ //#ifdef RVM_DAR_SWE // #include "dar_api.h" // #include "dar_gen.h" // #include "dar_structs_i.h" // #include "dar_diagnose_i.h" /* Define a pointer to the DAR Global Environment Control block */ // extern T_DAR_ENV_CTRL_BLK *dar_gbl_var_p; //#endif UINT8 rvf_trace_level = TRACE_LEVEL_FILTER; UINT32 rvf_layer_mask = LAYER_DBG; /* Decimal to hexadecimal conversion table */ static const char Num2Char[] = {'0','1','2','3','4','5','6','7','8','9','A','B','C','D','E','F'}; extern T_RVT_USER_ID rv_trace_user_id; #ifndef FRAMING_PROTOCOL void rvf_send_trace1 (char * msg, UINT8 msg_length, UINT32 val, UINT8 TRACE_LEVEL, UINT32 swe_use_id) { UINT32 trace_type = swe_use_id; /* Apply the appropriate compilation flags to filter trace messages based on their type and level */ if ((TRACE_LEVEL < RV_TRACE_LEVEL_WARNING) || ((TRACE_LEVEL <= rvf_trace_level) && (((trace_type & rvf_layer_mask & 0x0000FFFF) == (trace_type & 0x0000FFFF)) || ((trace_type & rvf_layer_mask & 0xFFFF0000) != (trace_type & 0xFFFF0000))))) { char * buff; if (val == NULL_PARAM) { rvt_mem_alloc (rv_trace_user_id, msg_length, (T_RVT_BUFFER *)&buff); if (buff != NULL) /* Check if there is enough memory for the buffer */ { /* Copy the body of the message */ memcpy( buff, msg, msg_length); rvt_send_trace_no_cpy( buff, rv_trace_user_id, msg_length, RVT_ASCII_FORMAT); } } else { rvt_mem_alloc (rv_trace_user_id, msg_length +11, (T_RVT_BUFFER *)&buff); if (buff != NULL) /* Check if there is enough memory for the buffer */ { UINT8 i; /* Copy the body of the message */ memcpy( buff, msg, msg_length); ((char *)buff)[msg_length] = ' '; ((char *)buff)[msg_length + 1] = '0'; ((char *)buff)[msg_length + 2] = 'x'; for (i=0; i<8; i++) { ((char *)buff)[msg_length+3+i] = Num2Char[(UINT8)((val<<(i<<2))>>28)]; } rvt_send_trace_no_cpy(buff, rv_trace_user_id, msg_length + 11, RVT_BINARY_FORMAT); } } } } #else /********************************* VERSION WITH TRACE MUX **************************/ void rvf_send_trace1 (char * msg, UINT8 msg_length, UINT32 val, UINT8 TRACE_LEVEL, UINT32 swe_use_id) { UINT32 trace_type = swe_use_id; /* Apply the appropriate compilation flags to filter trace messages based on their type and level */ if ((TRACE_LEVEL < RV_TRACE_LEVEL_WARNING) || ((TRACE_LEVEL <= rvf_trace_level) && (((trace_type & rvf_layer_mask & 0x0000FFFF) == (trace_type & 0x0000FFFF)) || ((trace_type & rvf_layer_mask & 0xFFFF0000) != (trace_type & 0xFFFF0000))))) { char * buff; if (val == NULL_PARAM) { rvt_mem_alloc (rv_trace_user_id, msg_length+5, (T_RVT_BUFFER *)&buff); if (buff != NULL) /* Check if there is enough memory for the buffer */ { /* Add the trace type (MSB and LSB) and Trace level */ buff [0] = (char) (trace_type >> 24); buff [1] = (char) (trace_type >> 16); buff [2] = (char) (trace_type >> 8); buff [3] = (char) (trace_type & 0xff); buff [4] = (char) TRACE_LEVEL; /* Copy the message in the new buffer */ memcpy(buff+5, msg, msg_length); /* Send the trace message */ rvt_send_trace_no_cpy ((T_RVT_BUFFER) buff, rv_trace_user_id, msg_length+5, RVT_BINARY_FORMAT); } } else { rvt_mem_alloc (rv_trace_user_id, msg_length+16, (T_RVT_BUFFER *)&buff); if (buff != NULL) /* Check if there is enough memory for the buffer */ { UINT8 i; /* Add the trace type (MSB and LSB) and Trace level */ buff [0] = (char) (trace_type >> 24); buff [1] = (char) (trace_type >> 16); buff [2] = (char) (trace_type >> 8); buff [3] = (char) (trace_type & 0xff); buff [4] = (char) TRACE_LEVEL; /* Copy the message in the new buffer */ memcpy( buff + 5, msg, msg_length); buff[5+msg_length] = ' '; buff[5+msg_length + 1] = '0'; buff[5+msg_length + 2] = 'x'; for (i=0; i<8; i++) { ((char *)buff)[8+msg_length+i] = Num2Char[(UINT8)((val<<(i<<2))>>28)]; } /* Send the trace message */ rvt_send_trace_no_cpy ((T_RVT_BUFFER) buff, rv_trace_user_id, msg_length+16, RVT_BINARY_FORMAT); } } } } #endif