SAJEMS NS Vol 2 (1999) No 3 509 

An Econometric Analysis of the Impact of the 
RDP on the Demand for Construction Materials 
in South Africa 

Charles C Okeahalam 

Donald Gordon Professor, Graduate School of Business, University of the 
Witwatersrand 

ABSTRACT 

The Reconstruction and Development Programme (RDP) is an attempt by the 
South African government to redress the imbalances of apartheid. It has many 
facets. One of these involves the provision and distribution of infrastructure to 
citizens who hitherto have been neglected. This calls for significant 
construction effort particularly for housing, water, roads and other social 
construction. This will require efficient production, and allocation of resources 
to ensure that there is adequate supply of materials to meet the likely increase in 
demand. This paper examines the expected demand for construction materials, 
assesses the supply capacity of South African suppliers of construction 
materials, and develops an econometric model which can be used to evaluate the 
impact that growth of the internal construction activity will have on construction 
industry suppliers. 

JEL 011 

1 INTRODUCTION 

The role of construction as part of Keynesian economic policy has been debated, 
by for example Coates and Hillard (1987) and Fishlow (1995). Some, such as 
Easterley and Vierra da Cunha (1994) and Tanzi (1996), see specific industrial 
sector focus, unwarranted by potential for positive expected financial returns, to 
be a distortion of incentives and thus a form of fiscal laxity. Accordingly, they 
consider pump-priming (greater expenditure by government on public works on 
construction as a method of stimulating economic growth) to be inefficient; 
indeed detrimental, to long term growth. 

Different conditions face each of the Southern African countries in terms of 
resources, population, economic and technological levels. The objective of this 
paper is to provide an analysis of recent trends and patterns within the 

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510 SAJEMS NS Vol 2 (1999) No 3 

construction industry of the Southern Africa region and then develop a 
framework to conduct an econometric analysis of the South Africa construction 
material demand-supply position. Section 2 provides an analysis and evaluation 
of salient trends, in section 3 we estimate an econometric model to test the data, 
in section 4 we present the findings of the econometric exercise, section 5 gives 
some methodological points with which to validate the results, section 6 
contains conclusions and section 7 provides recommendations, managerial 
implications and areas for future research. 

2 REVIEW OF TRENDS IN THE SOUTHERN AFRICA 
CONSTRUCTION SECTOR 

In what follows here, we discuss the main trends in the data to provide an 
overview to the reader and to describe the data used in the econometric model 
which follows in section 3. The data set used is based on information for the 
four-year inclusive period of 1991 to 1994 and is derived primarily from desk 
top and library search from a variety of publications, including the Business 
Construction Review (1992, 1993 and 1994) and publications of the Southern 
African Research Strategy Consulting Unit (SARSCU) - notably, The Market 
for Building Materials (1996). 

As noted in Gouden, Merrifield, Amod and Nkosi (1996) it is inevitable that 
effects of war damage and insufficient delivery of transport infrastructure will 
influence the rate of inflation in the regional construction industry and this 
varies greatly, as can be seen in Table I below. Furthermore, Table 2 shows the 
different annual rates of change in planned residential investment in the 
southern Africa region. This shows that Botswana which has experienced 
significant annual rates of economic growth has the highest rate (110.5%) while 
Tanzania has the lowest (6.9%). In Table 3, again it can be seen that, with 
regard to the non-residential sector, Namibia has the highest (39.5%) and 
Mozambique the lowest rate (6%). The size and growth of the construction 
industry of countries in the Southern Africa region thus differ and the extent to 
which they have penetrated each others' construction markets and industries 
will also differ. 

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SAJEMS NS Vol 2 (1999) No 3 511 

Table 1 Average construction industry inflation rate (%) in southern 
African (SADC) countries 

COUNTRY 1991 1992 1993 1994 MEAN 

Angola 1185.4 1011.9 1617.1 1738 1388.1 

Botswana 12.0 11.6 Il.l 10.9 11.4 

Lesotho 15.2 15.5 15.1 15.6 15.4 

Malawi 28.8 25.1 24.6 19.8 24.6 

Mozambique 497.9 454.5 404.3 343.6 425 

Namibia 12.1 9.2 8.6 8.9 9.6 

South Africa 14.4 14.6 14.5 14.7 14.6 

Swaziland 14.7 15.0 14.9 15.1 14.9 

Tanzania 25.9 25.2 24.4 22.0 24.4 

Zambia 29.1 27.6 27.9 28.7 28.3 

Zimbabwe 19.0 18.7 18.4 17.2 18.3 

Sources:Statistical Year Book, United Nations, 1994 Construction Industry Study, Botswana 
Technology Centre, 1992 Southern African Research Centre, Harare, Zimbabwe. 
Economic Research Bureau, University of Dar es Salaam, 1991; Central Statistical 
Office, Mbabane, Swaziland; The Economic Intelligence Unit Ltd, 1994; Business 
and Construction Review, June 1993; The Central Bank of Swaziland, 1993; Bank 
of Tanzania Annual Report, 1992. 

Table 2 Southern African construction industry indicators, annual rate 
(%) of change for residential buildings approved 
plan/investment 

COUNTRY 1991 1992 1993 1994 MEAN 

Angola 2.3 2.6 4.5 4.8 3.5 

Botswana 50.7 30.1 20.8 8.9 27.6 

Lesotho 3.4 4.3 4.4 3.6 4.0 

Malawi 2.1 3.6 3.3 2.9 2.9 

Mozambique 1.8 2.7 2.2 2.9 2.4 

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512 SAJEMS NS Vol 2 (1999) No 3 

Table 2 continued 

COUNTRY 1992 1993 MEAN 

Namibia 9.8 8.7 7.1 8.4 

South Africa 4.5 10.3 14.7 21.2 12.7 

Swaziland 4.5 6.1 5.2 

Tanzania 2.0 1.0 1.7 

Zambia 2.3 2.6 2.0 1.8 2.2 

Zimbabwe 13.2 13.8 13.1 12.9 13.1 

Sources; CSIR Pretoria, personal communication division of information services 
(INFORTEK) Construction Industry Study, Botswana Technology Center, 1992; 
Bureau of Economic Research, University of Stellenboscb, Building and 
Construction Business and Construction Review, 1996; Development and 
Cooperation, 1990; Central Bank of Swaziland, 1993. 

Table 3 Southern African construction industry indicators, annual rate 
of change for non- residential buildings approved plan! 
investment 

COUNTRY 
I 

1991 1992 1993 1994 MEAN 

Angola 3.7 4.1 2.1 4.2 3.5 

Botswana 8.2 7.8 7.6 7.2 7.7 

Lesotho 24.1 2.6 3.7 3.0 8.4 

Malawi 2.9 1.6 2.7 1.7 2.2 

Mozambique I 1.6 1.4 2.0 1.0 1.5 

Namibia I 9.6 6.4 12.3 11.2 9.9 

South Africa 10 15 20 23 17.0 

Swaziland 5.2 3.6 5.0 4.5 4.6 

Tanzania 4.9 3.5 2.6 2.1 3.3 

Zambia 3.7 4.9 3.3 2.6 3.6 

Zimbabwe 6.9 7.8 6.3 5.0 6.5 

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SAJEMS NS Vol 2 (1999) No 3 513 

Sources: Business and Construction Review, 1992-93Ministry of Works, Transport and 
Communications, Botswana 
Quarterly Economic and Statistical Review, Zimbabwe. 

Although not shown here, the data set makes it possible to observe that the 
demand for South Africa bricks is highest in South Africa itself. We can also 
observe that the largest regional importer of bricks which are manufactured in 
South Africa is Botswana. The data moreover suggests that Botswana as the 
major importer of bricks is followed by Namibia, Swaziland and Lesotho. We 
suggest that the prime reason for this is geographical proximity. 

There also appears to be a significant amount of horizontal and vertical 
integration between South African construction companies and construction 
materia] manufacturers in Namibia, Lesotho, and Swaziland. 

Table 4 Percentage of GDP allocated to the construction in SADC 
countries in 1994 

COUNTRY PERCENTAGE 

Angola 12.1 

Botswana 33.8 

Lesotho 6.5 

Malawi 4.8 

Mozambique 10.6 

Namibia 7.1 

South Africa 30.2 

Swaziland 6.9 

Tanzania 5.2 

Zambia 5.0 

Zimbabwe 5.1 

Sources: Southern African Research Centre, Harare, Zimbabwe 
Construction Industry Study, Botswana Technology Centre, 1992 
Building Research Strategy Consulting Uniq Ply), Ltd. 'The market for materials 
1990-95' 
Quarterly Economic and Statistical Review, Zimbabwe, 1992 
World Bank Report, 1994. 

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514 SAJEMS NS Vol 2 (1999) No 3 

Table 4 indicates the role which the construction industry plays in the GDP of 
Southern Africa countries. It would also appear that countries which until 
recently were involved in war and conflict, notably Angola and Mozambique, 
are currently allocating a high proportion of their GDP to construction. 
However, the actual size of this growth for Angola and Mozambique is still 
lower in monetary terms than that of Botswana, and of course South Africa. 
The latter in particular, has socio-economic and political reasons for allocating a 
high proportion of its GDP to this industry sector. 

The data trends suggest that given the peaceful conditions which now prevail in 
most of the region, economic growth is likely to be more buoyant and the 
region-wide demand for South Africa materials should increase accordingly. 
This is primarily because of the significant technological advantages which it 
would appear South Africa has over its regional neighbours. Now, given the 
construction sector demand-impact which will be generated by the 
Reconstruction and Development Programme (RDP), I neighbouring countries 
may experience either supply backlogs in quantity and time, and/or, they may 
experience price inflation depending on the extent to which the sector becomes 
overheated. 

3 METHODOLOGY - SPECIFICATION AND TEST OF AN 
ECONOMETRIC MODEL 

To validate the above view, in this section we use econometric methods to test 
the demand for South African construction materials, and the impact that the 
growth of internal (SA based) construction activity will have on this demand. 

The demand for construction materials is a derived demand, arising from the 
commissioning of construction projects - projects which will use materials as 
part of the construction process. Here we develop an econometric framework in 
which the derived demand level for construction materials is made conditional 
on demand for construction projects. The largest catalyst of the demand for 
construction projects and therefore materials, is likely to be the RDP .. 

It is clear that the actual demand/supply structure of materials will vary as we 
near finite levels, however the principal economic trends, even if different in 
impact, applies to different types of materials. Accordingly we proceed in a 
generic framework to establish likelihood relationships which in principle 
should be applicable to all materials. The model is: 

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SAJEMS NS Vol 2 (1999) No 3 515 

Y jil = r. UCMC jlX P + GDPjtX l+RDPjt X jp+ ETLj,X 4+8 + Eil 
where 

(I) 

lji' = is the dependent variable and the total demand for construction 
materials} in period t for construction project i; 

UCM0uXt = unit construction material consumption of material} in period t by 
construction project i; 

a vector of parameters associated with UCMCjit XI; 
GDP JG = country average GOP growth rate; 
D· RDP XJ a binary dummy variable2 for a vector of RDP independent 

jJ 

Eil 

construction project commission rate variables; 
= vector of parameters associated with RDPX3 , 
= economic trade link variables3; 
= vector of parameters4 of economic trade links which are 

correlated with neighbouring country demand for SA country 
materials; 

= error term for construction project i in period t. 

The term RDP JG accounts for the range of possible types of construction 
projects, housing, roads, bridges, dams. For our pwpose the distribution of the 
UCMCu associated with these specific projects is of less interest than the 
aggregate level. 

A pure conditional-demand approach approximates the terms UCMCit via 
variables related to the type of construction project under consideration. 
Specification can take a linear form and be simplified by using the financial 
value of the construction project as a proxy for the use of construction materials; 
linearly the higher the value of the project the more material is used. However, 
there is a problem with this specification in that different projects use materials 
at a different rate and accordingly, the demand for construction materials is not 
fully correlated nor monotonic in functional form. 

An engineering·econometric approach would condition a UCMC specific type 
of project and the underlying technology to be used. Thus the structure of the 
estimated equation would be best emphasised by including all the relevant 
construction engineering data available. Using this latter approach, to apply the 
model empirically it would be necessary to focus on the specific end uses of 
construction materials at the rate that they differ for different types of 
construction. This would elicit cross·sectional as well as regional/country 
variations. However, in the case of roads for example, if a regional road 
construction plan exists it would be possible to enter calibrations based on this 
plan into the model. For housing we could, given the RDP, subtract the term 
from the left hand side of the equation. If the values are measured with error, 

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516 SAJEMS NS Vol 2 (1999) No 3 

this approach may reduce the parameter estimates of pI but should not bias the 
estimates, if the measurement errors are uncorrelated with the right hand side 
variables. 

The estimation of the model has to take cognisance of the cross-sectional and 
time-series properties of the data and attempt, in particular, to exploit the UCMC 
j response rates over time. We also have to assume homoscedasticity of 
disturbances for the construction period of every i. 

Given differences in each i, the paucity of the time-series data available and the 
increase in empty cells that arise from cross-sectional disaggregation, this would 
be a reasonable assumption.6 Even if we assume that the cross-section and time 
series construction material demand data are independent for each i, it is still 
possible to assess individual project construction material demand over time. 
To do this we need to assume that the disturbances in each project material 
demand behaviour structure are equi-correlated over time and given the current 
vintage of technology are time-invariant. Such a situation may arise from 
unobservable but universally applicable or acceptable standard construction 
project characteristics such as, for roads, the number of metres per tonne of 
bitumen, or in the case of house construction, the number of cement bags 
required to produce bricks. The calculus then simply becomes arithmetic, as 
demand is then a function of scale. Alternatively, given the RDP, we can argue 
with some persuasion that disturbances have an auto-regressive structure in 
which E( efT e is) = pt., . S 

4 FINDINGS - RESULTS OF THE MODEL ESTIMATES. 

Table 5 Model Estimates 

l~tXl 
Estimate Standard Error (SE) 

0.714 (0.023) 
GDPX 2 0.391 (0.011) 
D-RDPX3 
DRDPX3-0 0.54 (0.017) 
D RDPX3-1 0.23 (0.004 
ETL~ 0.29 (0.316) 

I , ion: 0 
Log-likelihood (0) L*(O)= -512242 DfL *(0) =183.7 
Log-likelihood (p) L *(p)= -366125 DfL* (p)= 141.4 

-1 _ 0.322 p -

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SAJEMS NS Vol 2 (1999) No 3 517 

To gain further information in support of the data in the tables, we have 
calibrated, estimated, and validated the above model. There are some empirical 
problems which we should briefly touch on before the provision of results. 
Given that we wish to understand what the impact that SA demand will have on 
the SA construction material supply-demand position, we have disaggregated 
the data and removed all non-SA demand. We have also divided each annual 
entry into quarterly entries to be able to have sufficient data points to fit the 
number of explanatory variable parameters. While this diverges from reality in 
that the level of demand for construction material is unlikely to be uniform for 
each quarter of the year, it allows for a better fit of the model and does not 
distort the aggregate numbers since the quarterly entries are obviously a function 
ofthe yearly entries. 

We estimated the above model equation using the maximum-likelihood 
technique. 7 As would be expected the estimated coefficient for UCMYit is 
extremely significant. This is to be expected, given the way this explanatory 
variable is specified and the strong correlation this variable has relative to ljil' 
Although the parameter estimate is significant, the relationship is not uni-
variate. The GDPX1 is also significant, suggesting that the level of GDP in the 
years for which we have time-series data has a positive influence on the demand 
for construction materials. 

The coefficient for D-RDPXrO is significant, suggesting that the RDP will 
have an impact even if the trend in construction demand is constant at the 
underlying rate. The estimate for D-RDPXrl is smaller than that for 0 but 
significant, suggesting that the 6% stimulus of the RDP will also have an impact 
on the demand for construction materials. Finally, we tried to test the hypothesis 
that the level of economic trade links that exist between SA and each of her 
neighbours, measured by data from the current account trade balance tables, 
would have some discernable impact on the demand for construction materials. 
However, while the coefficient value supports this view, it is not statistically 
significant and as such is a null hypothesis.s 

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518 SAJEMS NS Vol 2 (1999) No 3 

5 VALIDATION AND OTHER METHODOLOGICAL ISSUES 

Data has been collected from a variety of sources which are listed in the 
references. The methodology has involved evaluation of data count, such that 
with the observed data we are fairly sure that we have not double counted and 
that the variety of sources used does not bias the overall results. This is the 
usual methodology that is used with some form of asymptotic estimator to 
validate combined cross-section and time-series (panel) data. This is 
particularly so with regard to some construction materials where, as we 
disaggregated further, the number of empty cells increased. 

I do feel that for further investigation and as the analysis becomes more detailed. 
there is a need to employ some form of simple random sampling, stratified 
sampling or exhaustive sampling to validate the overall statistical consistency. 
To gain further statistical confidence information on the significance of RSA 
firm demand of SA materials, a two-step estimation process would then isolate 
the significant variables of equation I, and this could then be re-estimated by 
using Xl and XJ in a reduced-form equation. We however have insufficient data 
on SA firm involvement and are therefore unable to estimate the reduced form. 
However this should be pursued in later work. 

6 CONCLUSIONS 

It is quite clear that the RSA construction sector is the major determinant of the 
derived-demand level for RSA construction materials. We also see that a very 
high proportion of RSA GDP is geared to construction and allied sectors. We 
believe that while the RDP is undoubtedly going to stimulate the level of 
internal demand for construction materials, given macroeconomic limitations, of 
its own accord, it is not going to be capable of creating the level of demand pull, 
to present supply capacity problems and industrial construction material 
inflation.9 The regional impact of RSA construction material supply sector is 
most readily felt in Botswana, Namibia and latently in Mozambique. However, 
the building boom that drove the Botswana demand is over. Furthermore it is 
clear that the further we move from RSA, the less significant is its role as a 
supplier of construction materials to Southern Africa. There is significant scope 
for development in this regard. The corollary is also worthwhile noting. in that 
there has been little or no inroad into the RSA market by her regional 
neighbours. 

The econometric analysis suggests that there is a fairly strong relationship 
between the unit material consumption rate for construction projects, that the 
RSA economic growth rate is positively related to domestic demand for 

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SAJEMS NS Vol 2 (1999) No 3 519 

construction materials, and that the RDP, whether measured at the underlying 
rate or a multiplier of 1.06/1 also has a positive impact on internal demand for 
construction materials. 

7 RECOMMENDATIONS, MANAGERIAL IMPLICATIONS, AND 
FUTURE RESEARCH 

An interesting managerial implication of this is that SADC governments need to 
find ways in which regional construction business suppliers can enter the 
.expanding SA construction supply market, and effectively manage strategic 
partnerships in the vertical or horizontal supply chain which develops. See 
Forrest (1992) and Fellows and Langford (1993). 

The primary strategic managerial implication is that managers in the Southern 
Africa construction material supplies industries need to closely examine the 
possibility of joint ventures to share market revenues. The joint ventures need to 
be designed in such a way that while they are profitable, in that they yield 
adequate returns on the capital employed, they do not lead to political discord 
and trade protectionism, as charges are made of attempting to dominate local, 
national or regional markets. Accordingly, assessing the long term impact 
which such joint ventures may have on demand and supply patterns is an area of 
research, which in the future, should be further developed. 

ENDNOTES 

The RDP is the blue print for economic and social development which 
was developed by the African National Congress (ANC) led majority 
government in 1994. There is a level of construction activity which would 
exist without the impact of the RDP. Accordingly we need to ascertain 
the level of pre-RDP construction activity level and subtract this from the 
RDP construction activity level. We envisage the RDP to be a major 
catalyst of the 'growth of the internal construction activity' that is referred 
to in brief and accordingly I devote attention to its role the econometric 
model developed herein. 

2 This dummy variable takes the value 0 for non-RDP related growth in the 
demand for construction materials, i.e. the underlying pre-RDP growth 
rate and 1 for a factor of(+ 6%) which is added to the underlying rate and 
is determined by the RDP induced growth in demand for construction 
materials. This factor is equivalent to RDP construction sector rate minus 
non-RDP underlying construction sector growth rate. We have calibrated 
this aspect of the model with 6%. It is based on the government's blue-

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520 SAJEMS NS Vol 2 (1999) No 3 

print macroeconomic annual growth forecast of 1996, which has 
unfortunately proved ambitious, but was the best information available at 
the time. 

3 This variable can be established by examining the degree of openness 
which each country has with the RSA via protocols, agreements and tariffs 
apart from the general SADC positions on such issues. It can also be 
calibrated as the actual observed level of trade between the two countries, 
and is the method we use when we introduce this model in the estimation 
process later on. 

4 These parameters include the state of intra-country construction 
manufacturing vintage of technology, geographical proximity to RSA, 
availability or lack of skilled construction sector manpower. There is 
likely to be some form simultaneity bias which is difficult to decipher 
exactly. 

5 Thus the disturbances for this model take the following form where 
E, = (EJt.E;t •.....• EN') is the vector of disturbances for project i; i 
=1,2, ... ,N) in period 1. The covariance for two different construction 
project periods can be given as E( E,E!) O'ul N t.s = /,2, .... T. Note that 
E( EII~) is the covariance of each project i over time while E( Ell Ejs) is the 
cross-sectional covariance which we assume to be zero. 

6 Usually a robust test of the goodness of fit of the model would be to 
evaluate it empirically via a simulation exercise, i.e. use II ex-post trends 
to carry out 41 ex-ante analysis. Alternatively it is possible to statistically 
validate an econometric model which has been estimated via maximum 
likelihood via the following procedure. The validation of the model herein 
followed the procedure in which the log-likelihood was evaluated at 
L*(O)= - 512242 with 183 degrees of freedom and fell to -366125 with 
the log-likelihood evaluation as L*(,o) with 141 degrees of freedom. 
The overall statistical validity of the model is fairly robust particularly 
given that the P2 value is 0.322 which falls within the acceptable range 
which Johnston (1984) has shown to be a good fit for model of this type. 
See Johnston J., Econometric Methods, McGraw Hill, 1984 for more on 
this. This validation procedure was used because firstly there are no 
previous empirical results and secondly there is no sufficiently clean data 
to test this model via simulation. 

7 A good way of basically explaining the maximum-likelihood estimation 
method used herein is to assume a bounded random variable p with a 
parameter with an unknown value since it is drawn from a random sample 
with data values of Yl =1, Y2 =1 and Y3= O. 'The maximum-likelihood 
technique will choose the value of the unknown parameter p that 
maximises the probability (likelihood) of randomly drawing the sample 

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SAJEMS NS Vol 2 (1999) No 3 521 

that was actually obtained.' Judge Hill, Griffiths, Lutkepohl, and Lee 
(1988), page 63. Since it is probabilistic the model is multiplicative. 

8 In the tests for t value significance one sided alternative hypothesis is used 
by using the critical value of t (since it is usual to test at the 95% level of 
confidence). The t(OO) value cutting off 5% of the highest values in this 
data distribution is 1.645 and that cutting off the lowest values is -1.645. 

9 The current economic growth rate suggests that excess supply capacity 
exists in RSA industry (not just in the construction sector but through out 
the economy) which can easily be geared up to meet the demand pull 
impact of the RDP. Furthermore, stagflation (inflation and recession) is 
more likely than inflation on its own. 

REFERENCES 

COATES D. & HILLARD J. (1987) The Economic Revival of Modern 
Britain - the Debate Between Left and Right, Edward Elgar Publishers. 

2 EASTERLEY W. & P. VIERRA da CUNHA (1994) "Financing the 
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ACKNOWLEDGEMENTS 

Some of the ideas for this paper originated from work which was carried out for 
the Ministry of Public Works of the Republic of South Africa in preparation for 
a Green Paper. I wish to acknowledge the comments of Sam Amod. The usual 
disclaimer applies. 

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