drivers/staging/wlags49_h2/mmd.c - pub/scm/linux/kernel/git/linusw/linux-gpio - Git at Google


 //   vim:tw=110:ts=4:
 /************************************************************************************************************
 *
 * FILE	  : mmd.c
 *
 * DATE    : $Date: 2004/07/23 11:57:45 $   $Revision: 1.4 $
 * Original: 2004/05/28 14:05:35    Revision: 1.32      Tag: hcf7_t20040602_01
 * Original: 2004/05/13 15:31:45    Revision: 1.30      Tag: hcf7_t7_20040513_01
 * Original: 2004/04/15 09:24:42    Revision: 1.25      Tag: hcf7_t7_20040415_01
 * Original: 2004/04/08 15:18:17    Revision: 1.24      Tag: t7_20040413_01
 * Original: 2004/04/01 15:32:55    Revision: 1.22      Tag: t7_20040401_01
 * Original: 2004/03/10 15:39:28    Revision: 1.18      Tag: t20040310_01
 * Original: 2004/03/03 14:10:12    Revision: 1.16      Tag: t20040304_01
 * Original: 2004/03/02 09:27:12    Revision: 1.14      Tag: t20040302_03
 * Original: 2004/02/24 13:00:29    Revision: 1.12      Tag: t20040224_01
 * Original: 2004/01/30 09:59:33    Revision: 1.11      Tag: t20040219_01
 *
 * AUTHOR  : Nico Valster
 *
 * DESC    : Common routines for HCF, MSF, UIL as well as USF sources
 *
 * Note: relative to Asserts, the following can be observed:
 *	Since the IFB is not known inside the routine, the macro HCFASSERT is replaced with MDDASSERT.
 *	Also the line number reported in the assert is raised by FILE_NAME_OFFSET (20000) to discriminate the
 *	MMD Asserts from HCF and DHF asserts.
 *
 ***************************************************************************************************************
 *
 *
 * SOFTWARE LICENSE
 *
 * This software is provided subject to the following terms and conditions,
 * which you should read carefully before using the software.  Using this
 * software indicates your acceptance of these terms and conditions.  If you do
 * not agree with these terms and conditions, do not use the software.
 *
 * COPYRIGHT © 2001 - 2004	by Agere Systems Inc.	All Rights Reserved
 * All rights reserved.
 *
 * Redistribution and use in source or binary forms, with or without
 * modifications, are permitted provided that the following conditions are met:
 *
 * . Redistributions of source code must retain the above copyright notice, this
 *    list of conditions and the following Disclaimer as comments in the code as
 *    well as in the documentation and/or other materials provided with the
 *    distribution.
 *
 * . Redistributions in binary form must reproduce the above copyright notice,
 *    this list of conditions and the following Disclaimer in the documentation
 *    and/or other materials provided with the distribution.
 *
 * . Neither the name of Agere Systems Inc. nor the names of the contributors
 *    may be used to endorse or promote products derived from this software
 *    without specific prior written permission.
 *
 * Disclaimer
 *
 * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,
 * INCLUDING, BUT NOT LIMITED TO, INFRINGEMENT AND THE IMPLIED WARRANTIES OF
 * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.  ANY
 * USE, MODIFICATION OR DISTRIBUTION OF THIS SOFTWARE IS SOLELY AT THE USERS OWN
 * RISK. IN NO EVENT SHALL AGERE SYSTEMS INC. OR CONTRIBUTORS BE LIABLE FOR ANY
 * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
 * ON ANY THEORY OF LIABILITY, INCLUDING, BUT NOT LIMITED TO, CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
 * DAMAGE.
 *
 *
 **************************************************************************************************************/

 #include "hcf.h"				// Needed as long as we do not really sort out the mess
 #include "hcfdef.h"				// get CNV_LITTLE_TO_SHORT
 #include "mmd.h"				// MoreModularDriver common include file

 //to distinguish DHF from HCF asserts by means of line number
 #undef	FILE_NAME_OFFSET
 #define FILE_NAME_OFFSET DHF_FILE_NAME_OFFSET


 /*************************************************************************************************************
 *
 *.MODULE		CFG_RANGE_SPEC_STRCT* mmd_check_comp( CFG_RANGES_STRCT *actp, CFG_SUP_RANGE_STRCT *supp )
 *.PURPOSE		Checks compatibility between an actor and a supplier.
 *
 *.ARGUMENTS
 *	actp
 *	supp
 *
 *.RETURNS
 *	NULL	incompatible
 *	<>NULL	pointer to matching CFG_RANGE_SPEC_STRCT substructure in actor-structure matching the supplier
 *
 *.NARRATIVE
 *
 *  Parameters:
 *	actp	address of the actor specification
 *	supp	address of the supplier specification
 *
 *	Description: mmd_check_comp is a support routine to check the compatibility between an actor and a
 *	supplier.  mmd_check_comp is independent of the endianess of the actp and supp structures. This is
 *	achieved by checking the "bottom" or "role" fields of these structures. Since these fields are restricted
 *	to a limited range, comparing the contents to a value with a known endian-ess gives a clue to their actual
 *	endianess.
 *
 *.DIAGRAM
 *1a: The role-field of the actor structure has a known non-zero, not "byte symmetric" value (namely
 *	COMP_ROLE_ACT or 0x0001), so if and only the contents of this field matches COMP_ROLE_ACT (in Native
 *	Endian format), the actor structure is Native Endian.
 *2a: Since the role-field of the supplier structure is 0x0000, the test as used for the actor does not work
 *	for a supplier. A supplier has always exactly 1 variant,top,bottom record with (officially, but see the
 *	note below) each of these 3 values in the range 1 through 99, so one byte of the word value of variant,
 *	top and bottom words is 0x00 and the other byte is non-zero. Whether the lowest address byte or the
 *	highest address byte is non-zero depends on the Endianess of the LTV. If and only if the word value of
 *	bottom is less than 0x0100, the supplier is Native Endian.
 *	NOTE: the variant field of the supplier structure can not be used for the Endian Detection Algorithm,
 *	because a a zero-valued variant has been used as Controlled Deployment indication in the past.
 *	Note: An actor may have multiple sets of variant,top,bottom records, including dummy sets with variant,
 *	top and bottom fields with a zero-value. As a consequence the endianess of the actor can not be determined
 *	based on its variant,top,bottom values.
 *
 *	Note: the L and T field of the structures are always in Native Endian format, so you can not draw
 *	conclusions concerning the Endianess of the structure based on these two fields.
 *
 *1b/2b
 *	The only purpose of the CFG_RANGE_SPEC_BYTE_STRCT is to give easy access to the non-zero byte of the word
 *	value of variant, top and bottom. The variables sup_endian and act_endian are used for the supplier and
 *	actor structure respectively. These variables must be 0 when the structure has LE format and 1 if the
 *	structure has BE format. This can be phrased as:
 *	the variable is false (i.e 0x0000) if either
 *		(the platform is LE and the LTV is the same as the platform)
 *	or
 *		(the platform is BE and the LTV differs from the platform).
 *	the variable is true (i.e 0x0001) if either
 *		(the platform is BE and the LTV is the same as the platform)
 *	or
 *		(the platform is LE and the LTV differs from the platform).
 *
 *	Alternatively this can be phrased as:
 *	if the platform is LE
 *		if the LTV is LE (i.e the same as the platform), then the variable = 0
 *		else (the LTV is BE (i.e. different from the platform) ), then the variable = 1
 *	if the platform is BE
 *		if the LTV is BE (i.e the same as the platform), then the variable = 1
 *		else (the LTV is LE (i.e. different from the platform) ), then the variable = 0
 *
 *	This is implemented as:
 *	#if HCF_BIG_ENDIAN == 0	//platform is LE
 *		sup/act_endian becomes reverse of structure-endianess as determined in 1a/1b
 *	#endif
 *6:	Each of the actor variant-bottom-top records is checked against the (single) supplier variant-bottom-top
 *	range till either an acceptable match is found or all actor records are tried. As explained above, due to
 *	the limited ranges of these values, checking a byte is acceptable and suitable.
 *8:	depending on whether a match was found or not (as reflected by the value of the control variable of the
 *	for loop), the NULL pointer or a pointer to the matching Number/Bottom/Top record of the Actor structure
 *	is returned.
 *	As an additional safety, checking the supplier length protects against invalid Supplier structures, which
 *	may be caused by failing hcf_get_info (in which case the len-field is zero). Note that the contraption
 *	"supp->len != sizeof(CFG_SUP_RANGE_STRCT)/sizeof(hcf_16) - 1"
 *	did turn out not to work for a compiler which padded the structure definition.
 *
 * Note: when consulting references like DesignNotes and Architecture specifications there is a confusing use
 *	of the notions number and variant. This resulted in an inconsistent use in the HCF nomenclature as well.
 *	This makes the logic hard to follow and one has to be very much aware of the context when walking through
 *	the code.
 * NOTE: The Endian Detection Algorithm places limitations on future extensions of the fields, i.e. they should
 *	stay within the currently defined boundaries of 1 through 99 (although 1 through 255) would work as well
 *	and there should never be used a zero value for the bottom of a valid supplier.
 * Note: relative to Asserts, the following can be observed:
 *	1: Supplier variant 0x0000 has been used for Controlled Deployment
 *	2: An actor may have one or more variant record specifications with a top of zero and a non-zero bottom
 *	to override the HCF default support of a particular variant by the MSF programmer via hcfcfg.h
 *	3:	An actor range can be specified as all zeros, e.g. as padding in the automatically generated firmware
 *	image files.
 *.ENDDOC				END DOCUMENTATION
 *************************************************************************************************************/
 CFG_RANGE_SPEC_STRCT*
 mmd_check_comp( CFG_RANGES_STRCT *actp, CFG_SUP_RANGE_STRCT *supp )
 {

 CFG_RANGE_SPEC_BYTE_STRCT  *actq = (CFG_RANGE_SPEC_BYTE_STRCT*)actp->var_rec;
 CFG_RANGE_SPEC_BYTE_STRCT  *supq = (CFG_RANGE_SPEC_BYTE_STRCT*)&(supp->variant);
 hcf_16	i;
 int		act_endian;					//actor endian flag
 int		sup_endian;					//supplier endian flag

 	act_endian = actp->role == COMP_ROLE_ACT;	//true if native endian				/* 1a */
 	sup_endian = supp->bottom < 0x0100;		 	//true if native endian				/* 2a */

 #if HCF_ASSERT
 	MMDASSERT( supp->len == 6, 																supp->len )
 	MMDASSERT( actp->len >= 6 && actp->len%3 == 0, 											actp->len )

 	if ( act_endian ) {							//native endian
 		MMDASSERT( actp->role == COMP_ROLE_ACT,												actp->role )
 		MMDASSERT( 1 <= actp->id && actp->id <= 99,  										actp->id )
 	} else {									//non-native endian
 		MMDASSERT( actp->role == CNV_END_SHORT(COMP_ROLE_ACT),	 							actp->role )
 		MMDASSERT( 1 <= CNV_END_SHORT(actp->id) && CNV_END_SHORT(actp->id) <= 99,				actp->id )
 	}
 	if ( sup_endian ) {							//native endian
 		MMDASSERT( supp->role == COMP_ROLE_SUPL, 											supp->role )
 		MMDASSERT( 1 <= supp->id      && supp->id <= 99,  									supp->id )
 		MMDASSERT( 1 <= supp->variant && supp->variant <= 99,  								supp->variant )
 		MMDASSERT( 1 <= supp->bottom  && supp->bottom <= 99, 								supp->bottom )
 		MMDASSERT( 1 <= supp->top     && supp->top <= 99, 		 							supp->top )
 		MMDASSERT( supp->bottom <= supp->top,							supp->bottom << 8 | supp->top )
 	} else {									//non-native endian
 		MMDASSERT( supp->role == CNV_END_SHORT(COMP_ROLE_SUPL), 								supp->role )
 		MMDASSERT( 1 <= CNV_END_SHORT(supp->id) && CNV_END_SHORT(supp->id) <= 99,				supp->id )
 		MMDASSERT( 1 <= CNV_END_SHORT(supp->variant) && CNV_END_SHORT(supp->variant) <= 99,		supp->variant )
 		MMDASSERT( 1 <= CNV_END_SHORT(supp->bottom)  && CNV_END_SHORT(supp->bottom) <=99,		supp->bottom )
 		MMDASSERT( 1 <= CNV_END_SHORT(supp->top)     && CNV_END_SHORT(supp->top) <=99,  		supp->top )
 		MMDASSERT( CNV_END_SHORT(supp->bottom) <= CNV_END_SHORT(supp->top),	supp->bottom << 8 |	supp->top )
 	}
 #endif // HCF_ASSERT

 #if HCF_BIG_ENDIAN == 0
 	act_endian = !act_endian;																		/* 1b*/
 	sup_endian = !sup_endian;																		/* 2b*/
 #endif // HCF_BIG_ENDIAN

 	for ( i = actp->len ; i > 3; actq++, i -= 3 ) {													/* 6 */
 		MMDASSERT( actq->variant[act_endian] <= 99, i<<8 | actq->variant[act_endian] )
 		MMDASSERT( actq->bottom[act_endian] <= 99 , i<<8 | actq->bottom[act_endian] )
 		MMDASSERT( actq->top[act_endian] <= 99	  , i<<8 | actq->top[act_endian] )
 		MMDASSERT( actq->bottom[act_endian] <= actq->top[act_endian], i<<8 | actq->bottom[act_endian] )
 		if ( actq->variant[act_endian] == supq->variant[sup_endian] &&
 			 actq->bottom[act_endian]  <= supq->top[sup_endian] &&
 			 actq->top[act_endian]     >= supq->bottom[sup_endian]
 		   ) break;
 	}
 	if ( i <= 3 || supp->len != 6 /*sizeof(CFG_SUP_RANGE_STRCT)/sizeof(hcf_16) - 1 */ ) {
 	   actq = NULL;																					/* 8 */
 	}
 #if HCF_ASSERT
 	if ( actq == NULL ) {
 		for ( i = 0; i <= supp->len; i += 2 ) {
 			MMDASSERT( DO_ASSERT, MERGE_2( ((hcf_16*)supp)[i], ((hcf_16*)supp)[i+1] ) );
 		}
 		for ( i = 0; i <= actp->len; i += 2 ) {
 			MMDASSERT( DO_ASSERT, MERGE_2( ((hcf_16*)actp)[i], ((hcf_16*)actp)[i+1] ) );
 		}
 	}
 #endif // HCF_ASSERT
 	return (CFG_RANGE_SPEC_STRCT*)actq;
 } // mmd_check_comp

	// vim:tw=110:ts=4:
	/************************************************************************************************************
	*
	* FILE : mmd.c
	*
	* DATE : $Date: 2004/07/23 11:57:45 $ $Revision: 1.4 $
	* Original: 2004/05/28 14:05:35 Revision: 1.32 Tag: hcf7_t20040602_01
	* Original: 2004/05/13 15:31:45 Revision: 1.30 Tag: hcf7_t7_20040513_01
	* Original: 2004/04/15 09:24:42 Revision: 1.25 Tag: hcf7_t7_20040415_01
	* Original: 2004/04/08 15:18:17 Revision: 1.24 Tag: t7_20040413_01
	* Original: 2004/04/01 15:32:55 Revision: 1.22 Tag: t7_20040401_01
	* Original: 2004/03/10 15:39:28 Revision: 1.18 Tag: t20040310_01
	* Original: 2004/03/03 14:10:12 Revision: 1.16 Tag: t20040304_01
	* Original: 2004/03/02 09:27:12 Revision: 1.14 Tag: t20040302_03
	* Original: 2004/02/24 13:00:29 Revision: 1.12 Tag: t20040224_01
	* Original: 2004/01/30 09:59:33 Revision: 1.11 Tag: t20040219_01
	*
	* AUTHOR : Nico Valster
	*
	* DESC : Common routines for HCF, MSF, UIL as well as USF sources
	*
	* Note: relative to Asserts, the following can be observed:
	* Since the IFB is not known inside the routine, the macro HCFASSERT is replaced with MDDASSERT.
	* Also the line number reported in the assert is raised by FILE_NAME_OFFSET (20000) to discriminate the
	* MMD Asserts from HCF and DHF asserts.
	*
	***************************************************************************************************************
	*
	*
	* SOFTWARE LICENSE
	*
	* This software is provided subject to the following terms and conditions,
	* which you should read carefully before using the software. Using this
	* software indicates your acceptance of these terms and conditions. If you do
	* not agree with these terms and conditions, do not use the software.
	*
	* COPYRIGHT © 2001 - 2004 by Agere Systems Inc. All Rights Reserved
	* All rights reserved.
	*
	* Redistribution and use in source or binary forms, with or without
	* modifications, are permitted provided that the following conditions are met:
	*
	* . Redistributions of source code must retain the above copyright notice, this
	* list of conditions and the following Disclaimer as comments in the code as
	* well as in the documentation and/or other materials provided with the
	* distribution.
	*
	* . Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following Disclaimer in the documentation
	* and/or other materials provided with the distribution.
	*
	* . Neither the name of Agere Systems Inc. nor the names of the contributors
	* may be used to endorse or promote products derived from this software
	* without specific prior written permission.
	*
	* Disclaimer
	*
	* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,
	* INCLUDING, BUT NOT LIMITED TO, INFRINGEMENT AND THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. ANY
	* USE, MODIFICATION OR DISTRIBUTION OF THIS SOFTWARE IS SOLELY AT THE USERS OWN
	* RISK. IN NO EVENT SHALL AGERE SYSTEMS INC. OR CONTRIBUTORS BE LIABLE FOR ANY
	* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
	* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
	* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
	* ON ANY THEORY OF LIABILITY, INCLUDING, BUT NOT LIMITED TO, CONTRACT, STRICT
	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
	* DAMAGE.
	*
	*
	**************************************************************************************************************/

	#include "hcf.h" // Needed as long as we do not really sort out the mess
	#include "hcfdef.h" // get CNV_LITTLE_TO_SHORT
	#include "mmd.h" // MoreModularDriver common include file

	//to distinguish DHF from HCF asserts by means of line number
	#undef FILE_NAME_OFFSET
	#define FILE_NAME_OFFSET DHF_FILE_NAME_OFFSET


	/*************************************************************************************************************
	*
	.MODULE CFG_RANGE_SPEC_STRCT mmd_check_comp( CFG_RANGES_STRCT actp, CFG_SUP_RANGE_STRCT supp )
	*.PURPOSE Checks compatibility between an actor and a supplier.
	*
	*.ARGUMENTS
	* actp
	* supp
	*
	*.RETURNS
	* NULL incompatible
	* <>NULL pointer to matching CFG_RANGE_SPEC_STRCT substructure in actor-structure matching the supplier
	*
	*.NARRATIVE
	*
	* Parameters:
	* actp address of the actor specification
	* supp address of the supplier specification
	*
	* Description: mmd_check_comp is a support routine to check the compatibility between an actor and a
	* supplier. mmd_check_comp is independent of the endianess of the actp and supp structures. This is
	* achieved by checking the "bottom" or "role" fields of these structures. Since these fields are restricted
	* to a limited range, comparing the contents to a value with a known endian-ess gives a clue to their actual
	* endianess.
	*
	*.DIAGRAM
	*1a: The role-field of the actor structure has a known non-zero, not "byte symmetric" value (namely
	* COMP_ROLE_ACT or 0x0001), so if and only the contents of this field matches COMP_ROLE_ACT (in Native
	* Endian format), the actor structure is Native Endian.
	*2a: Since the role-field of the supplier structure is 0x0000, the test as used for the actor does not work
	* for a supplier. A supplier has always exactly 1 variant,top,bottom record with (officially, but see the
	* note below) each of these 3 values in the range 1 through 99, so one byte of the word value of variant,
	* top and bottom words is 0x00 and the other byte is non-zero. Whether the lowest address byte or the
	* highest address byte is non-zero depends on the Endianess of the LTV. If and only if the word value of
	* bottom is less than 0x0100, the supplier is Native Endian.
	* NOTE: the variant field of the supplier structure can not be used for the Endian Detection Algorithm,
	* because a a zero-valued variant has been used as Controlled Deployment indication in the past.
	* Note: An actor may have multiple sets of variant,top,bottom records, including dummy sets with variant,
	* top and bottom fields with a zero-value. As a consequence the endianess of the actor can not be determined
	* based on its variant,top,bottom values.
	*
	* Note: the L and T field of the structures are always in Native Endian format, so you can not draw
	* conclusions concerning the Endianess of the structure based on these two fields.
	*
	*1b/2b
	* The only purpose of the CFG_RANGE_SPEC_BYTE_STRCT is to give easy access to the non-zero byte of the word
	* value of variant, top and bottom. The variables sup_endian and act_endian are used for the supplier and
	* actor structure respectively. These variables must be 0 when the structure has LE format and 1 if the
	* structure has BE format. This can be phrased as:
	* the variable is false (i.e 0x0000) if either
	* (the platform is LE and the LTV is the same as the platform)
	* or
	* (the platform is BE and the LTV differs from the platform).
	* the variable is true (i.e 0x0001) if either
	* (the platform is BE and the LTV is the same as the platform)
	* or
	* (the platform is LE and the LTV differs from the platform).
	*
	* Alternatively this can be phrased as:
	* if the platform is LE
	* if the LTV is LE (i.e the same as the platform), then the variable = 0
	* else (the LTV is BE (i.e. different from the platform) ), then the variable = 1
	* if the platform is BE
	* if the LTV is BE (i.e the same as the platform), then the variable = 1
	* else (the LTV is LE (i.e. different from the platform) ), then the variable = 0
	*
	* This is implemented as:
	* #if HCF_BIG_ENDIAN == 0 //platform is LE
	* sup/act_endian becomes reverse of structure-endianess as determined in 1a/1b
	* #endif
	*6: Each of the actor variant-bottom-top records is checked against the (single) supplier variant-bottom-top
	* range till either an acceptable match is found or all actor records are tried. As explained above, due to
	* the limited ranges of these values, checking a byte is acceptable and suitable.
	*8: depending on whether a match was found or not (as reflected by the value of the control variable of the
	* for loop), the NULL pointer or a pointer to the matching Number/Bottom/Top record of the Actor structure
	* is returned.
	* As an additional safety, checking the supplier length protects against invalid Supplier structures, which
	* may be caused by failing hcf_get_info (in which case the len-field is zero). Note that the contraption
	* "supp->len != sizeof(CFG_SUP_RANGE_STRCT)/sizeof(hcf_16) - 1"
	* did turn out not to work for a compiler which padded the structure definition.
	*
	* Note: when consulting references like DesignNotes and Architecture specifications there is a confusing use
	* of the notions number and variant. This resulted in an inconsistent use in the HCF nomenclature as well.
	* This makes the logic hard to follow and one has to be very much aware of the context when walking through
	* the code.
	* NOTE: The Endian Detection Algorithm places limitations on future extensions of the fields, i.e. they should
	* stay within the currently defined boundaries of 1 through 99 (although 1 through 255) would work as well
	* and there should never be used a zero value for the bottom of a valid supplier.
	* Note: relative to Asserts, the following can be observed:
	* 1: Supplier variant 0x0000 has been used for Controlled Deployment
	* 2: An actor may have one or more variant record specifications with a top of zero and a non-zero bottom
	* to override the HCF default support of a particular variant by the MSF programmer via hcfcfg.h
	* 3: An actor range can be specified as all zeros, e.g. as padding in the automatically generated firmware
	* image files.
	*.ENDDOC END DOCUMENTATION
	*************************************************************************************************************/
	CFG_RANGE_SPEC_STRCT*
	mmd_check_comp( CFG_RANGES_STRCT actp, CFG_SUP_RANGE_STRCT supp )
	{

	CFG_RANGE_SPEC_BYTE_STRCT actq = (CFG_RANGE_SPEC_BYTE_STRCT)actp->var_rec;
	CFG_RANGE_SPEC_BYTE_STRCT supq = (CFG_RANGE_SPEC_BYTE_STRCT)&(supp->variant);
	hcf_16 i;
	int act_endian; //actor endian flag
	int sup_endian; //supplier endian flag

	act_endian = actp->role == COMP_ROLE_ACT; //true if native endian /* 1a */
	sup_endian = supp->bottom < 0x0100; //true if native endian /* 2a */

	#if HCF_ASSERT
	MMDASSERT( supp->len == 6, supp->len )
	MMDASSERT( actp->len >= 6 && actp->len%3 == 0, actp->len )

	if ( act_endian ) { //native endian
	MMDASSERT( actp->role == COMP_ROLE_ACT, actp->role )
	MMDASSERT( 1 <= actp->id && actp->id <= 99, actp->id )
	} else { //non-native endian
	MMDASSERT( actp->role == CNV_END_SHORT(COMP_ROLE_ACT), actp->role )
	MMDASSERT( 1 <= CNV_END_SHORT(actp->id) && CNV_END_SHORT(actp->id) <= 99, actp->id )
	}
	if ( sup_endian ) { //native endian
	MMDASSERT( supp->role == COMP_ROLE_SUPL, supp->role )
	MMDASSERT( 1 <= supp->id && supp->id <= 99, supp->id )
	MMDASSERT( 1 <= supp->variant && supp->variant <= 99, supp->variant )
	MMDASSERT( 1 <= supp->bottom && supp->bottom <= 99, supp->bottom )
	MMDASSERT( 1 <= supp->top && supp->top <= 99, supp->top )
	MMDASSERT( supp->bottom <= supp->top, supp->bottom << 8 \| supp->top )
	} else { //non-native endian
	MMDASSERT( supp->role == CNV_END_SHORT(COMP_ROLE_SUPL), supp->role )
	MMDASSERT( 1 <= CNV_END_SHORT(supp->id) && CNV_END_SHORT(supp->id) <= 99, supp->id )
	MMDASSERT( 1 <= CNV_END_SHORT(supp->variant) && CNV_END_SHORT(supp->variant) <= 99, supp->variant )
	MMDASSERT( 1 <= CNV_END_SHORT(supp->bottom) && CNV_END_SHORT(supp->bottom) <=99, supp->bottom )
	MMDASSERT( 1 <= CNV_END_SHORT(supp->top) && CNV_END_SHORT(supp->top) <=99, supp->top )
	MMDASSERT( CNV_END_SHORT(supp->bottom) <= CNV_END_SHORT(supp->top), supp->bottom << 8 \| supp->top )
	}
	#endif // HCF_ASSERT

	#if HCF_BIG_ENDIAN == 0
	act_endian = !act_endian; /* 1b*/
	sup_endian = !sup_endian; /* 2b*/
	#endif // HCF_BIG_ENDIAN

	for ( i = actp->len ; i > 3; actq++, i -= 3 ) { /* 6 */
	MMDASSERT( actq->variant[act_endian] <= 99, i<<8 \| actq->variant[act_endian] )
	MMDASSERT( actq->bottom[act_endian] <= 99 , i<<8 \| actq->bottom[act_endian] )
	MMDASSERT( actq->top[act_endian] <= 99 , i<<8 \| actq->top[act_endian] )
	MMDASSERT( actq->bottom[act_endian] <= actq->top[act_endian], i<<8 \| actq->bottom[act_endian] )
	if ( actq->variant[act_endian] == supq->variant[sup_endian] &&
	actq->bottom[act_endian] <= supq->top[sup_endian] &&
	actq->top[act_endian] >= supq->bottom[sup_endian]
	) break;
	}
	if ( i <= 3 \|\| supp->len != 6 /sizeof(CFG_SUP_RANGE_STRCT)/sizeof(hcf_16) - 1 / ) {
	actq = NULL; /* 8 */
	}
	#if HCF_ASSERT
	if ( actq == NULL ) {
	for ( i = 0; i <= supp->len; i += 2 ) {
	MMDASSERT( DO_ASSERT, MERGE_2( ((hcf_16)supp)[i], ((hcf_16)supp)[i+1] ) );
	}
	for ( i = 0; i <= actp->len; i += 2 ) {
	MMDASSERT( DO_ASSERT, MERGE_2( ((hcf_16)actp)[i], ((hcf_16)actp)[i+1] ) );
	}
	}
	#endif // HCF_ASSERT
	return (CFG_RANGE_SPEC_STRCT*)actq;
	} // mmd_check_comp